CN214677089U - Water feeder - Google Patents

Abstract

The utility model discloses a water bowl. This water bowl includes: the shell comprises a water storage cavity and a drinking water cavity; the filtering component is communicated with the drinking water cavity; the water pump is arranged in the water storage cavity, the nozzle is arranged in the drinking water cavity, and the water pump is connected with the nozzle through the conveying pipeline; the nozzle comprises at least one first nozzle part, and the first nozzle part faces to a preset direction, so that the water flow output from the first nozzle part flows in a spiral shape in the drinking cavity. In this way, the utility model discloses can provide the drinking water of flow state, be favorable to keeping the clean and the reduction rivers noise in drinking water chamber.

Description

Water feeder

Technical Field

The utility model relates to a feeding equipment technical field especially relates to a water bowl.

Background

People and animals are all friends, along with the progress of times and the development of urbanization, people raising pets nowadays are more and more, and people have better treated pets than families and have entrusted feelings of themselves on pets. On the basis of care of the pet by the owner, more and more care products and corresponding electronic products are used as the pet, and one of the care products is a pet water feeding device.

Current watering devices are simply a basin or bowl of water in which the water is held relatively stationary, rather than so-called live water (i.e., water in a flowing state which increases the oxygen content of the water), which is more prone to soiling and bacterial growth, and which has no way of attracting pet interest. That is, even if the pet needs to be thirsty, the pet does not actively drink still water, which affects the drinking motivation of the pet. In addition, when the existing water feeding equipment works, the water flow for the pet to drink can generate large noise, so that the pet is easily frightened.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model mainly solves the technical problem of providing a water feeder, can provide the drinking water of mobile state, be favorable to keeping the cleanness in drinking water chamber and reduce the rivers noise.

In order to solve the technical problem, the utility model discloses a technical scheme be: there is provided a water feeder, further comprising: the shell comprises a water storage cavity and a drinking water cavity; the filtering component is communicated with the drinking water cavity; the water pump is arranged in the water storage cavity, the nozzle is arranged in the drinking water cavity, and the water pump is connected with the nozzle through the conveying pipeline; the nozzle comprises at least one first nozzle part, and the first nozzle part faces to a preset direction, so that the water flow output from the first nozzle part flows in a spiral shape in the drinking cavity.

In an embodiment of the present invention, the predetermined direction and the first reference plane are disposed at an angle, and the first reference plane is defined by a radial direction of the drinking water chamber and an axial direction of the drinking water chamber at the position of the first nozzle portion.

In an embodiment of the present invention, the nozzle includes a second nozzle portion, the second nozzle portion is oriented toward the radial direction of the drinking water cavity at the position where the second nozzle portion is located, the second nozzle portion has a plurality of water outlet holes, and the first nozzle portion and the second nozzle portion are selectively used for supplying water to the drinking water cavity.

In an embodiment of the present invention, the conveying pipeline includes a middle pipeline and a water outlet pipeline, the middle pipeline is respectively connected to the water inlet of the water outlet pipeline and the water pump, and the end of the water outlet pipeline away from the water inlet has a first water outlet and a second water outlet; the first water outlet faces to a preset direction to form a first nozzle part, and the second water outlet faces to the radial direction of the drinking cavity at the position of the first water outlet to form a second nozzle part.

In an embodiment of the present invention, the housing includes a first housing and a second housing, the first housing is nested in the second housing, the first housing includes a water storage cavity and a drinking water cavity, and an accommodating cavity is formed between the first housing and the second housing; the water feeder comprises a circuit assembly, and the circuit assembly is accommodated in the accommodating cavity.

The utility model discloses an in the embodiment, circuit component includes level sensor, and level sensor locates the part that corresponds the drinking water chamber in the holding chamber for detect the water level in drinking water chamber, wherein when the water level in drinking water chamber is higher than level sensor, the water pump stops to carry the water of water storage intracavity to drinking water chamber.

In an embodiment of the utility model, the circuit component comprises a distance sensor, the distance sensor is arranged in the accommodating cavity and is used for detecting whether an object is close to the water feeder; the water pump has a first power when the distance sensor detects that an object is near the water feeder, and a second power when the distance sensor does not detect that an object is near the water feeder, wherein the first power is greater than the second power.

The utility model discloses an in the embodiment, circuit module includes first circuit board, and first circuit board integration has communication circuit for carry out the information interaction with user's mobile terminal.

The utility model discloses an in the embodiment, first casing is transparent, and the second casing is equipped with water level observation window to observe the residual water yield in the water storage chamber through water level observation window, the one end in drinking water chamber is kept away from to water level observation window and the one end parallel and level in water pump towards the drinking water chamber.

In an embodiment of the utility model, the water feeder comprises a shielding piece, the shielding piece is arranged at one side of the drinking water cavity far away from the water storage cavity, and the orthographic projection of the shielding piece on the second reference plane covers the orthographic projection part of the drinking water cavity on the second reference plane; the drinking water cavity and the water storage cavity are oppositely arranged, and the second reference plane is vertical to the opposite direction of the drinking water cavity and the water storage cavity.

The utility model has the advantages that: be different from the prior art, the utility model provides a water bowl. The water storage cavity is arranged to the water pump of this water bowl, and the drinking water cavity is located to the nozzle, and water pump and nozzle pass through pipeline and connect. Therefore, the water pump passes through conveying line with the water in the water storage cavity and carries to the nozzle, exports water to drinking water chamber by the nozzle, that is to say that the utility model discloses a water bowl can provide the drinking water of mobile state, can increase the oxygen content in the drinking water, avoids being infected with the filth and breeding the bacterium as far as possible to and improve the enthusiasm that the pet was drunk water.

The nozzle also comprises a first nozzle part which can be oriented to a preset direction to enable the water flow output by the first nozzle part to flow spirally in the drinking cavity. That is, when the water feeder works, the drinking water output by the first nozzle part flows spirally in the drinking water cavity. The drinking water flowing spirally can be in more full contact with air, and the oxygen content in the water in the drinking water cavity can be further increased; the water flow can cover most of the surface of the drinking cavity as much as possible, so that foreign matters remained in the drinking cavity can be washed, the cleanness of the drinking cavity can be kept, and the cleanness of drinking water for pets can be further ensured; and the drinking water that the heliciform flows can reduce the noise that rivers produced to avoid the pet to receive the frightening and influence the pet and normally drink water because of the noise.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the invention and together with the description, serve to explain the principles of the invention. Moreover, the drawings and the description are not intended to limit the scope of the inventive concept in any way, but rather to illustrate it by those skilled in the art with reference to specific embodiments.

