FILTRATION SYSTEM FOR PET WATER FOUNTAIN, AND METHOD FOR WATER FILTRATION

Abstract

A filtration system for a pet water fountain is provided. The filtration system utilizes a pump placed within or along a watering bowl. The water filtration system also utilizes a multi-stage filtering device. In one aspect, the multi-stage filtering device includes a first filtering stage representing copper zinc alloy particles, and a second filtering stage representing granulated activated carbon particles. Each stage may constitute filtering material that is separated into an array of cells residing along a vertical frame or is separated into stages placed in series within a tubular cartridge. A method for filtering water in a pet fountain is also provided herein.

Claims

1. A pet water fountain comprising: a basin configured to hold a volume of water accessible to a domesticated pet; a pump having a pump inlet and at least one pump outlet, the pump residing in a portion of the basin and being configured to circulate water within the basin when activated; and a multi-stage filtering device configured to filter water during circulation so as to (i) filter sediment and hair from the water, (ii) remove at least a portion of chlorine from the water, (iii) reduce bacteria in the basin, (iv) reduce soluble heavy metals in the water, and (v) control scale and algae in the basin.

2. The pet water fountain of claim 1, wherein: the domesticated pet is a dog or a cat; the pump is a submersible pump; and the pump resides within the basin.

3. The pet water fountain of claim 1, wherein: a first stage of the multi-stage filtration device comprises copper alloy particles; and a second stage of the multi-stage filtration device comprises granulated activated carbon particles.

4. The pet water fountain of claim 3, wherein: (i) the first stage resides near the pump inlet and the second stage resides near the pump outlet; (ii) the second stage resides near the pump inlet and the first stage resides near the pump outlet; (iii) both the first stage and the second stage reside near the pump inlet; or (iv) both the first stage and the second stage reside near the pump outlet.

5. The pet water fountain of claim 3, wherein: the first stage and the second stage together reside within a tubular body; a first porous screen resides along a first end of the tubular body; a second porous screen resides along a second, opposite end of the tubular body; and the first and second porous screens maintain the first and second stages in place within the tubular body during water circulation.

6. The pet water fountain of claim 5, wherein: the copper alloy is a copper zinc alloy; the tubular body is in fluid communication with the pump inlet or the pump outlet; and a third porous screen separates the first stage and the second stage.

7. The pet water fountain of claim 6, wherein: the tubular body holds at least two first stage compartments and at least two second stage compartments, with the first and second stage compartments alternating in series.

8. The pet water fountain of claim 3, wherein: the copper alloy particles are divided into portions placed along discreet cells within a frame to form the first stage; the granulated activated carbon particles are also divided into portions and are placed along discreet cells within a frame to form the second stage; the frames of each of the first and second stages are placed side-by-side and provide vertical support for the discreet cells; and the particles in the cells of each of the first and second stages are at least partially covered by a porous substrate, wherein the porous substrate defines discreet covers for closely holding particles within the cells of each of the first and second stages.

9. The pet water fountain of claim 8, wherein: the frames forming the first and second stages are positioned vertically within the water fountain between the pump outlet and a weir or a spout; a first screen is placed at an inlet side of the first stage; a second screen is placed at an outlet side of the second stage; a third screen is placed between the first and second stages; and the porous substrate comprises synthetic fibers, cellulosic fibers, or combinations thereof

10. The pet water fountain of claim 8, wherein the porous substrate is fabricated from woven fibers, non-woven fibers, or combinations thereof.

11. The pet water fountain of claim 8, wherein each of the cells of the first stage further comprises a salt.

12. The pet water fountain of claim 8, further comprising: a reservoir configured to receive a portion of the water delivered from a pump outlet during water circulation, and release water to a spout above the basin; and wherein the first stage, the second stage, or both, reside in vertical orientation within or adjacent to the reservoir.

13. A filtration system for a pet water fountain, wherein the pet water fountain comprises a basin configured to hold a volume of water accessible to a domesticated pet, and a submersible pump having a pump inlet and at least one pump outlet configured to circulate water within the basin, and the filtration system comprises: a first stage comprising a copper alloy filtering medium; and a second stage comprising a granulated activated carbon medium; and wherein the first stage and the second stage form two stages of a multi-stage filtering device configured to filter water during circulation so as to (i) filter sediment and hair from the water, (ii) remove at least a portion of chlorine from the water, (iii) reduce bacteria in the basin, (iv) reduce soluble heavy metals in the water, and (v) control scale and algae in the basin.

14. The filtration system of claim 13, wherein: the domesticated pet is a dog or a cat; the pump is a submersible pump that resides within the basin; and the multi-stage filtering device further (vi) adjusts the pH of the water (vii) reduces hydrogen sulfide, (viii) reduces organic and inorganic particles from the water, or (ix) combinations thereof

15. The filtration system of claim 14, wherein: the first stage and the second stage together reside within a tubular body; a first porous screen resides along a first end of the tubular body; a second porous screen resides along a second, opposite end of the tubular body; and the first and second porous screens maintain the first and second stages in place within the tubular body during water circulation.

