CA1065763A

CA1065763A - Water filter device

Info

Publication number: CA1065763A
Application number: CA237,630A
Authority: CA
Inventors: Charles Gelman; Attila Vadnay
Original assignee: Gelman Instrument Co
Current assignee: Gelman Instrument Co
Priority date: 1974-10-21
Filing date: 1975-10-15
Publication date: 1979-11-06
Also published as: DE2546881C2; FR2299065A1; JPS5170959A; FR2299065B1; GB1499347A; BR7506855A; AU8543575A; IT1048064B; DE2546881A1; AU499754B2; JPS5435711B2

Abstract

ABSTRACT

In accordance with the invention there is provided a water filter and water filter device having an upper water filtering layer containing charcoal particles, a lower filtering layer having a submicron pore size and an intermediate filtering layer having a pore size greater than that of the lower layer but less than the particle size of the charcoal in the upper layer.

Description

P-301 106~
The subject matter of the present invention i8 a water filtering device for attachment to a faucet and a replaceable water filtering cartridge for use in such device.
It has long been proposed that water faucets, such S as household water faucets, restaurant, office and other drinking water outlets, be equipped with a water filtering device such that the householder or other user can assure the potability of the water withdrawn from the faucet for drinking or cooking purposes. As far back as 1906 there is-sued to G. Klumpp United States Patent 818,264 disclosing ~-such a device, and in the meantime numerous patents have is-sued disclosing variations for such devices. In this regard, reference is here made to U.S. Patents 989,965, 2,334,802, .,.,, ;,

2,368,035, 3,519,134, 3,780,869, 3,802,563, and 3,822,018.
lS However, the fundamental difficulty has been - and the fun-damental dlfficulty which remained up until the present inven-` tion - is that such a filtering device in order to be prac-tical must on the one hand effectively filter the water to significantly increase its potability while yet, on the other hand, have a sufficiently long efficient filtering life so as not to require ~lmost constant replacement. In this regard, it has long been recognized, as evidenced by the 1906 patent, U.S. 818,264, that it is desirable to incorporate into such a device means for bypassing the filter so that when water is withdrawn other than for drinking or cooking purposes, the filter not be engaged thereby to increase the life of the fil-~ ter for continued use only for withdrawal of water from the `1 faucet for drinking or cooking. However, the devices here-tofore proposed have failed to meet a further requisite, namely, that the device be compact, simple of construction and .,~

hence economical. The problem has been compounded by the fact that as the years have gone by the standards for what would be considered potable water have greatly increased - and the higher the standards the greater the demand on the filtering device as regards filtering efficiency - and - with this, in turn, rendering all the more difficult the problem of attain-ing relatively long efficient filtering life for the device at a suffi-ciently low cost as to render the device economically feasible for the householder or other user. In essence, then, there is need for a water filtering device for attachment to a faucet which at one and the same time provides potable water to today's high standards for potable water, and on : a cost basis which is easily within the budget of the average householder.
According to the invention, a water filter comprises a housing, i a first filtering layer located within the housing and substantially adjacent a water inlet of the housing, the first filtering layer containing particles of activated charcoal, a second filtering layer located within the housing and substantially adjacent a water outlet of the housing, the second filtering layer having a submicron pore size, and a third filtering layer intermediate the first and second filtering layers and having a pore size less than the size of the charcoal particles in said first layer and greater than the pore size of said second filtering layer. Other features, and advantages will appear more clearly from the following description of a preferred embodiment thereof made with reference to the drawings in which:
Figure 1 is a cross-sectional view of a preferred embodiment of the device of the present invention shown attached to the faucet;
Figure 2 is a section taken on the line 2-2 of Figure l;
Figure 3 is a section taken on the line 3-3 of Figure l;
Figure 4 is a section taken on line 4-4 of Figure l;
Figure 5 is a perspective view with parts broken away of the filter cartridge shown in Figure l; and Figure 6 is a cross-sectional view in enlarged scale, .

