CN217407391U - Pet is fed ware and is used storage grain module and pet feeder - Google Patents

Abstract

The utility model discloses a go out grain structure and store up grain bucket and can detach fast or be connected, solve the pet feeder that goes out grain structure and change alone and wash the problem alone and use storage grain module and pet feeder. The adopted technical scheme is as follows: the utility model provides a pet feeder is with storing up grain module, includes and stores up the grain bucket and goes out the grain structure, store up the grain bucket including the ladle body with locate the opening of ladle body, it includes stirs the grain leaf to go out the grain structure, divides the grain subassembly and has the casing subassembly in holding chamber, be equipped with grain outlet and grain outlet on the casing subassembly, divide the grain subassembly to locate the holding intracavity, divide the grain subassembly to include the axis of rotation, divide the granary and divide the grain to separate, it connects to stir the grain leaf the one end of axis of rotation is located outside the holding chamber, it is equipped with on the grain structure and is used for quick the dismantlement to connect store up the quick-connect structure of grain bucket to go out the grain structural connection after storing up the grain bucket, grain outlet intercommunication the opening is located the open-ended below.

Description

Pet is fed ware and is used storage grain module and pet feeder

Technical Field

The utility model relates to a product technical field for the pet, in particular to pet feeder reaches pet feeder including this storage grain module with storing up grain module.

Background

With the ever-increasing standard of living of people, more and more families are beginning to feed pets, especially cats or canines. Pets have become an important member of the home in the owner's home, and therefore healthy feeding of pets has become a major concern. The pet food is a food which is easy to be oxidized and needs to be sealed and stored. In order to feed pets regularly and quantitatively, smart pet feeders have appeared in the market. The pet feeder provides convenience for pet owners, and solves the problem of healthy feeding of pets caused by the fact that the pet owners leave home for a period of time.

The pet feeder on the market generally comprises a grain barrel, a main machine, a grain discharging structure and a food tray. In the process of implementing the technical scheme of the utility model, the inventor finds that: the existing grain barrel and the grain discharging structure are usually fixed together and are not detachable, so that the problem that the grain discharging structure cannot be quickly replaced and is convenient to clean is also caused.

SUMMERY OF THE UTILITY MODEL

According to exist not enough among the prior art, the utility model provides a go out grain structure and store up grain bucket and can detach fast or be connected, solve the pet feeder that goes out grain structure and change alone and wash the problem alone and use storage grain module and pet feeder.

In order to solve the technical problem, the utility model discloses the technical scheme who adopts is: the utility model provides a pet feeder is with storing up grain module, includes and stores up the grain bucket and goes out the grain structure, store up the grain bucket including the ladle body with locate the opening of ladle body, it includes stirs the grain leaf to go out the grain structure, divides the grain subassembly and has the casing subassembly in holding chamber, be equipped with grain outlet and grain outlet on the casing subassembly, divide the grain subassembly to locate the holding intracavity, divide the grain subassembly to include the transmission shaft, divide the granary and divide the grain to separate, it connects to stir the grain leaf the one end of transmission shaft is located outside the holding chamber, it is equipped with on the grain structure and is used for quick the dismantlement to connect store up the fast structure of grain bucket to go out the grain structural connection after storing up the grain bucket, grain outlet intercommunication the opening.

Furthermore, the quick-connection structure in the technical scheme comprises a rotary clamping structure, one of the grain storage barrel and the grain discharging structure is provided with a rotary buckle, and the other is provided with a clamping position matched with the rotary buckle; the rotary buckle or the clamping position arranged on the grain storage barrel is positioned at one end provided with the opening, and the grain falling opening is positioned below the opening.

Furthermore, in the technical scheme, the quick-connection structure adopts a threaded connection structure, one of the grain storage barrel and the grain discharge structure is provided with an external thread, and the other one is provided with an internal thread matched with the external thread; the external thread or the internal thread arranged on the grain storage barrel is positioned at one end provided with the opening.

Furthermore, in the technical scheme, the casing assembly comprises a base body and a cover body, the grain outlet is formed in the cover body, the quick-connection structure is arranged on the side wall of the containing cavity of the casing assembly, the grain outlet structure is connected with the grain storage barrel, and the grain storage barrel is provided with an opening end which is abutted against the cover body or a sealing ring which is abutted against the cover body.

Furthermore, in the technical scheme, a sealing edge is arranged on the grain distribution assembly, the grain distribution assembly is divided into at least two grain distribution bins and at least two closed impellers by the grain distribution partition, the sealing edge is arranged on the periphery of each grain distribution bin and on each closed impeller and located above the grain outlet or above and below the grain outlet, and the sealing edge can be attached to the inner wall of the containing cavity in the shell assembly, so that the integral sealing of the grain storage module is realized when the grain distribution bins are not communicated with the grain outlet.

Furthermore, in the technical scheme, the quick connection structure comprises a rotary clamping structure, a positioning structure is further arranged on the grain discharging structure, a bump matched with the positioning structure is arranged on the grain storage barrel, and the positioning structure is arranged on the shell assembly and is positioned at the same end of the quick connection structure; the matching of the positioning structure and the bump is used for prompting the butt joint direction of the grain discharging structure and the grain storage barrel.