16. The filtration system of claim 15, wherein: the tubular body is in fluid communication with the pump inlet or the pump outlet; a third porous screen separates the first stage and the second stage; and the copper alloy is a copper zinc alloy.

17. The filtration system of claim 16, wherein: the tubular body holds at least two first stage compartments and at least two second stage compartments, with the first and second stage compartments alternating in series and a screen separating each of the compartments.

18. The filtration system of claim 15, wherein: the copper alloy medium is comprised of copper alloy particles that are divided into portions and placed along discreet cells within a frame to form the first stage; the granulated activated carbon medium is comprised of activated carbon particles that are also divided into portions and placed along discreet cells within a frame to form the second stage; the frames of each of the first and second stages are placed side-by-side and provide vertical support for the discreet cells; the particles in the cells of each of the first and second stages are at least partially covered by a porous substrate, wherein the porous substrate defines discreet covers for closely holding particles of each of the first and second stages within the cells; and the porous substrate is fabricated from synthetic fibers, cellulosic fibers, or combinations thereof.

19. The filtration system of claim 18, wherein each of the cells of the first stage further comprises salt pellets.

20. The filtration system of claim 18, wherein the copper ally particles comprise between about 50% and 85% copper, and between about 15% and 50% zinc.

21. The filtration system of claim 18, wherein: the frames forming the first and second stages are positioned vertically within the water fountain between the pump outlet and a weir or a spout; a first screen is placed at an inlet side of the first stage; a second screen is placed at an outlet side of the second stage; and a third screen is placed between the first and second stages.

22. A method of filtering water for a pet water fountain, comprising: receiving a pet water fountain comprising: a basin configured to hold a volume of water accessible to a domesticated pet; a pump having a pump inlet and at least one pump outlet, the pump being configured to circulate water within the basin; and a multi-stage filtering device residing within the basin and configured to filter water during circulation so as to (i) filter hair from the water, (ii) remove at least a portion of chlorine from the water, (iii) capture inorganic solids, (iv) reduce micro-organisms, (v) reduce bacteria in the basin, (vi) reduce soluble heavy metals in the water, and (vii) control scale and algae in the basin. placing water into the basin; and providing electrical power to activate the pump and, thereby, circulate the water across the multi-stage filtering device.

23. The method of claim 22, further comprising: allowing a domesticated dog or cat to access the pet water fountain and drink from the basin.

24. The method of claim 22, wherein: a first stage of the multi-stage filtration device comprises copper alloy particles; and a second stage of the multi-stage filtration device comprises granulated activated carbon particles.

25. The method of claim 25, wherein: (i) the first stage resides near the pump inlet and the second stage resides near the pump outlet; (ii) the second stage resides near the pump inlet and the first stage resides near the pump outlet; (iii) both the first stage and the second stage reside near the pump inlet; or (iv) both the first stage and the second stage reside near the pump outlet.

26. The method of claim 25, wherein: the first stage and the second stage together reside within a tubular body; a first porous screen resides along a first end of the tubular body; a second porous screen resides along a second, opposite end of the tubular body; and the first and second porous screens maintain the first and second stages in place within the tubular body during water circulation.

27. The method of claim 27, wherein: the tubular body is in fluid communication with the pump inlet or the pump outlet; and a third porous screen separates the first stage and the second stage.

28. The method of claim 28, wherein: the copper alloy is a copper zinc alloy; the tubular body holds at least two first stage compartments and at least two second stage compartments, with the first and second stage compartments alternating in series.

29. The method of claim 22, wherein: the copper alloy particles are divided into portions and are placed along discreet cells within a frame to form the first stage; the granulated activated carbon particles are also placed along discreet cells within a frame to form the second stage; the frames of each of the first and second stages are placed side-by-side and provide vertical support for the discreet cells; and the particles in the cells of each of the first and second stages are at least partially covered by a porous substrate, wherein the porous substrate defines discreet covers for holding particles within the cells of each of the first and second stages.

30. The method of claim 29, wherein: the frames forming the first and second stages are positioned vertically within the water fountain between the pump outlet and a weir or a spout; a first screen is placed at an inlet side of the first stage; a second screen is placed at an outlet side of the second stage; a third screen is placed between the first and second stages; the porous substrate comprises synthetic fibers, cellulosic fibers, or combinations thereof; and the porous substrate is fabricated from synthetic fibers, cellulosic fibers, or combinations thereof

31. The method of claim 22, further comprising: receiving a replaceable filter cartridge that houses the first stage and the second stage together; and replacing the replaceable filter cartridge.