of the filter cartridge shown in FIGURE 1.
Referring to FIGURE 1, the device comprises a gener-ally tubular passage 2 having, at the upper end thereof as shown, an internally threaded collar 4 for threadedly se-curing the device to the end of a faucet 6. At this point it should be mentioned that most modern faucets are provided with an aerator threadedly engaged to the end of the faucet : and hence it is simply a matter of threadedly disengaging the aerator from the faucet and replacing same by threadedly en-gaging the collar 4 to the end of the faucet in place of the . removed aerator. At the lower end, as shown, of the passage 2 where the water exits from the device there is an externally threaded collar 8 which can threadedly receive the aerator 10 : removed from the faucet, the aerator 10 being shown in broken outline and forming no part of the present invention.
When the device is secured to the end of the faucet, as aforesaid, the generally tubular passage 2 i9 aligned with the end of the faucet so that water exiting from the faucet; is caused to enter into the passage.
The passage 2 has a portion 12 which is of relatively small diameter and a portion 14, at the lower end thereof as shown, of relatively large diameter. The relatively small diameter portion 12 of the passage is surrounded by an annular : water filtering chamber 16 the lower axial end of which, as shown, is adjacent the large diameter portion 14 of the pas-. sage 2. A plurality of radially extending openings 18, whichare in the form of tapered grooves in the inner surface of the lower wall of chamber 16, provide communication between the lower axial end of the chamber 16 and the large diameter por-tion 14 of the passage 2. Likewise, a plurality of radially ~. . . . .. - . . . . .

~06S~63 extending openings 20, which are in the form of tapered grooves in the inner surface of the top wall of chamber 16, provide communication between the passage adjacent the upper end, as shown, of the small diameter portion 12 of the passage and the upper axial end of the water filtering chamber 16.
An internally threaded sleeve 19 is threadedly se-cured to the external surface of the large diameter portion 14 of the passage and hence the sleeve 19, by rotation thereof, can be moved up or down axially of the large diameter portion of the passage. Secured within the sleeve 19 by a wall 22 ~-having a plurality of openings 23 therethrough (for exit of the water) is an upwardly extending projection 24 within and : concentric with the sleeve, the upper end of the projection . 24 having secured thereto by a screw 26 a conically tapered resilient washer 28, made of rubber or the like, for mated sealing engagement with a conical taper 30 provided at the lower end of the small diameter portion 12 of the passage 2.
Hence, it will be qeen that when the sleeve 19 is turned in a direction to cause it to move axially upwardly with respect to large diameter portion 14 of the passage, the washer 28 ` engages and blocks the lower end of the small diameter portion 12 of the passage and thereby blocks any flow of water from ` the small diameter portion 12 of the passage directly to the large diameter portion 14 of the passage. Such constitutes a valve, and with the valve closed, as aforesaid, to block the flow of water directly from passage portion 12 to passage ` portion 14, water from the faucet is caused to flow from the small diameter portion 12 of the passage through the openings 20 into and then through the filter chamber 16 and then from the lower axial end of the filter chamber through the openings . ,." - , .......................... ... ..
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P-301 106~
18 into the large diameter portion 14 of the passage, and - from there to exit from the bottom of the passage 2. Hence, with the sleeve being turned in one rotary direction such that the valve constituted by washer 28 is open, the water from the faucet is allowed to flow directly from the small diameter portion of the passage to the large diameter portion of the passage and exit therefrom thereby bypassing the filter chamber 16, whereas with the sleeve 19 rotated in the other direction the valve blocks the direct flow of water through the passage 2 and causes the water to flow through the filter : chamber 16. This structure provides simple and efficient means for, on the one hand, causing bypass of the filter : where filtered water is not desired, and, on the other hand, for causing the water to pass through the filtering chamber where filtered potable water is desired.
The axial ends of the filter chamber 16, namely, the upper axial end 32 and the lower axial end 34, are re-movably secured to each other, and therefor separable from each other, by reason of the threaded connection between these axial ends as shown at 36. This adapts the chamber . 16, by separation of the axial ends thereof, to removably receive a replaceable water filtering cartridge 38, such i` water filtering cartridge being shown in FIGURES 4 and 5 as well as in FIGURE 1. It will be understood that means other than a threaded connection can be used to removably secure . together the axial ends of the chamber. For example, a bay-. onet type connection can be used instead of a threaded con-nection.
Referring now to FIGURES 4 and 5, in particular, the water filtering cartridge comprises an annular housing 40 , .: . ".
. : -. .