Furthermore, in the technical scheme, the grain outlet is formed in the side surface of the shell assembly, and the grain outlet is positioned below the shell assembly; when the grain distribution bin faces the grain outlet, the grain distribution partition is an inclined plane or a curved surface which inclines from the upper end surface of the grain distribution assembly to the grain outlet; the transmission shaft can drive the grain stirring blades and the grain distribution assembly to rotate together relative to the shell assembly, so that the grain distribution bin is aligned with the grain outlet or/and the grain outlet, or one grain outlet is aligned with the grain outlet and the grain outlet, or the grain distribution bin is positioned in the containing cavity.

Furthermore, when the grain distribution bin faces the grain outlet, the grain distribution bin is flush with the port connected with the grain outlet.

Furthermore, in the technical scheme, the grain distribution assembly comprises a support frame and a flexible grain distribution piece, the transmission shaft is arranged on the support frame, the grain distribution piece is sleeved on the outer surface of the support frame and is supported by the support frame, the grain distribution piece is arranged on the grain distribution piece in a spaced mode, and at least two grain distribution bins are separated from the grain distribution piece.

Furthermore, in the technical scheme, the grain separating partition and the grain separating piece are integrally formed, and the grain separating piece can be separated from the supporting frame through elastic deformation; the grain distribution assembly is provided with a sealing edge, and the sealing edge can be attached to the inner wall of the containing cavity in the shell assembly to realize the integral sealing of the grain storage module when the grain distribution bin is not communicated with the grain outlet.

Furthermore, in the technical scheme, the grain separating piece is divided into four parts by the grain separating partition, wherein the four parts comprise two grain separating bins and two closed impellers, and the grain separating bins and the closed impellers are arranged at intervals; when the grain distribution assembly rotates, one grain distribution bin is aligned to the grain outlet, and the other grain outlet is aligned to the grain outlet, or one closed impeller is aligned to the grain outlet, and the other grain outlet is aligned to the grain outlet.

Furthermore, in the technical scheme, a plurality of salient points and positioning marks for enhancing hand feeling are arranged on the side surface of the closed impeller, and the positioning marks are used for indicating the position relationship between the closed impeller and the shell assembly.

Furthermore, in the technical scheme, a positioning structure is arranged on the shell assembly, the positioning structure is positioned above the grain outlet, and the positioning structure can limit the connection mode of the grain outlet structure and an external host; and the positioning structure is provided with an indicating mark matched with the positioning mark.

Furthermore, in the technical scheme, the grain distribution assembly is provided with a sealing edge, the sealing edge is arranged on the periphery of each grain distribution bin and extends to the upper part of the grain outlet in each closed impeller, and the sealing edge can be attached to the inner wall of the containing cavity in the shell assembly to realize the integral sealing of the grain storage module when the grain distribution bins are not communicated with the grain outlet.

Furthermore, in the technical scheme, the shell assembly is further provided with a through hole, the transmission shaft is provided with a first end and a second end, the quick connection structure and the grain dropping port are located at one end provided with the grain stirring blades, the grain discharging port is located at the other end deviating from the quick connection structure, and the through hole is formed in the end face of the other end; the external power output part can penetrate through the through hole to be detachably connected with the second end or the second end penetrates through the through hole to be connected with the external power output part.

Furthermore, in the technical scheme, the through hole is positioned below the second end, and the detachable connection scheme of the second end and the external power output part adopts a plug-in connection scheme to realize power transmission; the diameter of the through hole is preferably in the range of 3-5 cm.

Furthermore, in the technical scheme, the shell assembly comprises a base body and a cover body, the grain outlet is formed in the base body, the grain outlet is formed in the side face of the shell assembly, and the containing cavity is formed in the base body and is sealed and covered by the cover body.

Furthermore, in the technical scheme, the cover body covers the side wall of the accommodating cavity on the base body, and the cover body is provided with a sealing ring to realize sealing with the side wall; the quick-connection structure is arranged on the side surface of the base body.

Furthermore, in the technical scheme, one of the base body and the cover body is provided with a limiting bulge, and the other is provided with a matched limiting groove.

Furthermore, in the technical scheme, the side wall is provided with a limiting bulge, and the cover body is provided with a matched limiting groove.

Furthermore, in the technical scheme, the quick-connection structure is arranged on the side wall, the quick-connection structure is positioned above the limiting protrusion, and the grain outlet structure is connected with the grain storage barrel and then the grain storage barrel is abutted to the cover body or the sealing ring.

Furthermore, in the technical scheme, the cover body is sleeved on the transmission shaft, the cover body is positioned between the grain distribution assembly and the grain stirring blades, the cover body and the grain distribution assembly are connected together through the transmission shaft and can be integrally separated from the base body.

Furthermore, in the technical scheme, the cover body is integrally formed with two grain limiting rakes, the two grain limiting rakes are respectively positioned on two sides of the grain outlet, and the grain limiting rakes are made of flexible materials.

Further, in the technical scheme, the shell assembly is cylindrical, and the outer diameter of the shell assembly is preferably less than 8.5 cm.

Furthermore, when the grain discharging structure is connected with the grain storage barrel in the technical scheme, the grain stirring blade is positioned in the grain storage space of the grain storage barrel through the opening; it includes flexible leaf subassembly and connecting axle to stir the grain leaf, the connecting axle can be dismantled with first end and be connected, leaf subassembly circumference distributes the side of connecting axle, the connecting axle is connected the position of leaf subassembly corresponds the protrusion and has the strengthening rib, every blade all wraps up in the leaf subassembly the strengthening rib.