FIG. 1 is a schematic structural view of an embodiment of a water feeder of the present invention;

FIG. 2 is an exploded view of the water feeder of FIG. 1;

FIG. 3 is a schematic cross-sectional view taken along the line A-A of the water feeder of FIG. 1;

FIG. 4 is a schematic view of the water feeder of the present invention with different water outlet modes;

fig. 5 is a schematic structural view of an embodiment of the first blocking member, the second blocking member and the third blocking member of the present invention;

fig. 6 is a schematic structural view of an embodiment of the water outlet member of the present invention;

FIG. 7 is a schematic structural view of an embodiment of the filter assembly of the present invention;

fig. 8 is an exploded view of the filter assembly of the present invention;

FIG. 9 is a schematic cross-sectional view taken in the direction B-B of the filter assembly of FIG. 7;

FIG. 10 is an enlarged, fragmentary schematic view of the filter assembly of FIG. 9;

fig. 11 is a schematic structural view of an embodiment of a first filter housing according to the present invention;

FIG. 12 is a schematic diagram of a drinking water chamber and filter assembly according to an embodiment of the present invention;

FIG. 13 is a schematic structural view from below of the water feeder of FIG. 1.

Detailed Description

To make the objects, technical solutions and advantages of the present invention clearer, embodiments of the present invention are combined to clearly and completely describe the technical solutions in the embodiments of the present invention, and obviously, the described embodiments are some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention. The embodiments described below and the features of the embodiments can be combined with each other without conflict.

In order to solve the problems that the oxygen content in the water feeder in the prior art is less and the foreign matters are easily accumulated at the drinking water position of the water feeder, an embodiment of the utility model provides a water feeder. The water feeder comprises a shell, a water storage cavity and a water drinking cavity; the filtering component is communicated with the drinking water cavity; the water pump is arranged in the water storage cavity, the nozzle is arranged in the drinking water cavity, and the water pump is connected with the nozzle through the conveying pipeline; the nozzle comprises a first nozzle part facing a preset direction, so that water flow output from the first nozzle part flows spirally in the drinking cavity, and the preset direction is perpendicular to the radial direction of the drinking cavity at the position of the first nozzle part. As described in detail below.

Referring to fig. 1-4, fig. 1 is a schematic structural diagram of an embodiment of a water feeder of the present invention, fig. 2 is a schematic structural diagram of an explosion of the water feeder shown in fig. 1, fig. 3 is a schematic structural diagram of a cross section of the water feeder shown in fig. 1 in a direction a-a, and fig. 4 is a schematic diagram of different water outlet modes of the water feeder of the present invention.

In one embodiment, the water feeder of the utility model can be applied to pet feeding in daily households, or large-scale and systematic livestock, poultry feeding and the like. The following description will be given by taking a water feeder applied to pet feeding in daily households as an example.

The water feeder comprises a shell 1, a filtering component 2, a water pump 3, a nozzle 4 and a conveying pipeline 5. The shell 1 is used as a basic carrier of the water feeder and plays a role in bearing and protecting various parts of the water feeder, and the shell 1 comprises a drinking water cavity 111 for drinking water for pets and a water storage cavity 112 for storing drinking water.

The filter assembly 2 is in communication with the drinking water chamber 111 for filtering water stored in the water bowl, thereby making the water for the pet to drink cleaner.

Water pump 3, pipeline 5 and nozzle 4, water pump 3 locates water storage chamber 112, and drinking water chamber 111 is located to nozzle 4, and water pump 3 and nozzle 4 pass through pipeline 5 and connect. That is, the water pump 3 is connected to the nozzle 4 through the transfer line 5, and water in the water storage chamber 112 can be transferred to the nozzle 4 through the transfer line 5, and further water passing through the transfer line 5 is output from the nozzle 4 to the drinking water chamber 111.

The nozzle 4 comprises at least one first nozzle portion, which is oriented in the predetermined direction P, so that the water flow outputted from the first nozzle portion flows in a spiral shape in the drinking water chamber 111. For example, FIG. 4a shows the first nozzle portion 41, and FIG. 4b shows the first nozzle portion 42.

In this embodiment, when the water bowl during operation, water pump 3 passes through conveying line 5 with the water in the water storage chamber 112 and carries to nozzle 4, exports water to drinking water chamber 111 by nozzle 4, that is to say the utility model discloses a water bowl can provide the drinking water of flow state, and the drinking water that is in flow state can increase oxygen content wherein, avoids being infected with the filth and breeding the bacterium as far as possible to be favorable to improving the enthusiasm of pet drinking water.

The first nozzle portion is capable of directing the water flow outputted from the first nozzle portion in a spiral shape in the drinking water chamber 111 in the predetermined direction P. That is, when the water feeder is operated, the drinking water outputted from the first nozzle portion flows spirally in the drinking water chamber 111. The drinking water flowing spirally can be in more full contact with air, and the oxygen content in the water in the drinking water cavity 111 can be further increased; the water flow can cover most of the surface of the drinking water cavity 111 as much as possible, so that foreign matters remained in the drinking water cavity 111 can be washed, the cleanness of the drinking water cavity 111 can be kept, and the cleanness of drinking water for pets can be further ensured; and the drinking water that the heliciform flows can reduce the noise that rivers produced to avoid the pet to receive the frightening and influence the pet and normally drink water because of the noise.

Please refer to fig. 4 a. In an embodiment, the predetermined direction P is arranged at an angle to a first reference plane δ, which is defined by the radial direction D1 of the drinking water chamber at the location of the first nozzle portion and the axial direction Z of the drinking water chamber, i.e. the radial direction D1 of the drinking water chamber at the location of the first nozzle portion and the axial direction Z of the drinking water chamber are on the first reference plane δ. The following description will take the predetermined direction P perpendicular to the first reference plane δ in fig. 4a as an example, which is only for illustration and not intended to limit the predetermined direction P.

It should be noted that the number of the first nozzle parts included in the water feeder may be one, two, three, four, five, etc., and is not limited herein. Wherein the orientation of each first nozzle portion may be different, but should be arranged at an angle to the first reference plane δ. The following description will be given by taking an example in which the water feeder includes two first nozzle portions, that is, the water feeder includes the first nozzle portion 41 shown in fig. 4a and the first nozzle portion 42 shown in fig. 4b, which are only necessary for discussion, and the number of the first nozzle portions is not limited thereby.

Please continue to refer to fig. 1-4. In one embodiment, the nozzle 4 comprises a first nozzle portion 41 and a first nozzle portion 42, the orientation of the first nozzle portion 42 is opposite to the orientation of the first nozzle portion 41, the water flow output by the first nozzle portion 41 flows in a spiral shape in the drinking water cavity 111, as shown in fig. 4a, and the water flow output by the first nozzle portion 42 flows in a spiral shape in the drinking water cavity 111, as shown in fig. 4 b. Wherein the first nozzle portion 41 and the first nozzle portion 42 can be selectively used to supply water to the drinking water chamber 111.

Optionally, the nozzle 4 further includes a first blocking member 411 and a first blocking member 421, as shown in fig. 5, the first blocking member 411 and the first nozzle portion 42 are respectively disposed on the first nozzle portion 41 and the first nozzle portion 42, and by combining the first blocking member 411, the first nozzle portion 41, the first blocking member 421 and the first nozzle portion 42, the first nozzle portion 41 and the first nozzle portion 42 can be selectively used for supplying water to the drinking water cavity 111, so that a water outlet manner of the water feeder is increased, and a user can set a water outlet manner of the water feeder according to his own needs, thereby increasing selectivity and interest of the water feeder, and also improving enthusiasm of drinking water for pets.