open at the upper axial end thereof, as shown, for reception of water into the housing and having at the other, or lower axial end thereof, as shown, an annular wall with openings therethrough to allow exit of water from the housing. In the preferred embodiment, as shown, the housing is an organic resin molding the lower wall 42 of which constitutes an integral screen or grid and the upper, or open, end thereof, as shown, is provided with a !', ~'~
radially outwardly extending flange 44 at the outer circumferential edge thereof and a radially inwardly extending flange 46 at the inner bore there-of. Referring for the moment to Figure 1, it will be seen that a rubber or the like resilient gasket 48 is provided in the inner surface of the upper axial end of the chamber 16 to cooperate with the upper surface of radially outwardly extending flange 44 to provide a seal, and the upper end of the small diameter portion of passage 2 is likewise provided with a rubber or like resilient gasket 49 to cooperate with the underside of -inwardly extending flange 46 to provide a seal. The housing 40 is of a size to fit snugly in the chamber 16 as can be seen in Figure 1.
Referring again to Figures 4 and 5, within the annular filter cartridge housing 40 and adjacent the upper or open axial end of the housing is a filtering layer 50 containing particles of activated charcoal. In the embodiment shown the layer 50, in the aggregate, consists of a plurality of ; layers (specifically three layers in the particular embodiment shown), in combination, each of which layers consist of a fibrous matting impregnated i with charcoal particles, the charcoal particles preferably being from about 5 microns to 50 microns in size and the pore size of the layer 50 pre-. ~ .