Furthermore, in the technical scheme, an anti-counterfeiting device is further arranged on the grain storage barrel, and an identification device for identifying the anti-counterfeiting device is arranged on the external host.

In order to solve the technical problem, the utility model also discloses another technical scheme: the pet feeder comprises a grain storage module and a host, wherein a power output piece and a grain discharging channel are arranged on the host, the grain storage module is any one of the technical schemes, a storage bin suitable for storing a grain discharging structure is arranged on the host, the grain discharging channel is communicated with the storage bin, and the grain discharging structure is located in the storage bin and faces the grain discharging channel.

Furthermore, still be equipped with the switch on the host computer in this technical scheme, the switch is used for responding to whether place the grain structure in the storage compartment.

Further, in the technical scheme, the power output piece protrudes out of the storage bin.

Furthermore, in the technical scheme, an anti-counterfeiting device is further arranged on the grain storage barrel, and an identification device for identifying the anti-counterfeiting device is arranged on the host machine.

Furthermore, in the technical scheme, one of the barrel body and the host is provided with a clamping position, and the other is provided with a matched elastic clamp; when the grain storage barrel is connected with the host machine, the clamping position is matched with the elastic clamp to fix the barrel body and the host machine together.

The utility model provides a beneficial effect that technical scheme brought is mainly: because go out structural being equipped with of grain and being used for quick the dismantlement to connect store up the structure of connecing of grain bucket, so go out grain structure and store up grain bucket and can dismantle fast or be connected, solved the problem that the structure of going out grain changed alone and washed clearly alone, also made things convenient for the change of storing up the grain bucket when storing up the grain bucket for disposable storing up the grain bucket.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings required to be used in the description of the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without any creative effort.

Fig. 1 is a perspective view of a pet food dispensing device according to an embodiment of the present invention;

FIG. 2 is a schematic view of a pet food dispensing device according to an embodiment of the present invention, with its components in a disassembled state;

FIG. 3 is a sectional view of the pet food dispensing device according to the embodiment of the present invention;

FIG. 4 is a perspective view of the main body of the embodiment of the present invention;

FIG. 5 is a sectional view of the grain storage module according to the embodiment of the present invention;

FIG. 6 is a structural section view of the grain discharging structure and the grain storage barrel in a separated state in FIG. 5;

fig. 7 is a perspective view of the grain discharging structure under the top view angle in the embodiment of the utility model;

fig. 8 is a perspective view of the grain discharging structure under the bottom view angle in the embodiment of the utility model;

FIG. 9 is a perspective view of the embodiment of the present invention, in which the stirring blades, the cover and the grain-dividing assembly are separated from the base as a whole;

FIG. 10 is a perspective view of the embodiment of the present invention, in which the stirring blades, the cover and the grain distributing assembly are integrated into a whole assembly;

fig. 11 is an exploded view of the grain discharging structure in the embodiment of the present invention;

FIG. 12 is a sectional view of the grain discharging structure in the embodiment of the present invention;

fig. 13 is an exploded view of the grain discharging structure in the sectional state of fig. 12;

fig. 14 is a perspective view of the structure of the grain distribution bin aligned with the grain outlet after being rotated 90 degrees relative to the grain distribution assembly of fig. 7;

fig. 15 is a structural sectional view of the grain discharging structure in the state of fig. 14;

FIG. 16 is a cross-sectional view of an alternative arrangement of the cover of FIG. 15;

fig. 17 is a schematic diagram of another arrangement of the quick-connect structure in the embodiment of the invention.

Detailed Description

In order to make the technical problems, technical solutions and advantageous effects to be solved by the present invention more clearly understood, the present invention is further disclosed and explained in detail below with reference to the accompanying drawings. It should be understood that the detailed description and specific examples, while indicating the scope of the invention, are intended for purposes of illustration only and are not intended to limit the scope of the invention.

In the description of the present invention, unless otherwise explicitly specified or limited, the terms "disposed" and "connected" are to be interpreted broadly, e.g., as a fixed connection, a detachable connection, or an integral connection; may be directly connected or indirectly connected through an intermediate. The specific meaning of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

The term "pet" is used herein to refer primarily to a common feline or canine animal. For convenience of description, spatially relative terms, such as "forward", "rearward", "circumferential", "peripheral", "top", "one end", "outer", "bottom", "upper", "lower", "side", "inner", and the like, may be used herein to describe one element or feature's relationship to another element or feature as illustrated in the figures. This spatially relative relationship is intended to encompass different orientations of the mechanism in use or operation in addition to the orientation depicted in the figures. For example, if the mechanism in the figures is turned over, elements described as "below" or "beneath" other elements or features would then be oriented "above" or "over" the other elements or features. Thus, the example term "below … …" can include both an orientation of above and below. The mechanism may be otherwise oriented (rotated 90 degrees or at other orientations) and the spatially relative descriptors used herein interpreted accordingly.