32. The method of claim 22, wherein the multi-stage filtering device further (viii) adjusts the pH of the water (ix) reduces hydrogen sulfide, or (x) combinations thereof.

33. The method of claim 22, wherein the pet watering fountain further comprises a reverse osmosis stage, an ion exchange system, or both.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0029] So that the manner in which the present inventions can be better understood, certain illustrations, photographs, charts and/or flow charts are appended hereto. It is to be noted, however, that the drawings illustrate only selected embodiments of the inventions and are therefore not to be considered limiting of scope, for the inventions may admit to other equally effective embodiments and applications.

[0030] FIG. 1A is a first perspective view of an animal watering fountain as may be used in connection with the multi-stage filtration system of the present invention. The view is taken from a right side of the fountain. No water is in the basin of the illustrative fountain.

[0031] FIG. 1B is another perspective view of the animal watering fountain of FIG. 1A. Here, the view is taken from a left side of the fountain. Water is placed in the fountain and a pump is activated, creating a spout of flowing water.

[0032] FIG. 1C is a perspective view of a portion of the housing from the animal watering fountain of FIGS. 1A and 1B. A cap has been removed from the housing, exposing a reservoir with a first stage of a filter.

[0033] FIG. 1D is another perspective view of FIGS. 1A and 1B. Here, the cap has again been removed from the housing. An illustrative filter is shown exploded from the reservoir.

[0034] FIG. 2A is a perspective view of a first stage of a filtering system, in one embodiment. Here, particles of copper zinc alloy are used as a medium.

[0035] FIG. 2B is a top view of the first stage of the filtering system of FIG. 2A. Here, a porous substrate has been placed over the copper zinc alloy particles to enshroud and to hold the particles in place.

[0036] FIG. 3A is a perspective view of a second stage of a filtering system, in one embodiment. Here, granulated activated carbon is used as a medium.

[0037] FIG. 3B is a top view of the second stage of the filtering system of FIG. 3A. Here, a porous substrate has been placed over the granulated activated carbon particles to enshroud and hold the particles in place.

[0038] FIG. 4 is a perspective, cross-sectional view of a multi-stage filter cartridge as may be used in a vertical filter system for a pet watering fountain. The filter cartridge comprises a frame that defines an array of cells.

[0039] FIG. 5 is a cut-away view of a filter cartridge as may be used for holding a multi-stage filter for a pet watering fountain, in one aspect.

[0040] FIG. 6 is a cut-away view of a portion of a filter cartridge as may be used for housing a multi-stage filter for a pet watering fountain, in another aspect.

[0041] FIG. 7 is a cross-sectional view of a tubular filtration device, showing granular activated carbon within a pouch.

[0042] FIG. 8A is a perspective view of a two-stage filter in one embodiment. Here, the filtration media are encased within a tubular body. A copper zinc alloy stage is visible as a porous substrate.

[0043] FIG. 8B is another perspective view of the two-stage filter of FIG. 8A, with the filter being flipped. Here, a granulated activated carbon stage is visible as a porous substrate.

[0044] FIG. 8C is a perspective, cross-sectional view of a two-stage filter with a tubular body, showing both first and second stage filtering media.

[0045] FIG. 9 is a perspective view of a filter cartridge in fluid communication with the outlet of a pump in accordance with one embodiment of the multi-stage filtration system.

DETAILED DESCRIPTION OF CERTAIN EMBODIMENTS

DEFINITIONS

[0046] For purposes of the present disclosure, it is noted that spatially relative terms, such as “up,” “down,” “right,” “left,” “beneath,” “below,” “lower,” “above,” “upper” and the like, may be used herein for ease of description to describe one element or feature's relationship to another element(s) or feature(s) as illustrated in the figures. It will be understood that the spatially relative terms are intended to encompass different orientations of the device in use or operation in addition to the orientation depicted in the figures. For example, if the device in the figures is turned over or rotated, elements described as “below” or “beneath” other elements or features would then be oriented “above” the other elements or features. Thus, the exemplary term “below” can encompass both an orientation of above and below. The device may be otherwise oriented (rotated 90 degrees or at other orientations) and the spatially relative descriptors used herein interpreted accordingly.

Description of Selected Specific Embodiments

[0047] A filtration system for a pet water fountain is provided herein. The filtration system utilizes a pump placed within or along a pet watering bowl. The watering bowl may be of any configuration and volume so long as a domesticated pet such as a dog or cat can access circulating aqueous contents therein.

[0048] FIG. 1A is a first perspective view of an illustrative animal watering fountain 100 as may be used with the filtration systems of the present invention. The view is taken from a right side of the fountain 100.

[0049] As illustrated, the pet water fountain 100 first has a watering bowl 110. The watering bowl 110 defines a radial wall 112 and an interior basin 115. The wall 112 and the basin 115 together hold an aqueous drinking liquid, such as water. In FIG. 1A, the bowl 110 is shown without water. However, FIG. 1B is offered wherein the bowl 110 is holding water.