For example, the first nozzle 41 is blocked by the first blocking member 411, and the first nozzle 42 is conducted, so that water can be supplied to the drinking water chamber 111 only through the first nozzle 42. When the first nozzle portion 42 is blocked by the first blocking member 421 and the first nozzle portion 41 is conducted, the water is supplied to the drinking water chamber 111 only through the first nozzle portion 41. Of course, if neither the first nozzle 41 nor the first nozzle 42 is blocked, the first nozzle 41 and the first nozzle 42 can supply water to the drinking chamber 111 at the same time.

Please continue to refer to fig. 1, fig. 2 and fig. 3. In one embodiment, the nozzle 4 further comprises a second nozzle portion 43, the second nozzle portion 43 faces the radial direction D3 of the drinking water cavity 111 at the position of the second nozzle portion 43, and the second nozzle portion 43 has a plurality of water outlet holes, so that the water output by the second nozzle portion 43 can flow to the drinking water cavity 111 in a fan-shaped fine jet manner, as shown in fig. 4 c. The first nozzle part 41, the first nozzle part 42 and the second nozzle part 43 are selectively used for supplying water to the drinking water cavity 111, the water outlet mode of the water feeder is further increased, and a user can set the water outlet mode of the water feeder according to the requirement of the user, so that the selectivity and the interestingness of the water feeder are increased, and the enthusiasm of pet drinking water can be improved.

Thus, the nozzle 4 also comprises a first obturating member 411, a first obturating member 421 and a second obturating member 431, as shown in fig. 5; the first nozzle part 41, the first nozzle part 42 and the second nozzle part 43 can be selectively used for supplying water to the drinking water cavity 111 by combining the first blocking member 411, the first nozzle part 41, the first blocking member 421, the first nozzle part 42, the second blocking member 431 and the second nozzle part 43. The detailed description is similar to that described in the above embodiments and will not be repeated here.

Further, the second nozzle portion 43 is provided with a water outlet member 432, and the structure of the water outlet member 432 is shown in fig. 6; the water outlet member 432 is disposed at one side of the second nozzle portion 43 facing the radial direction of the drinking water cavity 111, the water outlet member 432 has a plurality of water outlet holes, which may be a plurality of circular through holes disposed on the water outlet member 432, as shown in fig. 6; the water outlet holes of the water outlet member 432 are used for outputting water to the drinking water cavity 111 in a fan-shaped fine jet manner.

Optionally, if the user selects to discharge water into the drinking water chamber 111 through the second nozzle portion 43, the water discharge member 432 may be installed on the second nozzle portion 43 to discharge water into the drinking water chamber 111 through the fan-shaped fine jet; if the user does not want to discharge the water from the second nozzle portion 43, the second stopper 431 may be attached to the second nozzle portion 43 so that the user can select whether to discharge the water using the second nozzle portion 43.

Through the water outlet mode of the first nozzle part 41, the first nozzle part 42 and the second nozzle part 43, the noise generated by the water flow output to the drinking water cavity 111 can be reduced, and the phenomenon that the normal drinking water of the pet is influenced and even the stress reaction of the pet is caused because the pet is frightened by the noise is avoided; meanwhile, the water in the drinking cavity 111 flows spirally and flows in a fan-shaped fine jet flow mode, so that the water flowing to the drinking cavity 111 can be fully contacted with air, and the oxygen content in the water in the drinking cavity 111 can be further increased; meanwhile, the water flow can cover the surface of the most part of the drinking water cavity 111 as far as possible, so that the residual foreign matters in the drinking water cavity 111 can be washed, the cleanness of the drinking water cavity 111 can be kept, and the cleanness of drinking water of pets can be further ensured.

In the use scene of water bowl, for guaranteeing that the pet drinking water can be cleaner health, avoid the pet to be sick because of the quality of water problem, the filter assembly 2 of water bowl can filter the water by drinking water chamber 111 flow direction water storage chamber 112 in for the water at the water bowl inner loop keeps clean, the utility model discloses a filter assembly 2 can be through strict seal structure, avoids water to flow back and lead to filtering insufficient condition to appear in the structure gap of water bowl, thereby improves filter assembly 2's filter effect.

Referring to fig. 7 and 8, fig. 7 is a schematic structural diagram of an embodiment of the filter assembly of the present invention, and fig. 8 is a schematic structural diagram of an explosion of the filter assembly of the present invention.

In an embodiment, the filtering component 2 in the water feeder of the utility model can also be applied to daily houses of human beings, or large-scale and systematic filtering engineering and the like. The following description will be given by taking a water feeder applied to pet feeding as an application environment.

The filter assembly 2 comprises a first filter housing 21, a filter member 22 and a second filter housing 23, wherein the filter member 22 is clamped between the first filter housing 21 and the second filter housing 23 for filtering the liquid flowing from the first filter housing 21 to the second filter housing 23; wherein the filter element 22 is sealingly connected to the first filter housing 21.

In this embodiment, the filter assembly 2 can achieve full-retention filtration by the sealing connection between the filter element 22 and the first filter housing 21, i.e. the water passing through the first filter housing 21 can flow to the second filter housing 23 after passing through the filter element 22.

In this way, after the liquid passes through the first filter housing 21, the filter element 22 can filter impurities in the water when passing through the filter element 22, wherein the filter element 22 is hermetically connected to the first filter housing 21, so that the liquid is difficult to flow out from a gap between the filter element 22 and the first filter housing 21, the liquid passes through the filter element 22 as much as possible and receives the filtering effect of the filter element 22, and the filtering effect of the filter assembly 2 can be improved. If it is possible to prevent water from flowing back through the gap between the first filter housing 21 and the filter member 22, there occurs a case where the unfiltered water directly flows into the second filter housing 23, resulting in impurities existing in the water flowing back to the water storage chamber 112 through the second filter housing 23.

The liquid filtered by the filtering component 2 may be water, or other various solutions, etc., and the filtering liquid is specifically exemplified as water in the following by taking the filtering liquid as water, taking the above-mentioned water feeder applied to pet feeding in daily households as an example.

Referring to fig. 7 to 11, fig. 9 is a schematic sectional view of the filter assembly shown in fig. 7 along a direction B-B, fig. 10 is a partially enlarged schematic view of the filter assembly shown in fig. 9, and fig. 11 is a schematic structural view of an embodiment of a first filter housing according to the present invention.

In one embodiment, the first filter housing 21 is annular in shape and encloses an over-flow region 211, as shown in FIG. 11. The filter member 22 includes a filter portion 221 and a first connection portion 222 surrounding the outer circumference of the filter portion 221, the over-flow region 211 can expose the filter portion 221 of the filter member 22 so that water to be filtered flows to the filter portion 221 through the over-flow region 211, and the filter portion 221 can be used to filter the water flowing from the first filter housing 21 to the second filter housing 23.

That is, the water flowing back from the drinking water chamber 111 to the water storage chamber 112 can be achieved by the structure in which the overcurrent area 211 exposes the filter portion 221 of the filter member 22, reaches the filter portion 221 of the filter member 22 through the overcurrent area 211 of the first filter housing 21, and then is filtered by the filter portion 221 through the filter assembly 2.

Further, please refer to fig. 10 and fig. 11 in combination.