As shown in fig. 1, 2 and 6, in order to provide a pet feeding device 200 according to a preferred embodiment of the present invention, the pet feeding device 200 includes a main body 210, a grain storage barrel 220, a food bowl 230 and a grain discharging structure 100, the grain storage barrel 220 includes a barrel body 221, an opening 222, a rotating buckle 223 and a projection 224, which are disposed on the barrel body 221, and a placement platform 215 and a grain discharging channel 216 are disposed on the main body 210. Wherein the opening 222 is provided at the lower end of the tub 221, and the rotary latch 223 and the projection 224 are provided at the sidewall of the same end as the opening 222. The grain storage barrel 220 is suitable for being located above the main machine 210, the placing platform 215 extends out of the bottom of the main machine 210 and is located in front of the grain discharging channel 216, and the food bowl 230 is placed on the placing platform 215 and used for receiving pet grains falling from the grain discharging channel 216. As shown in fig. 3 and 4, a motor 211 is arranged in the main unit 210, the main unit 210 is further provided with a storage bin 212 and a switch 214, the storage bin 212 is shaped to be suitable for storing the grain discharging structure 100, the switch 214 is used for sensing whether the grain discharging structure 100 is placed in the storage bin 212, and the switch 214 is a spring plate pressing switch. The motor 211 is positioned below the storage bin 212, an output shaft of the motor 211 is connected with a power output member 213, and the power output member 213 extends out of the storage bin 212. As shown in fig. 5 and 6, the grain discharging structure 100 is provided with a quick-connecting structure 112 for quickly connecting and disconnecting the grain storage barrel 220. When the grain storage barrel 220 is assembled, the grain discharging structure 100 is connected with the grain storage barrel 220 and then the grain storage barrel and the grain discharging structure are connected with the main machine 210; after assembly, the grain storage barrel 220 is finally located above the main body 210, and the grain discharging structure 100 is located in the storage bin 212.

As shown in fig. 7, 8, 9 and 11, the grain discharging structure 100 includes a grain stirring blade 120, a grain dividing assembly 103 and a housing assembly 110 having an accommodating cavity 111, and the grain dividing assembly 103 is disposed in the accommodating cavity 111. As shown in fig. 10, fig. 11 and fig. 12, the grain dividing assembly 103 includes a transmission shaft 151 and a grain dividing partition 131, the transmission shaft 151 is located on a central axis of the grain dividing assembly 103, the transmission shaft 151 has a first end 1511 and a second end 1512, the grain stirring blade 120 is connected to the first end 1511 and then located outside the accommodating cavity 111, and the grain stirring blade 120 and the grain dividing assembly 103 can rotate together relative to the housing assembly 110. The shell assembly 110 is provided with a quick connection structure 112, a grain outlet 141, a grain outlet 113 and a through hole 114, the quick connection structure 112 and the grain outlet 141 are located at one end of the grain stirring blade 120, the grain outlet 113 is located at the other end deviating from the quick connection structure 112, and the through hole 114 is arranged on the end surface of one end of the grain outlet 113 and is located right below the second end 1512. The grain outlet 113 is arranged on the side surface of the shell assembly 110 and is positioned at the lower position of the shell assembly 110, and when the grain discharging structure 100 is positioned in the storage bin 212, the grain outlet 113 is opposite to the grain discharging channel 216. The quick-connecting structure 112 is used for enabling the grain discharging structure 100 and the grain storage barrel 220 to be connected in a quick-detachable mode, and the second end 1512 is exposed through the through hole 114 so as to be detachably connected with the power output piece 213. After the grain discharging structure 100 is connected with the grain storage barrel 220, the grain outlet 141 is communicated with the opening 222 and is positioned below the opening 222, and the power output part 213 passes through the through hole 114 and is detachably connected with the second end 1512 to complete power transmission. In other embodiments, the second end 1512 may also be configured to extend out of the through hole 114, and the pto 213 may be detachably connected to the second end 1512 without passing through the through hole 114.

As shown in fig. 7 and 9, the housing assembly 110 includes a cup-shaped base 118 and a cover 119. The grain dropping port 141 is arranged on the cover body 119, the quick connection structure 112, the grain outlet 113 and the through hole 114 are arranged on the base body 118, the grain outlet 113 is arranged on the side surface of the shell assembly 110, and the accommodating cavity 111 is arranged in the base body 118 and is sealed and covered by the cover body 119. The cover 119 covers the sidewall of the receiving cavity 111 in the base 118, and a sealing ring 143 is disposed on the cover 119 to seal with the sidewall. The quick-connect structure 112 is selected as a rotary clamping structure, and in this embodiment, the quick-connect structure 112 is selected as a clamping structure (position clamping) matched with the rotary buckle 223. In other embodiments, the quick-connection structure 112 may also be a screw connection structure, and at this time, one of the grain storage barrel 220 and the grain output structure 100 is provided with an external thread, and the other is provided with an internal thread matched with the external thread; the external thread or the internal thread arranged on the grain storage barrel 220 is positioned at the same end provided with the opening 222.