[0050] FIG. 1B offers a second perspective view of the pet water fountain 100 of FIG. 1A. Here, the view is taken from the left side of the fountain 100. Water has been placed in the bowl 110. A pump (discussed below and shown in FIG. 9 at 950) has been activated, creating an aesthetically pleasing spout 105 of flowing water.

[0051] The pet water fountain 100 exists not only to hold water, but also to circulate that water so that it remains fresh and oxygenated. The flow of water from the pump (FIG. 9 at 950) may be split so that a first portion fills a reservoir and spills over through a spout 125, while a second portion circulates radially around the basin 115. In addition, the water is filtered so that it is maintained in a clean or substantially particle-free state.

[0052] In order to provide the circulation and filtering functions, various components are provided. Those components are generally held within a housing 130 and are not visible in FIGS. 1A and 1B. However, a few of the components are shown in FIGS. 1C and 1D, discussed below.

[0053] Referring again to FIGS. 1A and 1B together, the pet watering fountain 100 also includes an inlet port 122 and an outlet port 124. In the illustrative arrangement of FIGS. 1A and 1B, the inlet port 122 and the outlet port 124 are in the form of grates formed in the housing 130. Water is drawn into the housing 130 through the inlet port 122. A first portion of water is pumped into a reservoir (shown at 135 in FIGS. 1C and 1D) and released through the spout 125, while a second portion of water is pumped back into the basin 115 through the outlet port 124. The first portion of water falls from the spout opening 125, and falls back into the basin 115, creating an aesthetically pleasing arrangement for the owner and an object of interest for the animal.

[0054] Optionally, a splash ramp 126 is provided above the water level in the basin 115. This keeps water from splattering over the wall 112 and out of the watering bowl 110.

[0055] The animal watering fountain 100 is designed to provide water for an animal (not shown). The animal is ideally a domesticated dog or cat. The owner fills the basin 115 with water and then activates a pump (FIG. 9 at 950). Activation may mean simply plugging in a power cord 140. The pump 950 keeps water flowing through the housing 130 and back into the basin 115. Similarly, the pump 950 keeps water flowing through a reservoir (seen at 135 in FIGS. 1C and 1D), through the spout opening 125, and back into the basin 115.

[0056] FIG. 1C is a perspective view of a portion of the housing 130 from the pet watering fountain 100. Here, it can be seen that the housing 130 includes a removable cap 132. The cap 132 is shown separated from the housing 130, revealing a reservoir 135 within the housing 130. The reservoir 135 receives water from the pump (FIG. 9 at 950) when the pump 950 is activated, e.g., when the electrical cord 140 is plugged in. As the pump 950 operates, water is moved through a pump outlet 957, causing the water level in the reservoir 135 to rise.

[0057] FIG. 1C also reveals a filter 134 residing within the reservoir 135. The filter 134 is representative of one or both stages of the multi-stage filtering device described in further detail below, in one embodiment. The filter 134 divides the reservoir 135 into two compartments. Water flows from the pump 950 into a first compartment in front of the filter 134. The water then flows through the filter 134 and into the second compartment. As water fills the second compartment, it reaches the spout opening 125 of the housing 130. The spout opening 125 thus serves as a lip over which water flows down into the basin 115.

[0058] FIG. 1D provides another perspective view of the pet water fountain 100 of FIGS. 1A and 1B. Here, the cap 132 has been removed from the housing 130 and is not seen. In addition, the filter 134 has been removed from the housing 130. The filter 134 is shown exploded above the housing 130 for illustrative purposes.

[0059] FIG. 1D also more clearly shows the inlet port 122 and the outlet port 124 in the housing 130. In addition, the splash ramp 126 is seen below the spout opening 125.

[0060] It is understood that the fountain 100 presented in FIGS. 1A, 1B, 1C and 1D is merely illustrative. The present disclosure teaches a multi-stage filtering device that may be used with the fountain 100, or with any other pet fountain having a circulating pump 950.

[0061] In one aspect, the multi-stage filtering device includes a first filtering stage comprising copper zinc alloy particles and a second filtering stage comprising granulated activated carbon particles. Each stage may constitute filtering material that is separated into an array of material placed upon a grid having a frame. The frames are placed within respective porous pouches (or are covered by a porous substrate) that closely hold the filtering material within each cell of the array. The porous substrates with filtering media are secured to or otherwise held along the cells within the respective frames.

[0062] FIG. 2A is a perspective view of a first stage 200 of a filtering system, in one embodiment. Here, particles of copper zinc alloy 210 are used as a medium. A frame 220 divides the first stage 200 into discreet cells. A porous substrate has been removed for illustration revealing the particles 210. FIG. 2B is a top view of the first stage 200 of the filtering system. Here, the porous substrate 215 is placed over the copper zinc alloy particles.