The first filter housing 21 is provided with a connecting groove 212, the notch of the connecting groove 212 faces the second filter housing 23, the first connecting portion 222 of the filter element 22 is inserted into the connecting groove 212, and the first connecting portion 222 is hermetically connected with the groove wall of the connecting groove 212. The design of the notch of the connection groove 212 towards the second filter housing 23 can avoid water accumulation at the connection of the filter element 22 and the first filter housing 21, further reduce the possibility of water backflow from the first filter housing 21 and the gap between the filter elements 22, further ensure that the filter assembly 2 realizes full interception and filtration, and improve the filtering effect of the filter assembly 2.

Specifically, the coupling groove 212 of the first filter housing 21 includes a first groove wall 2121, a second groove wall 2122, and a third groove wall 2123, the first groove wall 2121 and the second groove wall 2122 are disposed opposite to each other and spaced apart from each other, and the first groove wall 2121 and the second groove wall 2122 are connected by the third groove wall 2123 to form a groove facing the second filter housing 23.

Please continue to refer to fig. 9 and 10. In an embodiment, the first connection portion 222 is embedded in a groove space surrounded by the first groove wall 2121, the second groove wall 2122, and the third groove wall 2123, and the first connection portion 222 is connected to at least one of the first groove wall 2121, the second groove wall 2122, and the third groove wall 2123 in a sealing manner.

That is, the first connection portion 222 of the filter member 22 is sealingly connected to at least one groove wall of the first filter housing 21. Therefore, the filtering member 22 is hermetically connected to the first filtering housing 21, so that the water to be filtered is difficult to flow out from the gap between the filtering member 22 and the first filtering housing 21, that is, the water is filtered by the filtering member 22 through the filtering member 22 as much as possible, thereby avoiding the occurrence of insufficient filtering, facilitating the filtering assembly 2 to realize full interception and filtering, and improving the filtering effect of the filtering assembly 2.

Alternatively, the first slot wall 2121 may be located on a side of the second slot wall 2122 away from the over-flow region 211.

To further ensure the sealing connection between the first filter housing 21 and the filter element 22, the filter assembly 2 further includes a sealing element 24, and one side of the first connecting portion 222 of the filter element 22 facing the first slot wall 2121 is provided with a sealing groove 2221, so that the sealing element 24 can be clamped between the sealing groove 2221 and the first slot wall 2121, further achieving the sealing connection between the first filter housing 21 and the filter element 22, and reducing the possibility of the filter assembly 2 having a gap, thereby further facilitating the filter assembly 2 to achieve full-retention filtration, and improving the filtering effect of the filter assembly 2.

Alternatively, the sealing member 24 may be a sealing ring or the like, and further, may be a silicone ring or the like. The silica gel ring has the characteristics of wide temperature application range, good sealing performance, good insulativity and the like, is not easy to be disturbed by the outside to cause quality change, and is a relatively ideal sealing material.

Wherein, when the sealing element 24 is a silicone ring, the sealing groove 2221 may be a semi-arc groove or the like. That is, the shape of the sealing groove 2221 should be adapted to the edge characteristics of the sealing element 24, so as to reduce the gap between the sealing groove 2221 and the sealing element 24 as much as possible, further improve the sealing effect of the filter assembly 2, and improve the filtering effect of the filter assembly 2.

Therefore, after the drinking water flows through the first filtering shell 21, the filtering member 22 can filter impurities in the water when passing through the filtering member 22, wherein the filtering member 22 is connected with the first filtering shell 21 in a sealing manner, so that the drinking water is difficult to flow out from a gap between the filtering member 22 and the first filtering shell 21, the drinking water is made to pass through the filtering member 22 and receive the filtering effect of the filtering member 22 as much as possible, thereby being beneficial to the realization of the filtering assembly 2 to realize the full interception and filtration, and improving the filtering effect of the filtering assembly 2.

Please continue to refer to fig. 8. In one embodiment, the filter portion 221 of the filter element 22 includes at least two filter subsections 2211, and the at least two filter subsections 2211 are sequentially spaced around the axial direction of the filter element 22.

Further, the filtering part 221 may be divided into at least two filtering sub-parts 2211 with the same size, and the filtering sub-parts 2211 may be filled with a substance having a filtering function, so as to filter the water passing through the filtering element 22. And since the filtering portion 221 includes at least two filtering subsections 2211, the space for the filling material in the filtering subsections 2211 to flow becomes smaller, that is, the filling material in each filtering subsection 2211 does not move with the water flow, so as to avoid uneven dispersion of the filling material in the filtering portion 221, so that the water passing through each filtering subsection 2211 can be fully filtered by the filtering element 22, and the filtering effect of the filtering assembly 2 is further improved.

In particular, in combination with the actual size of the filter portion 221, the filter portion 221 may also include three, four, five, six, as shown in fig. 8, or even more filter sub-portions 2211, and the fill composition within each filter sub-portion 2211 should be consistent.

Still further, the filter sub-portion 2211 includes a porous filter body and has at least one of weak acid ion exchange resin, activated carbon, and trace elements.

The porous filter body may be filter cotton, and preferably is filter cotton with a high-density microporous filter screen, and the specific structure and principle of the filter cotton belong to the understanding scope of those skilled in the art, and are not described herein again.

Specifically, at least one of the weak acid ion exchange resin, the activated carbon, and the trace elements included in the filter portion 2211 may be coated on the porous filter body.

Weak acid ion exchange resin can replace the heavy metal ion through filtering component 2's aquatic to can realize softening quality of water, and then can avoid the pet to form the calculus because of the quality of water problem in vivo.

The active carbon can adsorb the impurity of the aquatic through filtering component 2 to can get rid of the aquatic peculiar smell, promote the taste of the water of flow direction drinking water chamber 111, and then avoid the pet to be reluctant to drink water because of the peculiar smell.

The trace elements can adjust PH (alkalinity acidity) of water passing through the filter assembly 2, so that the alkalinity acidity of the drinking water is closer to an optimal value of the drinking water, and various trace elements required by pets, such as phosphorus, magnesium, iron, copper, manganese, zinc, iodine, selenium, and the like, can be released in the water. Alternatively, the filter sub-section 2211 may be selected to have a medical stone or the like containing a plurality of trace elements.

For example, the filter portion 2211 may include weak acid ion exchange resin, activated carbon and medical stone, and the above substances are wrapped by high-density microporous filter cotton. Optionally, the above substances are included in the form of a mixture with the high-density micro-porous screen filter cotton, so that the water passing through each of the filter sub-portions 2211 can be sufficiently filtered, thereby improving the filtering effect of the filter assembly 2.

In an alternative embodiment, the filter portion 221 may include only one filter sub-portion 2211, that is, the filter sub-portion 2211, i.e., the filter portion 221, is capable of filtering water passing through the filter assembly 2, thereby facilitating an increase in the filterable area of the filter element 22.

In a particular business, the manufacturer may sell filter assemblies 2 that include multiple filter elements 22, each filter element 22 including a different number of filter sub-portions 2211. For example, when sold with a water feeder or a filter assembly 2, 6 filter elements 22 are attached, each having one, two, three, four, five, six filter subsections 2211, and a user can select one filter element 22 to be installed in the filter assembly 2 according to his/her needs, and then can change the filter element 22 according to the needs. On the basis, other embodiments exist, and are not described herein again.