As shown in fig. 2 and 3, the grain storage barrel 220 is further provided with an anti-counterfeiting device 226, the host 210 is provided with an identification device 217 for identifying the anti-counterfeiting device 226, and the matching of the anti-counterfeiting device 226 and the identification device 217 can remind a user of using the grain storage barrel 220 matched with a product. The anti-counterfeiting device 226 stores anti-counterfeiting data, and the anti-counterfeiting device 226 and the identification device 217 can adopt common NFC or RFID near-field sensing technology. As shown in fig. 2 and 4, the barrel 221 is provided with a clamping position 225, and the host 210 is provided with an elastic card 218 matching with the clamping position 225; when the grain storage barrel 220 is connected with the main machine 210, the clamping position 225 is matched with the elastic clamp 218 to fix the barrel body 221 and the main machine 210 together. The purpose of the arrangement is that when the main machine 210 falls down, the grain storage barrel 220 can not be separated from the main machine 210 so as to ensure that the pet grains are not spilled. In order to achieve a good sealed grain storage effect, when the grain storage barrel 220 is made into a capsule shape and designed into a disposable product, the anti-counterfeiting scheme can enable a user to use a quality pet grain, and the edible safety of the pet grain is improved.

As shown in fig. 12 and 13, the cover 119 is sleeved on the transmission shaft 151, and the cover 119 is located between the grain distribution assembly 103 and the grain stirring blade 120. The grain stirring blade 120, the cover body 119 and the grain distribution assembly 103 are connected in series through the transmission shaft 151 to form a whole body which can be separated from the base body 118 integrally, but the cover body 119 does not rotate together with the grain stirring blade 120. The housing assembly 110 is cylindrical and the cylindrical outer diameter of the housing assembly 110 is selected to be 8.5 cm or less. In order to facilitate the user to push out the grain distribution assembly 103 by penetrating the fingers through the through holes 114, the diameter size range of the through holes 114 is selected to be 3-5 cm.

As shown in fig. 4, 8, and 9, the clamping structure 112 is disposed on an inner side surface of the base 118, and the detachable connection scheme of the second end 1512 and the power output element 213 is a plug-in connection scheme to realize power transmission. Specifically, the second end 1512 is provided with a plug hole 1513, and the power output member 213 is provided with a connection protruding shaft with a shape matching with the plug hole 1513.

As shown in fig. 9 and 10, a limiting protrusion 115 is disposed on a sidewall of the receiving cavity 111 of the base 118, and a matching limiting groove 144 is disposed on the cover 119. When the cover 119 is covered on the base 118, the limiting protrusion 115 is clamped in the limiting groove 144, so that the cover 119 and the base 118 form a whole, and the sealing ring 143 is in interference fit with the side wall of the accommodating cavity 111. The quick connection structure 112 is also arranged on the side wall of the accommodating cavity 111 and is positioned above the limiting protrusion 115; in other embodiments, when the snap-fit structure 112 is selected as the snap-fit structure, as shown in fig. 16, the snap-fit structure 112 may also extend from the end surface of the base 118 to form a mating snap 112'. In this embodiment, the height difference from the limiting protrusion 115 to the quick-connection structure 112 is the thickness of the cover body 119 plus the height from the bottom of the grain storage barrel 220 to the clamping position. As shown in fig. 5, after the grain discharging structure 100 is connected to the grain storage barrel 220, the grain storage barrel 220 abuts against the sealing ring 143 on the cover 119, and the grain stirring blade 120 is located in the grain storage space of the grain storage barrel 220 after passing through the opening 222. In other embodiments, the position-limiting protrusion 115 may also be disposed on the cover 119, and the base 118 is correspondingly disposed with the matching position-limiting groove 144.

As shown in fig. 8 and 11, the base 118 is provided with a positioning structure 116 connected with the host 210, the positioning structure 116 is disposed on the housing assembly 110 and located at the same end of the quick connection structure 112, the positioning structure 116 protrudes from the grain outlet 113, and the protrusion 224 can be engaged in the positioning structure 116. When the grain discharging structure 100 is connected with the grain storage barrel 220, the matching of the positioning structure 116 and the bump 224 is used for prompting the butt joint direction of the grain discharging structure 100 and the grain storage barrel 220; when the grain discharging structure 100 is connected with the main machine 210, the positioning structure 116 is used for limiting the base 118 and the main machine 210 to be connected together without rotating, and is also convenient for the second end 1512 to be quickly connected with the power output part 213.

As shown in fig. 15 and 16, two grain-restricting rakes 142 are integrally formed on the cover 119, and the two grain-restricting rakes 142 are respectively located at both sides of the grain-dropping opening 141. In this embodiment, the rake 142 is made of a flexible material, and the rake 142 can abut (or be close to) the grain dividing assembly 103 when the grain dividing assembly 103 rotates.

As shown in fig. 11 and 13, the grain dividing assembly 103 includes a flexible grain dividing member 130 and a supporting frame 150, the transmission shaft 151 is disposed in the center of the supporting frame 150, the grain dividing member 130 is sleeved on the outer surface of the supporting frame 150 and is supported by the supporting frame 150, and the supporting frame 150 supports the grain dividing member 130 to keep the grain dividing member 130 in a set shape and prevent the grain dividing member 130 from deforming. The grain separating piece 130 can be separated from the supporting frame 150 through elastic deformation, so that the grain separating piece 130 is convenient to clean and rinse. The grain separating partition 131 (shown as a dotted line in fig. 11) is disposed on the grain separating member 130 (in this embodiment, the grain separating partition 131 is integrally formed with the grain separating member 130), and the grain separating member 130 is divided into four fan-shaped equal parts, which include two grain separating bins 132 and two closed impellers 134. When the grain distribution bin 132 faces the grain outlet 113, the end of the grain distribution bin 132 connected with the grain outlet 113 is flush, the grain distribution partition 131 is an inclined plane or a curved surface which inclines from the upper end surface of the grain distribution assembly 103 to the grain outlet 113, and the grain distribution bin 130 and the closed impeller 134 are arranged at intervals. In this embodiment, the grain outlet 141 and the grain outlet 113 are arranged oppositely, and on the same plane, the difference between the center lines of the grain outlet 141 and the grain outlet 113 is 180 degrees. The purpose of the grain separating element 130 being flexible is to make the grain separating element 130 have a certain deformation capacity so as to be compatible with larger granular pet grains (such as freeze-drying eaten by pet cats), and also to prevent the claws of the pet from being pinched when the grain separating element 103 rotates and the claws are at the grain outlet 113.