[0063] The copper zinc alloy particles provide a bacteriostatic medium and also act to assist in raising the pH level of the treated water. This serves to “soften” the water during circulation. The alloy may be, for example, KDF 55 available from KDF Fluid Treatment, Inc. of Three Rivers, Mich. Alternatively, the alloy may be KDF 85 also available from KDF Fluid Treatment, Inc. Those of ordinary skill in the art will understand that municipal water supplies can contain calcium, magnesium, or other minerals that make water “hard.” Such minerals can form scale and cause a variety of problems in hardware. It is believed that the KDF alloy products will remove these minerals. KDF Fluid Treatment, Inc. has represented that its process media are also non-toxic. Some of the KDF alloy products are promoted as being able to remove mercury as well.

[0064] It is observed that other copper alloys 210 may be used as the first filtering medium 200. Copper alloys 210 are metal alloys that have copper as a principal component. Copper alloys 210 are known to have a high resistance against corrosion and are frequently used as a material for piping. The first filtering medium 200 may comprise brass particles, which is copper mixed with zinc and also sometimes tin or aluminum. The first filtering medium 200 may alternatively comprise copper-nickel-zinc particles. In embodiments comprising copper-zinc alloys 210, the filtering medium 200 may include 30% to 90% copper. One embodiment may comprise about 50% copper, while another embodiment may comprise about 85% copper. The filtering medium 200 preferably comprises between 70% to 10% zinc, inclusive. One embodiment may comprise about 50% zinc, while another embodiment may comprise about 15% zinc.

[0065] It is further observed that the first filtering medium 200 may include small amounts of salt, such as potassium chloride or sodium chloride. Softening salt pellets are available at many retail outlets. These salts will further act to soften the water during circulation.

[0066] A copper-zinc alloy 210 may be used as part of an oxidation reduction process, or electro-chemical reaction. During this reaction, electrons are transferred between molecules, and new elements are created. For example, chlorine is changed into benign, water-soluble chloride particles which are then filtered or harmlessly circulated. Similarly, some heavy metals such as lead and mercury are effectively removed from the water by plating out into the medium's surface.

[0067] FIG. 3A is a perspective view of a second stage 300 of a filtering system, in one embodiment. Here, granulated activated carbon particles 310 are used as a medium. A frame 320 divides the second stage 300 into discreet cells. A porous substrate has again been removed for illustration. FIG. 3B is another top view of the second stage 300 of the filtering system. Here, the porous substrate 315 is placed over the granulated activated carbon particles 310.

[0068] The granulated activated carbon medium 310 helps remove chlorine, lead, pesticides, and heavy metals from water. This, in turn, can improve the taste and odor of water sourced from municipal water supplies. The carbon filter granules 310 may be derived, for example, from coconut fiber. The coconut carbon helps stimulate adsorption and catalytic oxidation to remove chlorine and sediment from the circulating water. The granulated activated carbon medium 310 also serves as a carbon filter to remove, or at least reduce the presence of, certain sized physical and sediment impurities from the water. In one embodiment, the carbon filter granules can remove particles down to 5 microns in size and can also capture particles that may shelter living organisms from being fully exposed during an optional UV treatment process, described below.

[0069] In each of the first 200 and second 300 stages, a frame 220, 320 is used to support the particles 210, 310. The first stage filtration particles 210 are supported along frame 220 while the second stage filtration particles 310 are supported along frame 320. Each frame 220, 320 preferably comprises an array of cells. In the illustrative frames 220, 320, a 2×3 array of cells is shown. However, it is understood that other arrays may be considered.

[0070] In other embodiments, the first 200 and second 300 filtration particles may share a single frame. In such embodiments, the first filtration stage 200 may be disposed vertically along a front face of the frame, and the second filtration stage 300 may be disposed vertically along a back face of the frame, thereby allowing water to pass horizontally through the first 200 and second 300 filtration particles before consumption. Alternatively, the first 200 and second 300 filtration particles may be interspersed along both faces of a shared frame.

[0071] In any aspect, the first 200 and second 300 stages are illustrated together by filter 134.

[0072] It is again observed in FIGS. 2B and 3B that the particles 210, 310 are covered by the porous substrates 215, 315. The substrates 215, 315 may also represent pouches that receive particles 210, 310. In either instance, the porous substrates 215, 315 are disposed within respective cells inside the frames 220, 320, and closely hold the particles 210, 310.