Please continue to refer to fig. 9 and 10. In an embodiment, the second filter housing 23 of the filter assembly 2 is provided with a second connecting portion 231 on a side facing the first filter housing 21, wherein the second connecting portion 231 is disposed opposite to the third slot wall 2123, and the second connecting portion 231 and the first slot wall 2121 are connected by screw-fitting, so that the first connecting portion 222 can be clamped between the third slot wall 2123 and the second connecting portion 231.

Of course, in other embodiments, the first filter housing 21 and the second filter housing 23 are also connected in a sealing manner by other means, such as a snap, a screw, etc., which are not limited herein.

Please continue to refer to fig. 9. In an embodiment, the second filter housing 23 further includes a receiving portion 232, and the receiving portion 232 is far away from the first filter housing 21 relative to the second connection portion 231. Wherein, the containing part 232 is provided with an overflowing part to allow the water filtered by the filter member 22 to flow out through the overflowing part.

Specifically, the overcurrent part includes a first overcurrent part 2321 and a second overcurrent part 2322. The first flow-passing portion 2321 may be disposed on the side arm of the accommodating portion 232, alternatively, the first flow-passing portion 2321 may be a longitudinally extending through slot or the like, as shown in fig. 7 and 9; the second flow-passing portion 2322 may be disposed at a side of the accommodating portion 232 away from the first filter housing 21, and optionally the second flow-passing portion 2322 may be a plurality of circular through holes, as shown in fig. 7 and 9.

Further, the accommodating portion 232 encloses and forms an accommodating space 2323 for accommodating a function pack (not shown). When passing through the second filter housing 23, the water filtered by the filter 22 can flow through the functional bag placed in the accommodating space 2323 of the accommodating part 232, so that the functionality of the water feeder is increased, and elements contained in the functional bag are added to the water flowing to the water storage cavity 112. Meanwhile, when the water amount in the water storage cavity 112 is large, the functional bag can be immersed in the water storage cavity 112, so that the water is rich in elements contained in the functional bag.

Alternatively, the functional bag may contain a substance or the like that can be used to improve the physical needs of the pet. For example, the functional bag is an alpha-12 bacteriostatic bag and the like, the alpha-12 bacteriostatic bag comprises a manganese-based compound, wherein manganese is an antibacterial catalyst element and can effectively inhibit escherichia coli, staphylococcus aureus, salmonella and the like, the escherichia coli and the salmonella can cause acute enteritis of the pet, and the staphylococcus aureus can cause dermatophytosis of the pet. That is, the α -12 antibacterial bag is placed in the accommodating space 2321, so that diseases such as acute enteritis and skin tinea of pets can be effectively prevented.

With continuing reference to fig. 7 and 12, fig. 12 is a schematic structural view of an embodiment of the drinking water chamber and the filter assembly of the present invention.

In one embodiment, the outer wall of the first filter housing 21 is provided with a catch 213, and the catch 213 extends in a direction away from the first filter housing 21, as shown in fig. 7; the drinking water chamber 111 is provided with a mounting portion 1111, and the first filter housing 21 is embedded in the mounting portion 1111, as shown in fig. 12. Wherein, the installation department includes dodging portion 1112 and catching groove 1113, dodges portion 1112 and outwards extends, and catching groove 1113 intercommunication dodges portion 1112 and extends along drinking water cavity 111's circumference.

The specific steps of mounting the first filter housing 21 and the drinking water chamber 111 are as follows:

in the process that the first filter housing 21 is inserted into the mounting portion 1111, the latch 213 is inserted into the avoiding portion 1112, and the first filter housing 21 and the drinking water chamber 111 are relatively rotated until the latch 213 abuts against the side of the avoiding portion 1112 far from the retaining groove 1113, that is, the latch 213 is inserted into the retaining groove 1113 from the avoiding portion 1112, and then the first filter housing 21 and the drinking water chamber 111 are mounted, that is, the filter assembly 2 is fixedly connected with the drinking water chamber 111. The structure based on the buckle 213 and the mounting portion 1111 is firm, so that the filter assembly 2 cannot be easily separated from the drinking water chamber 111, and the structure of the water feeder is firm.

Further, first filter housing 21 outer wall can be equipped with a plurality of buckles 213, and drinking water chamber 111 correspondingly sets up a plurality of installation parts 1111, for example two buckles 213 and two installation parts 1111, three buckle 213 and three installation parts 1111 etc to can make first filter housing 21 can with drinking water chamber 111 more closely link, and then make filter assembly 2 and drinking water chamber 111 can zonulae occludens, further avoid filter assembly 2 to break away from drinking water chamber 111 in the use.

Of course, in other alternative embodiments, the first filter housing 21 and the drinking water chamber 111 may be connected by other connection manners, and the purpose of tightly connecting the filter assembly 2 and the drinking water chamber 111 may be achieved, such as a threaded connection, which is not limited herein.

It can be seen from the above embodiment that, through the strict sealing connection structure of the filter assembly 2, the liquid is difficult to flow out from the gap of the filter assembly 2, the liquid is made to pass through the filter element 22 as much as possible and receives the filtering effect of the filter element 22, so that the water flowing into the filter assembly 2 from the drinking water cavity 111 can flow into the water storage cavity 112 cleanly, and the filtering effect of the water feeder can be improved.

Please refer to fig. 1, fig. 2 and fig. 3. In one embodiment, the drinking water chamber 111 may be provided with a plurality of backflow holes 1114, so that water in the drinking water chamber 111 can flow back to the water storage chamber 112 through the filter assembly 2 through the backflow holes 1114. The overcurrent area 211 of the first filtering shell 21 should completely cover the plurality of backflow holes 1114 of the drinking water cavity 111, so that the water flowing out of the backflow holes 1114 can completely pass through the first filtering shell 21, and then is filtered and flows back to the water storage cavity 112 through the filtering piece 22, thereby further promoting the filtering component 2 to realize the complete interception and filtration, and improving the filtering effect of the filtering component 2.

Optionally, the number of the backflow holes 1114 of the drinking water cavity 111 may be 9, for example, water in the drinking water cavity 111 cannot flow back in time when the backflow holes 1114 are too few, so that the water in the drinking water cavity 111 overflows the water feeder; the phenomenon that when the backflow hole 1114 is too much, the water backflow speed in the drinking water cavity 111 is too high, so that sufficient water cannot be stored in the drinking water cavity 111 for the pet to drink can also be avoided.

Please continue to refer to fig. 1, fig. 2 and fig. 3. In one embodiment, the delivery line 5 includes an intermediate line 51 and an outlet line 52.

In connection with the embodiment of the water feeder described above including the first nozzle portion 41, the first nozzle portion 42, and the second nozzle portion 43, the water outlet pipeline 52 includes the first water outlet 521, the first water outlet 522, the second water outlet 523, and the water inlet 524, wherein the water inlet 524 is located at an end of the water outlet pipeline 52 away from the first water outlet 521, the first water outlet 522, and the second water outlet 523. Wherein, the number of the water outlets of the water outlet pipeline 52 is adapted to the number of the nozzle parts of the nozzle 4.