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P-301 ~S7~
ferably being between 20 and 50 microns. (In this instance and in all other instances herein where pore size is speci-fied it is to be understood that that to which reference is made, in specifying pore size, is the size, i.e. the minimum size, of the particles blocked by the filtering layer in-volved. Hence, if the pore size of a given layer is 20 microns, particles of a size greater than 20 microns are blocked from passage therethrough.) The fibrous matting used for the ad-herence thereto of the charcoal particles can be of any sui-table fibrous material such, for example, as cotton or poly-ester or other synthetic fibers. The fibrous material can be of woven instead of matted construction if desired. The rea-son a plurality of layers is used to constitute the totality of the layer 50 is that to accomplish the most desired thick-ness of the layer 50, which is from about .1 to .2 inches while at the same time accomplishing optimum impregnation and adher-ence of the activàted charcoal particles to the fibrous base for such layer, it is preferable to constitute the layer 50 - of two or more separately prepared relatively thin layers of the fibrous material impregnated with the activated charcoal particles.
Adjacent, but in the preferred embodiment not abut-ting, the bottom perforated wall of the housing is a filter layer 52 consisting of a porous material preferably having a thickness of less than 250 microns, and typically from about 100 to 250 microns, and a pore size of less than 1 micron, and preferably a pore size of from about .2 to .5 micr~ns.
The layer 52 is preferably a unitary film of an organic poly-meric material, such as a copolymer Of acrylonitrile and polyvinyl chloride, having porosity as aforesaid. The film ~065763 can have imbedded therein fibers, such as nylon fiber web, for reinforcement.
; Excellent for the practice of the invention is the product sold by the assignee of the present invention, the Gelman Instrument Company of Ann Arbor, Michigan, under the trademark "ACROPOR". Whereas the purpose of the afore-mentioned activated charcoal-bearing layer 50 is to remove chlorine and other dissolved materials in the water, the purpose of the filtering layer 52 is to filter from the water submicron particles, including bacteria, having a submicron particle size, and even, in the preferred embodiment, a particle size of .5 microns or less. The combination of layers 50 and 52 provide a filtered water having purification close to that of spring water. -Between layer 50 and layer 52 is an intermediate filtering layer 54. Intermediate filtering layer 54 can be of a fibrous material, matted ` or woven, such as polyester or other organic polymeric material (an example being Dacron*); but the layer 54 should preferably have a pore size of from about 1 to 10 microns and less than the particle size of the activated charcoal particles in layer 50 but greater than the pore size of layer 52.
The thickness of layer 54, if of a fibrous material, is preferably from about 200 to 800 microns. The function of the intermediate filtering layer 54 is to prevent relatively large sized particles from reaching filter layer 52. That is, whether it be charcoal particles washed from layer 50 or asbestos or other particles within the water itself, what we have found is that if provision is not made for preventing relatively large sized particles from reaching filter layer 52, filter layer 52 rapidly clogs, and therefore the filter cartridge has relatively short life, thereby requirin~g frequent ~: replacement. By the provision of the inter-`;
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~ * A trademark of E.I. duPont de Nemours ~ Company of Wilmington, Delaware.
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P-301 1 ~
mediate filtering layer 54, the life of the filter cartridge, in providing filtered water close to the purification of spring water, is greatly increased. The intermediate layer 54 need not be of fibrous material but instead can be a uni-tary film the same or similar in composition and thickness to submicron pore size layer 52 but of a pore size as speci-fied above for layer 54, i.e. preferably from about l to lO
microns and less than the size of the charcoal particles in layer 50 but larger than the pore size of layer 52.
In the embodiment shown there is provided, between ,J
the lower perforated annular wall of the housing 40 and the filtering layer 52 a layer 56 of porous material, preferably of synthetic fibrous material such as matting or woven cloth of fibrous natural or polyester or other synthetic organic fibers, having a pore size of greater than 10 microns, and preferably greater than 20 microns. The chief purpose of the layer 56 is simply to assure that the maximum filtering area of filter layer 52 is utilized in the filtration of the water.
That is, the function of layer 56 is simply to physically separate submicron filtering layer 52 from the grid or screen forming the bottom wall of the filter cartridge so that less of the total area of filter layer 52 is blocked by reason of the area it contacts. The need for layer 56 can be reduced ` or eliminated by forming at least the upper, or inner, surface ` 25 of the grid which constitutes the wall 42 of the filter car-tridge housing to a triangular, or generally triangular cross-i~ section such that the apices 57 of the triangular cross-section constitute the inner surface of the wall 42 thereby providing less area of contact between the wall and the fil-` 30 tering material while yet providing the necessary support ., .
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~065763 for the filter material.
Further, in order to increase the area and volume of flow path between the bottom wall of the filter cartridge housing and the bottom wall of the filtering chamber receiv-ing the cartridge, it is desirable to provide the lower sur-; face of the bottom wall of the cartridge housing with small spaced downwardly extending projections, as shown at 66 in FIGURE 6, thereby to space the grid which forms the cartridge housing bottom wall from the inner surface of the bottom wall of the chamber. The projections can take other forms such, for example, as short ribs.
As can best be seen in FIGURE 5 the bottom wall of housing 40 is, in the preferred embodiment, provided with in-`1 ner and outer circumferential flanges, 58 and 60 respectively.Bottom layer 56 fits between these flanges and layer 52 along with layer 50 are of slightly larger external diameter and smaller internal diameter so as to extend from the inner to '~ the outer wall of housing 40 above the flanges. The thick-ness of layer 56 is preferably from 100 to 300 microns.
In the preferred embodiment shown the outer edge of filter layer 52 is sealed to the upper surface of flange 60 and the inner edge of layer 52 is sealed to the upper sur-face of flange 58 whereby there is a water-tight seal between the layer 52 and the cartridge housing. Such inner and outer seals can be accomplished by heat-sealing or by a suitable cement. Where layer 54 is a film it is also desirable to seal the inner and outer edges of this layer to the housing.
Lastly, in the most preferred embodiment the open end o the filter cartridge receives, above the activated charcoal bearing filter layer 50, a porous layer 62, pre- ;
ferably the same or similar in pore size, thickness and . . : . . . , :

construction, to layer 56, such layer being principally for the purpose of protecting the activated charcoal bearing layer 50 during handling of the cartridge prior to its insertion into the filtering device. Additionally, of course, S layer 62 functions to, in the first instance filter large particles from the water before they ever reach the charcoal-bearing layer 50 - and hence enhances the life of the filter.
It will be understood that whereas the invention has been described in its particulars specifically with respect to preferred embodiments thereof various changes and modifications may be made fully within the intended ; scope of the claims which follow.
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Claims

THE EMBODIMENTS OF THE INVENTION IN WHICH AN EXCLUSIVE
PROPERTY OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:

1. A water filter comprising a housing, a first filtering layer located within the housing and substantially adjacent a water inlet of the housing, the first filtering layer containing particles of activated char-coal, a second filtering layer located within the housing and substantially adjacent a water outlet of the housing, the second filtering layer having a submicron pore size, and a third filtering layer intermediate the first and second filtering layers and having a pore size less than the size of the charcoal particles in said first layer and greater than the pore size of said second filtering layer.