[0073] It is noted here that the use of the terms “first stage” and “second stage” are not intended to imply a sequence or order of filtering; rather, these terms simply indicate that two separate filtering steps are being taken. Thus, in one aspect, water may first flow through a filtration medium comprised of copper zinc alloy particles 210, and then flow through a second filtration medium comprised of granulated activated carbon particles 310. Alternatively, water may first flow through a filtration medium comprised of granulated activated carbon particles 310 and then flow through a second filtration medium comprised of copper zinc alloy particles 210. Alternatively still, more than one layer (or medium) of copper zinc alloy particles 210 may be used and/or more than one layer (or medium) of granulated activated carbon particles 310 may be used.

[0074] It is also noted here that the use of the terms “circulate” or “circulation” are not intended to imply the movement of liquid only in a circular fashion. Instead, these terms are simply meant to indicate that the liquid will be pumped through specified areas of a basin or other areas of a watering fountain.

[0075] Both filtration media may reside proximate the water inlet 955 of the pump 950. Alternatively, both filtration media may reside proximate the water outlet 957 of the pump 950. Alternatively still, one filtration medium may reside proximate the pump 950 while the other resides in front of or within the reservoir 135.

[0076] FIG. 4 is a perspective, cross-sectional view of a multi-stage filter cartridge 400 as may be used in a vertical filter system for a pet watering fountain. The filter cartridge 400 comprises a frame 420 that defines an array of cells 410. The first stage 200 of filtration may be housed within the array of cells 410. As discussed in conjunction with FIGS. 2A and 2B, the first filtering stage 200 may comprise copper zinc alloy particles 210 that are encapsulated in a porous screen 215. In the FIG. 4 embodiment, a 2×12 array of cells is shown. However, it is understood that other arrays may be considered. The back portion of the filter cartridge 400 includes a compartment 430 for accommodation of the second stage 300 of filtration. As discussed in conjunction with FIGS. 3A and 3B, the second filtering stage 300 may comprise granulated activated carbon particles 310 that are encapsulated in a porous screen 315. The encapsulated active carbon particles 310 may be divided within discreet cells or may exist in a single cell that extends through the compartment 430.

[0077] In operation, the filter cartridge 400 of FIG. 4 may be disposed vertically within a watering fountain as generally shown at 134 of FIGS. 1C and 1D. When so disposed within the reservoir (135 at FIG. 1D), unfiltered water enters the filter cartridge 400 in the direction of arrow 405. Filtered water then exits the filter cartridge 400 in the direction of arrow 407, spills over the spout opening (shown at 125 of FIG. 1D) and flows into the basin (115 of FIG. 1B) for consumption.

[0078] FIG. 5 is a cut-away view of a filter cartridge 500 in an alternate embodiment as may be used for holding a filter for a pet watering fountain. The filter cartridge 500 comprises a cylindrical container 530 that is divided into a first housing 510A that accommodates the first filtering stage 200 and a second housing 510B that accommodates the second filtering stage 300. It is understood that the first housing 510A may alternatively accommodate the second filtering stage 300, and the second housing 510B may alternatively accommodate the first filtering stage 200. A permeable wall 520 may be disposed between the first 510A and second 510B housings. A similar cartridge may be designed that only holds a single filtering medium. Cartridges may also be designed to hold more than two filtering media.

[0079] The filter cartridge 500 may additionally include a mechanism 535 for reversibly attaching the filter cartridge 500 to the watering fountain or to reversibly join two halves of the filter cartridge 500. Such a mechanism 535 allows a user to replace the first 200 and second 300 filter stages without having to discard the filter cartridge 500. As shown, the mechanism 535 may comprise openings to receive respective screws. Additional mechanisms 535 may be employed for reversible attachment of the filter cartridge 500. The filter cartridge 500 may further include a handle 560 to allow for easy removal of the cartridge 500 from the pet watering fountain.

[0080] As shown in FIG. 5, water is pumped in the direction of arrow 505 though an inlet port 540 of the filter cartridge 500. Water then passes through the first 200 and second 300 filter stages before exiting the filter cartridge at an exit port 545 in the direction of arrow 507. The water may optionally flow through the filter cartridge 500 in the opposite direction.

[0081] FIG. 6 is a cut-away view of a portion of a filter cartridge 600 as may be used for housing a multi-stage filter for a pet watering fountain, in yet another embodiment. The filter cartridge 600 includes a generally tubular body 630 that slightly tapers at an upper portion 614. The lower portion 612 of the filter cartridge 600 provides a compartment for the first filtering stage 200, such as copper-zinc alloy particles 210. The upper portion 614 provides a compartment for the second filtering state 300, which may comprise granulated activated carbon particles 310. In this manner, the first 200 and second 300 filtering media are stacked within a single tubular body 630. Again, it is understood that the location of the filtering media 200, 300 may be swapped in alternate embodiments.

[0082] The filter cartridge 600 may additionally include a frame 620. The frame 620 supports the filtering media 200, 300. The filtering media 200, 300 are preferably encapsulated within a porous substrate 215, 315. The porous substrate 215, 315 may be attached directly to the lower and upper ends of the filter cartridge 600 to encapsulate the respective filtering media 200, 300. A similar cartridge may be designed that holds only a single filtering medium. Cartridges may also be designed to hold more than two filtering media.