Wherein the first water outlet 521 faces a predetermined direction (the same as the predetermined direction in the above-mentioned embodiments) to form the first nozzle portion 41; the first water outlet 522 is also directed to a predetermined direction, but the first water outlet 522 is directed to the opposite direction of the first water outlet 521, so as to form the first nozzle portion 42; the second water outlet 523 faces a radial direction of the drinking water chamber 111 where it is located to form the second nozzle part 43.

Alternatively, the water outlet line 52 may be a tee or the like, such as a tee. As the name implies, a tee has three through holes, at least serving as an inlet and two outlets, and a through hole can be opened where the two pipes converge to form a third outlet.

Further, the intermediate pipe 51 is connected to the water inlet 524 of the water outlet pipe 52 and the water pump 3, respectively. The intermediate pipeline 51 can convey the water pumped by the water pump 3 to the water outlet pipeline 52, and the water flows to the drinking water cavity 111 through the nozzle 4 for the pet to drink through the first water outlet 521, the first water outlet 522 and the second water outlet 523 of the water outlet pipeline 52 in combination with the operation of the first nozzle part 41, the first nozzle part 42 and the second nozzle part 43 in the above embodiments.

For example, the water inlet 524 of the intermediate pipe 51 and the water outlet pipe 52 and the water pump 3 may be assembled through the bone site. In other alternative embodiments, the water inlet 524 of the intermediate pipeline 51 and the water outlet pipeline 52 and the water pump 3 may be connected by threads, screws, etc., and are not limited herein.

Please continue to refer to fig. 1, fig. 2 and fig. 3. In an embodiment, the housing 1 comprises a first housing 11 and a second housing 12, the first housing 11 being nested in the second housing 12. Wherein, a water storage cavity 112 and a drinking water cavity 111 of the water feeder are formed based on the structure of the first shell 11, and an accommodating cavity 121 is formed between the first shell 11 and the second shell 12.

Further, the water feeder further comprises a circuit assembly 7, and the circuit assembly 7 is accommodated in the accommodating cavity 121 between the first shell 11 and the second shell 12.

Optionally, the first housing 11 and the second housing 12 may be an integrally formed structure, and the integrally formed structure can reduce the existence of a gap between the first housing 11 and the second housing 12, so that the accommodating cavity 121 can be isolated from water in the water storage cavity 112, and further, the circuit component 7 can be prevented from being damaged by water entering.

In other alternative embodiments, the first housing 11 and the second housing 12 may be two parts, and the accommodating cavity 121 may be formed by strict sealing connection.

Please continue to refer to fig. 1, fig. 2 and fig. 3. In one embodiment, the first housing 11 is transparent, the second housing 12 is provided with a water level observation window 6 to observe the residual water amount in the water storage cavity 112 through the water level observation bed, one end of the water level observation window 6 far away from the drinking water cavity 111 is flush with one end of the water pump 3 facing the drinking water cavity 111, and a user can visually know the current residual water amount of the water feeder through the water level observation window 6 so as to timely supplement water into the water feeder when the water amount is insufficient.

Specifically, the water level observation window 6 may be marked with a highest water level scale and a lowest water level scale, and the highest water level scale and the lowest water level scale may be water levels required by the water feeder during normal operation, that is, a minimum amount of water and a maximum amount of water for a user to add water to the water feeder.

Wherein, the highest water level scale is not higher than the filtering member 22, so as to avoid the insufficient filtration of the water flowing into the filtering member 22 from the drinking water cavity 111; the lowest water level should not be less than the water pump 3 towards the one end of drinking water chamber 111, avoids water pump 3 not to submerge in the water completely, leads to water pump 3 during operation high temperature or even water pump 3 to appear dry combustion method, has the potential safety hazard.

Further, can select the water pump 3 that has the water level detection function, water pump 3 can detect its water level height on every side promptly to when the water level is less than minimum water level scale promptly water pump 3 towards the one end of drinking water chamber 111, water pump 3 automatic control stop work, in order to prevent that water pump 3 from burning futilely, thereby can further guarantee the security of water bowl.

Based on the above example that the first housing 11 and the second housing 12 are integrally formed, the housing 1 may be made of a transparent material, and the rest of the second housing 12 except the water level observation window 6 is subjected to surface covering treatment, so as to shield the structure in the accommodating cavity 121, thereby making the appearance of the water feeder more concise.

Please continue to refer to fig. 1, fig. 2 and fig. 3. Since there may be a case where the user fails to clean the water dispenser within the recommended time for any reason or does not replace the water in the water storage chamber 112 for a long time, a large amount of pet hair may remain in the drinking water chamber 111, entangle and block the backflow hole 1114 of the drinking water chamber 111, and continuously move the blocking filter assembly 2 downward by water flow flushing, thereby affecting the backflow rate of the water in the drinking water chamber 111, or even overflow of the water from the drinking water chamber 111 due to too slow backflow rate, how to detect and control the amount of the water in the drinking water chamber 111 should be considered.

In an embodiment, the circuit assembly 7 includes a water level sensor 71, the water level sensor 71 is disposed in a portion of the accommodating cavity 121 corresponding to the drinking water cavity 111 for detecting a water level of the drinking water cavity 111, wherein when the water level of the drinking water cavity 111 is higher than the water level sensor 71, the water pump 3 stops delivering the water in the water storage cavity 112 to the drinking water cavity 111.

Specifically, when the water level of the drinking water cavity 111 is higher than the end of the water level sensor 71 away from the water storage cavity 112 (i.e. the upper end of the water level sensor 71 when the water feeder is correctly placed), the water pump 3 controls to stop conveying the water in the water storage cavity 112 to the drinking water cavity 111, so as to avoid the water in the drinking water cavity 111 from increasing continuously and overflowing, and the trouble of cleaning the wetted room by the user is avoided. At this time, the water in the drinking water chamber 111 gradually flows back to the water storage chamber 112, the water level sensor 71 continuously detects the water level in the drinking water chamber 111 until the water level is lower than the end of the water level sensor 71 facing the water storage chamber 112 (i.e. the lower end of the water level sensor 71 when the water feeder is correctly placed), and the water pump 3 is started again to deliver the water in the water storage chamber 112 to the drinking water chamber 111.

Alternatively, the water level sensor 71 may be a water level detection chip with a water level detection function, and the specific working principle of detecting the water level in the container by the water level detection chip belongs to the understanding scope of those skilled in the art, and will not be described herein again.

Please continue to refer to fig. 1, fig. 2 and fig. 3. In an embodiment, the circuit assembly 7 further includes a distance sensor 72, and the distance sensor 72 is disposed in the accommodating cavity 121 and is used for detecting whether an object is close to the water feeder; the water pump 3 has a first power when the distance sensor 72 detects that an object is near the water feeder, and the water pump 3 has a second power when the distance sensor 72 does not detect that an object is near the water feeder, wherein the first power is greater than the second power.