2. A water filter as claimed in claim 1 wherein the pore size of said first filtering layer is from 20 to 50 microns and wherein the particle size of said charcoal particles is from 5 to 50 microns.

3. A water filter as claimed in claim 1 wherein said first filtering layer consists of a plurality of strata each of which comprises a fibrous material impregnated with said activated charcoal particles.

4. A water filter as claimed in any one of claims 1 to 3 wherein the pore size of said second filtering layer is from 0.2 to 0.5 microns and wherein the pore size of said intermediate filtering layer is from 1 to 10 microns.

5. A water filter as claimed in any one of claims 1 to 3 wherein said second filtering layer is a unitary film.

6. A water filter as claimed in any one of claims 1 to 3 wherein the thickness of said first filtering layer is from 0.1 to 0.2 inches, and wherein the thickness of said second filtering layer is from 100 to 250 microns.

7. A water filter as claimed in any one of claims 1 to 3 wherein the intermediate filtering layer is of a fibrous material.

8. A water filter as claimed in any one of claims 1 to 3 wherein said intermediate filtering layer is a unitary film.

9. A water filter as claimed in any one of claims 1 to 3 wherein a porous layer having a pore size greater than that of the intermediate layer is provided adjacent the first filtering layer and on the side thereof remote from the intermediate layer.

10. A water filter as claimed in claim 1 and which is adapted to be received within an annular water filtering chamber of a water filtering device, wherein the housing of the water filter is of annular shape and has radially inner and outer walls, the inlet of the housing being at one axial end thereof, said one end being open thereby constituting the inlet for the water to be filtered, and the outlet of the housing being at the other axial end thereof, the said other end comprising an annular wall with openings therein which constitute the outlet for the water from the filter.

11. A water filter as claimed in claim 10 wherein said second filter-ing layer is secured to the inner and outer walls of said housing in water-tight sealed relationship therewith.

12. A water filter as claimed in claim 10 wherein there is a porous layer between said second layer and said annular wall of said housing, said porous layer having a pore size at least as large as the pore size of said intermediate layer.

13. A water filter as claimed in any one of claims 10 to 12 wherein said annular wall of said housing comprises a grid, the portions of which have a substantially triangular cross-section with the apices of the sub-stantially triangular cross-section forming the inner surface of the wall.

14. A water filter as claimed in any one of claims 10 to 12 wherein, at the open axial end of said housing the outer wall is provided with a radially outwardly extending annular flange, and the inner wall with a radially inwardly extending annular flange, said flanges being adapted to engage respective portions of the water filtering device.

15. A water filter as claimed in any one of claims 10 to 12 wherein the exterior surface of the annular wall of said housing has a plurality of projections extending therefrom to space said wall from the wall of the chamber to which said annular wall of said housing is adjacent when the filter is inserted into the filtering chamber.

16. A water filtering device comprising wall means defining a generally tubular passage having an upper portion with an inlet for water and having a lower portion with a water outlet at the lower end thereof, an annular water filtering chamber surrounding at least part of said passage and within which is located a water filter as claimed in claim 10, at least one opening between the upper axial end of said chamber and the upper portion of said passage, and a valve in said passage movable axially thereof for blocking the flow of water directly from the upper portion of said passage to the lower portion of said passage whereby when said valve is closed water enter-ing the passage by way of the inlet is caused to flow from said passage into and through said filtering chamber.

17. A device as claimed in claim 16 wherein said valve comprises a sleeve rotatably secured to the wall means at the lower portion of said passage, the sleeve having secured thereon, within the passage, a washer which engages the wall means and blocks the passage between said opening or openings and said lower portion thereof when said sleeve is rotated in one direction relative to the wall means at said lower portion of said passage.

18. A device as claimed in claim 16 or claim 17 wherein the upper and lower axial ends of said chamber are releasably secured together to permit removal and/or replacement of the said water filter.