[0083] In operation, water enters the filter cartridge 600 at the bottom end of lower portion 612 in the direction of arrow 605. The water then flows in the direction of arrow 607 through the filtering media 200, 300 before exiting the filter cartridge 600 at the top end of the upper portion 614. In one arrangement, the water may flow through the filter cartridge 600 in the opposite direction.

[0084] FIG. 7 is a cross-sectional view of a pouch 730 serving as an in-line filter 700. Here, granular activated carbon particles 310 are shown residing within the pouch 730, and a porous screen 715 is shown at two ends of the planar pouch 730 to hold the carbon particles 310 in place.

[0085] FIG. 8A is a perspective view of the external surface of a two-stage filter 800, in one embodiment. Here, the filter 800 defines a tubular body 830 that is dimensioned to reside within or along a tubing (as shown in a FIG. 9 at 925) extending from the pump inlet 955 or the pump outlet 957. In the view of FIG. 8A, copper zinc alloy particles 210 reside within the tubular body 830, and are held in place by a porous screen 815. The copper zinc alloy particles 210 represent the first stage 200 of the filter 800.

[0086] FIG. 8B is another perspective view of the two-stage filter 800 of FIG. 8A, but with the tubular body 830 being flipped. Here, activated carbon particles 310 reside within the tubular body 830 and are also held in place by a porous screen 817. The carbon particles 310 represent the second stage 300 of the filter 800.

[0087] FIG. 8C is a cross-sectional view of an in-line filter 850 that comprises a tubular body 830. Here, the tubular body 830 encases particles 210, 310, serving as the first 200 and the second 300 stages of a filtering system. The copper zinc alloy particles 210 reside at a first end 862 of the tubular pouch 830, while the granular activated carbon particles 310 reside at a second end 864 of the tubular pouch 830. A porous screen 815 is shown at opposing ends of the tubular pouch 830 to hold the filtering particles 210, 310 in place. Optionally, an additional porous screen 816 may be disposed between the first 210 and second 310 particles of the filtering system 850.

[0088] In the arrangements of FIGS. 7, 8A, 8B, and 8C, the filtering particles 210, 310 are held within the tubular body 730, 830 at each end by a porous screen 715, 815, 817. The illustrative screens 215, 315, 715, 815, 816, 817 may comprise pores of any size that closely hold the first 200 and second 300 filtering media in place. The screens 215, 315, 715, 815, 816, 817 themselves may serve a filtering function, having pores with limited openings. For filtering functions, the screens 215, 315, 715, 815, 816, 817 may comprise pores of up to 1,000 microns in size. Embodiments may comprise pores that are up to 100 microns in size. In alternate embodiments, the pores may range from 0.2 microns to 2 microns in size. Some embodiments may comprise pores that are about 0.5 microns in size. Those of ordinary skill in the art will understand that as the diameter of the screen openings is reduced and as the porosity of the filtering particles is lowered, the capacity of the pump 950 needs to be increased.

[0089] FIG. 9 is a perspective view of an illustrative pump 950 as may be used in connection with the a multi-stage filtration system 900. In this arrangement, a filter cartridge 910 is in fluid communication with an outlet 957 of the pump 950. The filter cartridge may be, for example, the filter cartridge 500 of FIG. 5.

[0090] A tubing 925 is shown extending from the pump outlet 957, and a portion of the tubing 925 has been cut away to reveal the filter cartridge 910 that resides therein. The tubing 925 is configured to allow for removal and replacement of the filter cartridge 910 and its filtering media 200, 300 after a period of use. Although shown adjacent the pump outlet 957 in FIG. 9, it is to be under stood that the filter cartridge 910 may reside either downstream or upstream of the pump 950. For example, the filter cartridge 910 may reside adjacent the pump inlet 955.

[0091] In operation of the pump 950 of FIG. 9, water enters the pump 950 at the pump inlet 955 in the direction of arrow 905. The pump 950 then propels water to the pump outlet 957 and through the filter cartridge 910, where water is filtered via filtering media 200, 300. Water then exits the filter cartridge 910 in the direction of arrow 907 and continues through the tubing 925 to be delivered to the water basin (115 of FIG. 1A) for consumption.

[0092] It should be understood that the multi-stage filtration system 900 as depicted in FIG. 9 may be configured or adapted to incorporate any filter cartridge 910, housing, or filtering media 200, 300 that would be apparent to those having skill in the art or described elsewhere in this application. In embodiments, the filter cartridge 910 may be integral with the tubing 925 (as shown). Alternatively, the filter cartridge 910 may exist as an independent housing for filtering media 200, 300 that may be separately removable for simplified cleaning and replacement of the filtering media 200, 300.