That is, when the distance sensor 72 does not detect that the pet is close to the water feeder, the water pump 3 delivers water to the drinking water chamber 111 at a low pumping speed by the second power, so that the water feeder can continuously operate while reducing the power consumption of the water feeder, and the water in the water feeder circulates to increase the oxygen content in the water, reduce the possibility that the water in the water feeder is contaminated with dirt or breed bacteria, and increase the interest of the pet in drinking water.

When the distance sensor 72 detects that the pet is close to the water feeder, the water pump 3 is switched to the first power to operate, that is, the water pump 3 is gradually increased to a higher water pumping speed at a low water pumping speed to deliver water to the drinking water cavity 111, so that sufficient water is ensured to be provided for the pet to drink in the drinking water cavity 111.

Alternatively, the distance sensor 72 may be a PIR (Passive Infrared detector), etc., and the principle of the PIR detecting whether the pet is close to the water feeder belongs to the understanding scope of those skilled in the art, and will not be described herein.

Of course, in an alternative embodiment, when the distance sensor 72 does not detect that the pet is close to the water feeder, the water pump 3 may stop supplying water to the drinking water chamber 111, further reducing the power consumption and prolonging the service life of the water feeder.

Please continue to refer to fig. 1, fig. 2 and fig. 3. In an embodiment, the circuit assembly 7 further includes a second circuit board 73 disposed in a portion of the accommodating cavity 121 corresponding to the drinking water cavity 111, and the water level sensor 71 and the distance sensor 72 may be integrated on the second circuit board 73, so as to facilitate simplifying a circuit structure of the water feeder and avoid a redundant circuit structure in the water feeder.

Alternatively, the second Circuit Board 73 may be a PCB (Printed Circuit Board) or the like. Further, the second circuit board 73 can be fixed in the accommodating cavity 121 by fixing means such as bone position, and in order to further fix the second circuit board 73, the second circuit board 73 can be fixed in the bone position by gluing on the basis.

Please continue to refer to fig. 1, fig. 2 and fig. 3. In one embodiment, the circuit assembly 7 includes a first circuit board 74, the first circuit board 74 being used to control the operation of the various components of the water feeder, and a second circuit board 73 electrically connectable to the first circuit board 74. Optionally, the second circuit board 73 and the first circuit board 74 may be connected by a flexible flat cable, and the number and the distance of the wires of the flexible flat cable may be arbitrarily selected, so that the connection between the second circuit board 73 and the first circuit board 74 is more convenient, the volume of the circuit structure in the water feeder is reduced, and the production cost can be reduced.

For example, the flexible flat cable between the second circuit board 73 and the first circuit board 74 can avoid the water level observation window 6, so that the water level observation window 6 does not expose the internal structure of the water feeder, thereby increasing the aesthetic property of the appearance of the water feeder. The first Circuit Board 74 may be a Printed Circuit Board (PCB) or the like.

Further, the first circuit board 74 is integrated with a communication circuit (not shown) for information interaction with the mobile terminal of the user.

Specifically, the mobile terminal can be connected with the water feeder through a wireless network or a mobile network, a user can install corresponding APP (Application) at the mobile terminal, and the mobile terminal can be connected with a communication circuit of the water feeder through a communication protocol, so that data interaction between the mobile terminal APP and the water feeder is realized. The carrier of the communication protocol includes but is not limited to WiFi, 3G, 4G, 5G, etc.

The user can set up 3 pump water speeds of water pump at APP to and infrared distance inspection sensor's the working method of control water pump 3 etc.. In the above embodiment, it has been specifically described that the water pumping speed of the water pump 3 is controlled to be changed between the low speed and the high speed by the distance sensor 72, and the user can also specifically set the low speed and the high speed of the water pump 3 for pumping water, and the time for switching between the low speed and the high speed, respectively, on the APP.

Meanwhile, the user can set up the start-up and the stop that distance sensor 72 can control water pump 3 on APP, and distance sensor 72 detects that water pump 3 just starts when the pet is close to the water bowl promptly to can reduce power consumption, and prolong the life of water bowl.

The user can also set that when the water level sensor 71 detects that the water level of the drinking water cavity 111 is higher than the water level sensor 71, the APP can send out corresponding prompt information.

Further, when the water level in the drinking water chamber 111 is higher than the water level sensor 71 for a plurality of times (the specific times can be set by the user), the APP can prompt the user that the current state of the water feeder can be checked, and send information containing timely cleaning or replacing the drinking water chamber 111 and the filter assembly 2, etc.

The user can also be at APP predetermined duration to when reaching predetermined duration, can remind the user to change the water in the water storage chamber 112, clean or change filter assembly 2 and wash the water bowl complete machine etc..

Meanwhile, APP can record the installation time of the filter assembly 2, the service time of the water pump 3 is increased after the filter assembly 2 is replaced away from a user, and the user can start the reminding of replacing the filter element next time in APP after the filter assembly 2 is replaced.

When the water level in the water storage cavity 112 is lower than the water pump 3, and the water pump 3 is automatically controlled to stop working, the APP can send a prompt for supplementing water into the water storage cavity 112 to a user.

And APP can record the complete service time of the water pump 3, and the user can contact the manufacturer to replace the water pump 3 before the service life of the water pump 3 expires, so that better continuous performance is provided at a more favorable price.

It should be noted that the above embodiments are only examples, and other ways of information interaction with the mobile terminal of the user may also exist, and are not described herein again.

Please continue to refer to fig. 1, fig. 2 and fig. 3. In one embodiment, the water feeder comprises a shielding piece 8, the shielding piece 8 is arranged on one side of the drinking water cavity 111 far away from the water storage cavity 112, and the orthographic projection of the shielding piece 8 on the second reference plane β covers the orthographic projection part of the drinking water cavity 111 on the second reference plane β; the drinking water cavity 111 is opposite to the water storage cavity 112, and the second reference plane β is perpendicular to the opposite direction of the drinking water cavity 111 and the water storage cavity 112.

When the water feeder is correctly placed, the second reference plane β is a horizontal plane, and an orthographic projection of the shielding member 8 on the second reference plane β at least should cover a portion of the orthographic projection of the nozzle 4 located in the drinking water cavity 111 on the second reference plane β, so that the shielding member 8 can shield a portion splashed out of water flowing from the nozzle 4 to the drinking water cavity 111, and the splashed out water is prevented from wetting rooms.

Please continue to refer to fig. 1, fig. 2 and fig. 3. In one embodiment, the water feeder further comprises a water pump cable 91, the water pump cable 91 being electrically connected to the first circuit board 74. In order to ensure the safe connection of the water pump 3 and the first circuit board 74, the water feeder further comprises a sealing joint 92, and the water pump 3 and the first circuit board 74 are connected through the sealing joint 92, so that the water is prevented from entering the circuit to cause safety accidents.

The water feeder also includes a DC (Direct Current) power line 93, the DC power line 93 being connectable to an external power source to supply power to the water feeder to maintain the water feeder in operation.

The water feeder also comprises a bottom shell 94, the bottom shell 94 being connected to the side of the housing 1 remote from the shutter 8, the bottom shell 94 being able to carry the water feeder. Alternatively, the bottom case 94 and the housing 1 are fixedly connected by screws or the like.