As shown in fig. 12, 14 and 15, the grain distribution bin 132 is adapted to store a predetermined amount of pet food therein. Under the action of the power output part 213, the transmission shaft 151 can drive the grain stirring blades 120 and the grain distribution assembly 103 to rotate together relative to the shell assembly 111, so that one grain distribution bin 132 is aligned with the grain falling opening 141 (at the moment, the grain falling opening 141 is positioned right above the grain distribution bin, pet grains enter the grain distribution bin through the grain falling opening 141), and the other grain outlet 113 is aligned with the grain outlet (at the moment, the pet grains in the grain distribution bin enter the grain bowl 230 through the grain falling channel 216); or one closed impeller 134 blocks the grain outlet 141 and the other blocks the grain outlet 113 to intermittently align the grain distribution bin 132 with the grain outlet 141 and the grain outlet 113. Under the state that the two closed impellers 134 block the grain outlet 141 and the grain outlet 113, the closed impeller 134 blocking the grain outlet 141 is contacted with or close to the grain limiting rake 142; at this time, when the grain discharging structure 100 and the grain storage barrel 220 are separated, even if the grain discharging structure 100 is in a translation rotating state, the pet grain in the grain distribution bin 132 can not be dropped out.

As shown in fig. 7, the side of each enclosed impeller 134 is provided with a plurality of protrusions 133 and positioning marks 135 for enhancing the touch feeling, and the positioning marks 135 are used to indicate the positional relationship between the enclosed impeller 134 and the housing assembly 110. Specifically, the outer surface of the enclosed impeller 134 is provided with a positioning mark 135, and the positioning structure 116 of the casing assembly 110 is correspondingly provided with an indication mark 1161.

As shown in fig. 9, 10 and 11, the grain dividing member 130 is provided with sealing edges 136 at the periphery of each grain dividing bin 132 and above and below the grain outlet 113 in each closed impeller 134, and the sealing edges 136 are in a strip shape and surround the grain dividing member 130 for one circle. When the grain distributing piece 130 is arranged in the shell component 110, the sealing edge 136 is attached to the inner wall of the accommodating cavity 111 to realize the integral sealing of the grain storage module when the grain distributing bin 132 is not communicated with the grain outlet 113. When going out grain structure 100 and connecting on grain storage bucket 220, such setting can let divide granary 132 not facing to under the 113 states of grain outlet, and the inner wall of contained side 136 laminating holding chamber 111, every minute granary 132 forms an independent seal structure through 113 and external intercommunications of grain outlet this moment, so can prevent that the pet grain from by the oxidation, promotes the save effect of pet grain. In this embodiment, the sealing edge 136 is integrally formed with the grain dividing member 130. In addition, the sealing edge 136 may also prevent small pet food particles from entering the dispensing member 130.

As shown in fig. 13, the grain stirring blade 120 comprises a flexible blade assembly 121 and a connecting shaft 122, and the connecting shaft 122 is detachably connected with the first end 1511 through a thread. The blade assemblies 121 are circumferentially distributed on the side surface of the connecting shaft 122, reinforcing ribs 123 correspondingly protrude from the connecting shaft 122 at the position where the blade assemblies 121 are connected, and each blade in the blade assemblies 121 is wrapped with the reinforcing ribs 123. The arrangement of the reinforcing ribs 123 can enhance the fatigue resistance of the joint of the blade assembly 121 and the connecting shaft 122, improve the stability of combination, and prevent the blade assembly 121 from being broken due to the generated shearing force after long-time rotation; in addition, when leaf assembly 121 is made of a softer material, leaf assembly 121 can maintain a certain flexibility due to the arrangement of reinforcing ribs 123.

In other embodiments, the position relationship between the grain outlet 141 and the grain outlet 113 can be made into a corner scheme. As shown in fig. 16, the center lines of the grain outlet 141 and the grain outlet 113 are 90 degrees apart.

Because the housing assembly 110 is provided with the quick-connecting structure 112 and the through hole 114 in the embodiment, the quick-connecting structure 112 and the grain outlet 141 are located at one end of the grain stirring blade 120, the through hole 114 is formed in the end surface of the other end (away from the end with the quick-connecting structure 112), the quick-connecting structure 112 is used for enabling the grain discharging structure 100 to be connected with the grain storage barrel 220 in a quick-disassembling mode, and the second end 1512 and the power output part 213 can be connected in a detachable mode through the through hole 114 to complete power transmission, so that the grain discharging structure 100 is an overall uncharged modular structure design, and is convenient to be connected and separated with the grain storage barrel 220 and the host 210 in a quick mode, and independent replacement, cleaning or cleaning operations are achieved. Because the grain discharging structure 100 and the grain storage barrel 220 can be quickly connected and separated, the grain discharging structure 100 can be matched and connected with various grain storage barrels 220, and the grain storage barrel 200 is convenient to replace when the grain storage barrel 220 is a disposable capsule grain storage barrel with good sealing effect.