[0093] In any arrangement, the filtering system 900 preferably utilizes the pump 950 to circulate water through the system. The pump 950 is a submersible pump operating, for example, at 50-60 Hz and about 5.2 volts of power. The pump 950 may be, for example, the SP-880 aquarium pump manufactured by Resun™ of Shenzhen, China. The pump 950 may have a valve that allows the operator to adjust the water flow. In one aspect, the pump 950 pumps up to about 370 liters of fluid per hour.

[0094] Where a submersible pump 950 is used, the pump 950 will reside within the water basin 115. However, the filtration systems and the pet fountains herein may operate successfully with pumps that reside along the bowl 110 but above the water line of the basin 115. In this instance, the pump 950 will have a tube (not shown) extending from the pump inlet 955 to bring water into the pump 950 and then a separate tube extending from the pump outlet 957 to deliver water back to the basin 115. The filtering system may reside either upstream of or downstream of the pump 950.

[0095] A method for filtration of water for a pet fountain is also disclosed herein. In accordance with the method, a pet owner receives or is provided with a pet fountain. The pet fountain includes a basin 115, and a pump 950 residing within or along the basin 115. The basin 115 works as a wall 112 to serve as a watering bowl 110 and may be of any configuration and volume so long as a domesticated pet such as a dog or cat can access the liquid contents.

[0096] The method also includes inserting a multi-stage filtration device within the basin and in fluid communication with the pump 950. The multi-stage filtration device may be in accordance with any embodiment described herein. The multi-stage filtration device may be pre-inserted when the pet owner receives the pet fountain or may be inserted or replaced by the pet owner after purchase.

[0097] As part of the method, additional filtering or treatment steps may be employed. In one aspect, a third stage may be used that includes an anion resin bed. The anion resin bed contains positively charged resins that can remove negatively charged ions from the inflowing water stream. Negatively charged ions may include arsenates, nitrates, sulfides and sulfates. Alternatively, the resin bed may contain positively charged resins.

[0098] In another step, a UV chamber may be provided in a pet water fountain. The UV chamber comprises an ultraviolet light that kills microbes to further purify the water without lowering the pH of the water. Such treatment can kill bacterium, fungi and viruses. In one embodiment, the UV reactor unit can be selected to meet U.S. Pharmacopeia standards for purification. The inclusion of a UV treatment device can also possibly provide immunity from “boil water” orders that are sometimes issued during or after municipal water system damage or repairs.

[0099] The device and method disclosed herein provide a multi-stage design that allows the pet owner to provide cleaner, better tasting water for a pet. At the same time, the design allows the pet owner to go longer times without having to clean the basin and fountain components. In one aspect, the filtration stages herein produce a slightly alkaline water, which is believed to have positive health benefits by aiding the absorption of oxygen into the water rather than repelling or expelling oxygen from the water.

[0100] Variations of the filtering device and of the methods for filtering water for a pet fountain herein, may fall within the spirit of the claims, below. It will be appreciated that the inventions are susceptible to modification, variation, and change without departing from the spirit thereof.

EXAMPLES

[0101] An example is provided below to facilitate a more complete understanding of the invention. The following example illustrates an exemplary mode of making and practicing the invention. However, the scope of the invention is not limited to specific embodiments disclosed in this Example, which is for purposes of illustration only, since alternative methods can be utilized to obtain similar results.

Example 1

[0102] One of the challenges with pet fountains is keeping the watering bowl and filtering components clean. If fountains are not properly cleaned and maintained, the benefits of animal watering fountains can be reduced or even reversed. This typically requires the frequent disassembling of the fountain, rinsing of the filtering media, and washing of the small pump and basin. Some of this cleaning may involve the removal of scale and mineral deposits.

[0103] Given the cumbersome process of cleaning a pet watering bowl and fountain, an objective the filtering system and pet fountain in accordance with embodiments of the present invention is to provide a pet fountain that requires less frequent cleaning.

[0104] To study the effects of an embodiment of the water filtering system on bowl cleanliness, an experiment was performed wherein a control watering fountain that employs a standard submersible filter was allowed to run undisturbed for a period of 14 days. A second watering fountain that employs a filtering system in accordance with an embodiment of the present invention was also allowed to run undisturbed for the same 14-day period.

[0105] Example 1A shows a photographic view of the bowl utilized in the control watering fountain that employed a standard submersible filter after the 14-day test period. An accumulation of scale and scum is visible within the bowl.

[0106] Example 1B shows a photographic view of the bowl utilized in the second watering fountain that employed a filtering system in accordance with an embodiment of the present invention after the 14-day test period. No accumulation of scale or scum is visible due to the properties of the first 200 and second 300 stages of treatment. The bowl of FIG. 1B is substantially cleaner and shinier than the bowl of FIG. 1A.