The water feeder further comprises a plurality of foot pads 95, and the foot pads 95 are mounted on one side of the bottom case 94 far away from the drinking water chamber 111 and used for increasing friction between the water feeder and the ground, so that the water feeder can be stably placed on the ground. Optionally, the number of the foot pads 95 is 4 (as shown in fig. 13), and the 4 foot pads 95 are disposed on a side of the bottom case 94 away from the drinking water cavity 111 at regular intervals.

To sum up, the utility model discloses water bowl during operation, water pump pass through conveying line with the water of water storage intracavity and carry to the nozzle, export water to drinking water chamber by the nozzle, that is to say exactly the utility model discloses a water bowl can provide the drinking water of mobile state, can increase the oxygen content in the drinking water, avoids being infected with the filth and breeding the bacterium as far as possible to and improve the enthusiasm of pet drinking water.

Besides, the drinking water output by the first nozzle part flows spirally in the drinking water cavity. The drinking water flowing spirally can be in more full contact with air, and the oxygen content in the water in the drinking water cavity can be further increased; the water flow can cover most of the surface of the drinking cavity as much as possible, so that foreign matters remained in the drinking cavity can be washed, the cleanness of the drinking cavity can be kept, and the cleanness of drinking water for pets can be further ensured; and the drinking water that the heliciform flows can reduce the noise that rivers produced to avoid the pet to receive the frightening and influence the pet and normally drink water because of the noise.

Meanwhile, the filter assembly comprises a first filter housing, a second filter housing and a filter element, wherein the filter element is clamped between the first filter housing and the second filter housing and is connected with the first filter housing in a sealing manner. Therefore, after the liquid flows through the first filtering shell, the impurity in the water can be filtered by the filtering piece when the liquid passes through the filtering piece, wherein the filtering piece is in sealing connection with the first filtering shell, so that the liquid can flow out from the gap between the filtering piece and the first filtering shell difficultly, the liquid can pass through the filtering piece as much as possible and can receive the filtering effect of the filtering piece, and the filtering effect of the filtering component can be improved.

Further, the water bowl includes three nozzle, and three nozzle can select the combination to use based on more enjoyment of pet and owner and change, and no matter the whirl spiral goes out water or fan-shaped thin efflux can both the biggest area cover the dish that absorbs water and accomplish pet large tracts of land drinking water, can clean the drinking water chamber of water bowl simultaneously to reduce the noise of rivers and drinking water chamber collision, reduce the surprise to the pet, thereby avoid the pet to fear and dare not to be close to.

Still further, the backward flow hole in the middle of drinking water cavity is passed through to the water of drinking water intracavity, flows into and to intercept filterable filtering component entirely, based on filtering component's each parts sealing connection's structural design for the backward flow liquid can play and intercept and filter disinfection and sterilization entirely. Meanwhile, the function bag can be placed in the reserved space of the second filtering shell, and the pet can be fully enabled to drink water healthily.

The water feeder also has a water level detection function, and when the water level in the water drinking cavity exceeds the water level sensor, the water pump stops working automatically. When the water level is lower than the water level sensor, the water pump is started again to pump water, so that the problem that water overflows the water feeder to cause wetting of floors or carpets and the like is avoided.

And, the water bowl can also detect whether the pet is close to, can be when the pet is not close to the water bowl drinking water, the low-speed pump water of water pump, it can to keep little rivers to attract the pet, when the pet is close to the water bowl drinking water, the water pump begins to promote the pumping speed gradually, increases the water yield by the nozzle outflow, also can wash the suction disc comprehensively when the pet of being convenient for drinks water to can reduce power consumption and prolong the life of water pump. The amount of filtered water of the filter assembly can also be reduced, thereby also extending the life of the filter assembly.

Furthermore, in the present invention, unless otherwise expressly specified or limited, the terms "connected," "stacked," and the like are to be construed broadly, e.g., as meaning permanently connected, detachably connected, or integrally formed; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention.

Claims (10)

1. A water feeder, characterized in that the water feeder comprises:

the shell comprises a water storage cavity and a drinking water cavity;

the filter assembly is communicated with the drinking water cavity;

the water pump is arranged in the water storage cavity, the nozzle is arranged in the drinking water cavity, and the water pump is connected with the nozzle through the conveying pipeline;

the nozzle comprises at least one first nozzle part, and the first nozzle part faces to a preset direction, so that the water flow output by the first nozzle part flows in a spiral shape in the drinking water cavity.

2. The water feeder as recited in claim 1, wherein the predetermined direction is disposed at an angle to a first reference plane defined by a radial direction of the drinking chamber at a location of the first nozzle portion and an axial direction of the drinking chamber.

3. The water feeder as claimed in claim 2, wherein the nozzle comprises a second nozzle portion directed radially of the drinking chamber at its location, the second nozzle portion having a plurality of water outlet apertures, the first and second nozzle portions being selectively operable to supply water to the drinking chamber.

4. The water feeder as defined in claim 3,

the conveying pipeline comprises a middle pipeline and a water outlet pipeline, the middle pipeline is respectively connected with a water inlet of the water outlet pipeline and the water pump, and one end of the water outlet pipeline, which is far away from the water inlet, is provided with a first water outlet and a second water outlet;

the first water outlet faces the preset direction to form the first nozzle part, and the second water outlet faces the radial direction of the drinking cavity at the position of the first water outlet to form the second nozzle part.

5. Water feeder according to any one of claims 1 to 4,

the shell comprises a first shell and a second shell, the first shell is nested in the second shell, the first shell comprises the water storage cavity and the drinking water cavity, and an accommodating cavity is formed between the first shell and the second shell;

the water feeder comprises a circuit assembly, and the circuit assembly is accommodated in the accommodating cavity.

6. The water feeder according to claim 5, wherein the circuit assembly comprises a water level sensor disposed in a portion of the accommodating cavity corresponding to the drinking water cavity for detecting a water level of the drinking water cavity, wherein the water pump stops delivering the water in the water storage cavity to the drinking water cavity when the water level of the drinking water cavity is higher than the water level sensor.

7. The water feeder as defined in claim 5,

the circuit assembly comprises a distance sensor which is arranged in the accommodating cavity and used for detecting whether an object is close to the water feeder or not;

the water pump has a first power when the distance sensor detects that an object is close to the water feeder, and has a second power when the distance sensor does not detect that an object is close to the water feeder, wherein the first power is greater than the second power.

8. The water feeder of claim 5, wherein the circuit assembly comprises a first circuit board integrated with communication circuitry for information interaction with a mobile terminal of a user.

9. The water feeder as claimed in claim 5, wherein the first housing is transparent, the second housing is provided with a water level observation window for observing the residual water in the water storage cavity through the water level observation window, and one end of the water level observation window far away from the drinking water cavity is flush with one end of the water pump facing the drinking water cavity.

10. The water feeder as defined in claim 1,

the water feeder comprises a shielding piece, the shielding piece is arranged on one side of the drinking water cavity far away from the water storage cavity, and the orthographic projection of the shielding piece on a second reference plane covers the orthographic projection part of the drinking water cavity on the second reference plane;

the drinking water cavity and the water storage cavity are oppositely arranged, and the second reference plane is perpendicular to the relative direction of the drinking water cavity and the water storage cavity.

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