The above specific examples are used to illustrate the principles and embodiments of the present invention, and it should be understood that the above embodiments are only used to help understand the present invention, and should not be construed as limiting the present invention. Any minor modifications or equivalent replacements of the structural forms or constructions of the present invention according to the idea of the present invention shall be included in the protection scope of the present invention for those skilled in the art.

Claims (31)

1. The utility model provides a pet feeder is with storing up grain module, includes and stores up grain bucket and goes out the grain structure, store up the grain bucket including the ladle body with locate the opening of ladle body, go out the grain structure including stirring the grain leaf, divide the grain subassembly and have the casing subassembly in holding chamber, be equipped with grain outlet and grain outlet on the casing subassembly, divide the grain subassembly to locate the holding intracavity, divide the grain subassembly to include the transmission shaft, divide the granary and divide the grain to separate, it connects to stir the grain leaf the one end of transmission shaft is located outside the holding chamber, its characterized in that: the grain discharging structure is provided with a quick connection structure for quickly disassembling and connecting the grain storage barrel, and the grain discharging opening is communicated with the opening after the grain discharging structure is connected with the grain storage barrel.

2. The grain storage module of claim 1, wherein: the quick-connection structure comprises a rotary clamping structure, one of the grain storage barrel and the grain discharging structure is provided with a rotary buckle, and the other is provided with a clamping position matched with the rotary buckle; the rotary buckle or the clamping position arranged on the grain storage barrel is positioned at one end provided with the opening, and the grain falling opening is positioned below the opening.

3. The grain storage module of claim 1, wherein: the quick-connection structure adopts a threaded connection structure, one of the grain storage barrel and the grain discharge structure is provided with an external thread, and the other is provided with an internal thread matched with the external thread; the external thread or the internal thread arranged on the grain storage barrel is positioned at one end provided with the opening.

4. The grain storage module of claim 1, wherein: the shell assembly comprises a base body and a cover body, the grain outlet is formed in the cover body, the quick-connection structure is arranged on the side wall of the containing cavity on the shell assembly, the grain outlet structure is connected with the grain storage barrel, and the grain storage barrel is provided with an opening end abutted against the cover body or a sealing ring abutted against the cover body.

5. The grain storage module of claim 1, wherein: the grain distribution assembly is provided with a sealing edge, the grain distribution assembly is divided into at least two grain distribution bins and at least two closed impellers by the grain distribution partition, the sealing edge is arranged on the periphery of each grain distribution bin and on each closed impeller and located above the grain outlet or above and below the grain outlet, and the sealing edge can be attached to the inner wall of the containing cavity in the shell assembly, so that the integral sealing of the grain storage module is realized when the grain distribution bins are not communicated with the grain outlet.

6. The grain storage module of claim 1, wherein: the quick-connection structure comprises a rotary clamping structure, a positioning structure is further arranged on the grain discharging structure, a bump matched with the positioning structure is arranged on the grain storage barrel, and the positioning structure is arranged on the shell assembly and is positioned at the same end where the quick-connection structure is arranged; the matching of the positioning structure and the lug is used for prompting the butt joint direction of the grain discharging structure and the grain storage barrel.

7. The grain storage module of claim 1, wherein: the grain outlet is arranged on the side surface of the shell component and is positioned below the shell component; when the grain distribution bin faces the grain outlet, the grain distribution partition is an inclined plane or a curved surface which inclines from the upper end surface of the grain distribution assembly to the grain outlet; the transmission shaft can drive the grain stirring blades and the grain distribution assembly to rotate together relative to the shell assembly, so that the grain distribution bin is aligned with the grain outlet or/and the grain outlet, or one grain outlet is aligned with the grain outlet and the grain outlet, or the grain distribution bin is positioned in the containing cavity.

8. The grain storage module of claim 7, wherein: when the grain distribution bin faces the grain outlet, the grain distribution bin is flush with the port connected with the grain outlet.

9. The grain storage module of claim 8, wherein: the grain distribution assembly comprises a support frame and a flexible grain distribution piece, the transmission shaft is arranged on the support frame, the grain distribution piece is sleeved on the outer surface of the support frame and is supported by the support frame, and the grain distribution piece is arranged on the grain distribution piece in a spaced mode and is divided into at least two grain distribution bins.

10. The grain storage module of claim 9, wherein: the grain separating partition and the grain separating piece are integrally formed, and the grain separating piece can be separated from the supporting frame through elastic deformation; the grain distribution assembly is provided with a sealing edge, and the sealing edge can be attached to the inner wall of the containing cavity in the shell assembly to realize the integral sealing of the grain storage module when the grain distribution bin is not communicated with the grain outlet.

11. The grain storage module of claim 9, wherein: the grain separating piece is divided into four parts by the grain separating partition, wherein the four parts comprise two grain separating bins and two closed impellers, and the grain separating bins and the closed impellers are arranged at intervals; when the grain distribution assembly rotates, one grain distribution bin is aligned to the grain outlet, the other grain outlet is aligned to the grain outlet, or one closed impeller is aligned to the grain outlet, and the other grain outlet is aligned to the grain outlet.

12. The grain storage module of claim 11, wherein: the side surface of the closed impeller is provided with a plurality of salient points and positioning marks for enhancing hand feeling, and the positioning marks are used for indicating the position relation between the closed impeller and the shell assembly.

13. The grain storage module of claim 12, wherein: the shell assembly is provided with a positioning structure, the positioning structure is positioned above the grain outlet, and the positioning structure can limit the connection mode of the grain outlet structure and an external host; and the positioning structure is provided with an indicating mark matched with the positioning mark.

14. The grain storage module of claim 11, wherein: the grain distribution assembly is provided with a sealing edge, the sealing edge is arranged on the periphery of each grain distribution bin and extends to the upper part of the grain outlet in each closed impeller, and the sealing edge can be attached to the inner wall of the containing cavity in the shell assembly to realize the integral sealing of the grain storage module when the grain distribution bins are not communicated with the grain outlet.

15. The grain storage module of claim 1, wherein: the shell assembly is also provided with a through hole, the transmission shaft is provided with a first end and a second end, the quick-connection structure and the grain falling port are positioned at one end provided with the grain stirring blades, the grain outlet is positioned at the other end deviating from the quick-connection structure, and the through hole is formed in the end surface of the other end; the external power output part can penetrate through the through hole to be detachably connected with the second end or the second end penetrates through the through hole to be connected with the external power output part.

16. The grain storage module of claim 15, wherein: the through hole is positioned below the second end, and the detachable connection scheme of the second end and the external power output part adopts a plug-in scheme to realize power transmission; the diameter of the through hole is preferably in the range of 3-5 cm.

17. The grain storage module of claim 1, wherein: the shell assembly comprises a base body and a cover body, the grain outlet is formed in the base body, the grain outlet is formed in the side face of the shell assembly, and the containing cavity is formed in the base body and is sealed and covered by the cover body.

18. The grain storage module of claim 17, wherein: the cover body covers the side wall of the accommodating cavity on the base body, and is provided with a sealing ring to realize sealing with the side wall; the quick-connection structure is arranged on the side surface of the base body.

19. The grain storage module of claim 18, wherein: one of the base body and the cover body is provided with a limiting bulge, and the other one is provided with a matched limiting groove.

20. The grain storage module of claim 19, wherein: the side wall is provided with a limiting bulge, and the cover body is provided with a matched limiting groove.

21. The grain storage module of claim 20, wherein: the fast connection structure is arranged on the side wall and located above the limiting protrusion, and the grain outlet structure is connected with the grain storage barrel and then abutted to the cover body or the sealing ring.

22. The grain storage module of claim 17, wherein: the cover body is sleeved on the transmission shaft, the cover body is positioned between the grain distribution assembly and the grain stirring blades, the cover body and the grain distribution assembly are connected together through the transmission shaft and can be integrally separated from the base body.

23. The grain storage module of claim 17, wherein: the cover body is integrally formed with two grain limiting rakes, the two grain limiting rakes are respectively located on two sides of the grain outlet, and the grain limiting rakes are made of flexible materials.

24. The grain storage module of claim 1, wherein: the housing assembly is cylindrical, and the outer diameter of the housing assembly is preferably less than 8.5 cm.

25. A grain storage module as claimed in any one of claims 1 to 24 wherein: when the grain discharging structure is connected with the grain storage barrel, the grain stirring leaves are positioned in the grain storage space of the grain storage barrel through the opening; stir grain leaf and include flexible leaf subassembly and connecting axle, the connecting axle can be dismantled with first end and be connected, leaf subassembly circumference distributes the side of connecting axle, the connecting axle is connected the position of leaf subassembly corresponds the protrusion and has the strengthening rib, every blade all wraps up in the leaf subassembly has the strengthening rib.

26. A grain storage module as claimed in any one of claims 1 to 24 wherein: the grain storage barrel is also provided with an anti-counterfeiting device, and the external host is provided with an identification device for identifying the anti-counterfeiting device.

27. The utility model provides a pet feeder, is including storing up grain module and host computer, be equipped with power take off spare on the host computer and lower grain passageway, its characterized in that: the grain storage module is the grain storage module for the pet feeder as claimed in any one of claims 1 to 25, a storage bin suitable for storing the grain discharging structure is arranged on the main machine, the grain discharging channel is communicated with the storage bin, and when the grain discharging structure is positioned in the storage bin, the grain discharging port faces the grain discharging channel.

28. The pet food dispensing device as claimed in claim 27, wherein: the main machine is also provided with a switch which is used for sensing whether a grain discharging structure is placed in the storage bin or not.

29. The pet food dispensing device as claimed in claim 27, wherein: the power output member protrudes inside the storage compartment.

30. The pet feeder of claim 27, wherein: the grain storage barrel is also provided with an anti-counterfeiting device, and the host is provided with an identification device for identifying the anti-counterfeiting device.

31. The pet feeder of claim 27, wherein: one of the barrel body and the main machine is provided with a clamping position, and the other is provided with a matched elastic clamp; when the grain storage barrel is connected with the host machine, the clamping position is matched with the elastic clamp to fix the barrel body and the host machine together.

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