Siphon adapted for cleaning vessels

Abstract

A siphon is adapted for thoroughly cleaning fluid vessels. The siphon is capable of elevating discharge waste fluid through a transfer of kinetic energy provided by a pressurized fluid source, thereby obviating any need for undesirable electrical, chemical, or other mechanical power sources. An inlet couples pressurized fluid to a divider that splits the pressurized fluid between a jet port outlet and a tank flush source conduit. A siphon return conduit is operative to carry waste fluid from the fluid vessel, with the cleaning attachment protruding from the siphon return conduit. By slightly protruding, the cleaning attachment operatively blocks the siphon return conduit from being held by siphon vacuum against a surface of the fluid vessel while developing a beneficial eddy current flow path. A drain conduit is provided, as is a mixing chamber at a junction between the jet port outlet and an outlet from the siphon return conduit.

Claims

1. A siphon adapted for thoroughly cleaning fluid vessels and containers which is capable of elevating discharge waste fluid to water heads greater than present in said fluid vessels and containers, which derives the necessary motive power to drive the cleaning apparatus through fluid kinetic energy provided by a pressurized fluid source and thereby obviates the need for undesirable electrical, chemical, or other mechanical power sources, and which operation is both intuitive and without unexpected action required such that persons of diverse experience, knowledge and skill may readily use the apparatus, comprising: an inlet receiving pressurized fluid from said pressurized fluid source; a divider which simultaneously directs said pressurized fluid to both a jet port outlet and a tank flush source conduit; a siphon return conduit for carrying waste fluid from said fluid vessels and containers; a drain conduit; and a mixing chamber at a junction between said jet port outlet and an outlet from said siphon return conduit, said jet port outlet operative when no waste fluid is passing from said siphon return conduit into said mixing chamber to induce a siphon-generating flow into said drain conduit and said jet port outlet operative when waste fluid is passing from said siphon return conduit into said mixing chamber to introduce a fluid flow of higher velocity than within said waste fluid prior to mixing therewith and thereby transfer kinetic energy into said waste fluid to accelerate said waste fluid into said drain conduit, said jet port outlet aligned parallel with said waste fluid flow in said drain conduit.

2. The siphon adapted for thoroughly cleaning fluid vessels and containers of claim 1, further comprising a cleaning attachment removably terminating said tank flush source conduit.

3. The siphon adapted for thoroughly cleaning fluid vessels and containers of claim 2, wherein said additional cleaning attachment further comprises a spray nozzle.

4. The siphon adapted for thoroughly cleaning fluid vessels and containers of claim 1, wherein said divider is located between said fluid inlet and said tank flush source conduit and splits said pressurized fluid into first and second simultaneous and generally perpendicular fluid streams, said first fluid stream flowing to said jet port outlet and said second fluid stream flowing into said tank flush source conduit, said siphon return conduit passing generally parallel with said tank flush source conduit between said aqueous body and said divider and having a flow turning generally perpendicular to said tank flush source conduit adjacent said divider.

5. The siphon adapted for thoroughly cleaning fluid vessels and containers of claim 1, wherein said siphon return conduit shares an external wall with said the tank flush source conduit.

6. The siphon adapted for thoroughly cleaning fluid vessels and containers of claim 1, wherein said siphon return conduit is concentrically arranged about said tank flush source conduit.

7. The siphon adapted for thoroughly cleaning fluid vessels and containers of claim 1, wherein said fluid vessels and containers comprise a recreational vehicle water heater, and said kinetic energy transfer is operative to elevate a head of said waste fluid above a head of fluid within said recreational vehicle water heater, thereby facilitating cleaning and removal of said fluid within said recreational vehicle water heater.

8. The siphon adapted for thoroughly cleaning fluid vessels and containers of claim 1, further comprising a flow control valve between said jet port outlet and said divider which restricts flow from said inlet to said jet port outlet, thereby enabling an operator to control both a priming of said siphon and to control an extent of said kinetic energy transfer.

9. The siphon adapted for thoroughly cleaning fluid vessels and containers of claim 1, further comprising a flow control valve between said tank flush source conduit and said divider which restricts flow from said inlet to said tank flush source conduit, thereby enabling an operator to control a flow of fluid into said fluid vessels and containers.

10. The siphon adapted for thoroughly cleaning fluid vessels and containers of claim 8, further comprising a flow control valve between said tank flush source conduit and said divider which restricts flow from said inlet to said tank flush source conduit, thereby enabling an operator to control a flow of fluid into said fluid vessels and containers.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The foregoing and other objects, advantages, and novel features of the present invention can be understood and appreciated by reference to the following detailed description of the invention, taken in conjunction with the accompanying drawings, in which:

(2) FIG. 1 illustrates a preferred embodiment siphon adapted for cleaning vessels in accord with the teachings of the present invention, in further combination with a water heater and a discharge receptacle, all from a projected generally isometric view. To facilitate a better understanding of the operation, the water heater vessel is shown by cross-section, with other features of the water heater removed for clarity.

(3) FIG. 2 illustrates the preferred embodiment siphon of FIG. 1 by cross-sectional view taken along a plane approximately dividing the siphon into two symmetrical halves.

(4) FIG. 3 illustrates a first alternative embodiment siphon adapted for cleaning vessels in accord with the teachings of the present invention by cross-sectional view taken along a plane approximately dividing the siphon into two symmetrical halves.

(5) FIG. 4 illustrates a second alternative embodiment source water flow control by enlarged partial cross-sectional view taken along a plane approximately dividing the water flow control into two symmetrical halves.

(6) FIG. 5 illustrates a third alternative embodiment siphon adapted for cleaning vessels in accord with the teachings of the present invention by cross-sectional view taken along a plane approximately dividing the siphon into two symmetrical halves.

(7) FIG. 6 illustrates the third alternative embodiment siphon by a bottom view with the spray outlet and drain lines disconnected.

(8) FIGS. 7 and 8 illustrate a preferred divider used in the third alternative embodiment siphon of FIGS. 5 and 6 by bottom and side elevational views, respectively.

(9) FIGS. 9 and 10 illustrate an alternative embodiment divider by bottom and side elevational views, respectively.

(10) FIG. 11 schematically illustrates a prior art cleaning system with the spray conduit retracted from the drain conduit.

(11) FIG. 12 schematically illustrates an alternative embodiment siphon adapted for cleaning vessels with the spray conduit terminating adjacent with the drain conduit termination.

(12) FIG. 13 schematically illustrates the preferred embodiment siphon adapted for cleaning vessels of FIGS. 1 and 2 with spray conduit protruding from drain conduit.

DESCRIPTION OF THE PREFERRED EMBODIMENT

(13) Various embodiments of apparatus designed in accord with the present invention have been illustrated in the various figures. The embodiments are distinguished by the hundreds digit, and various components within each embodiment designated by the ones and tens digits. However, many of the components are alike or similar between embodiments, so numbering of the ones and tens digits have been maintained wherever possible, such that identical, like or similar functions may more readily be identified between the embodiments. If not otherwise expressed, those skilled in the art will readily recognize the similarities and understand that in many cases like numbered ones and tens digit components may be substituted from one embodiment to another in accord with the present teachings, except where such substitution would otherwise destroy operation of the embodiment. Consequently, those skilled in the art will readily determine the function and operation of many of the components illustrated herein without unnecessary additional description.

(14) A preferred embodiment siphon 100, adapted for cleaning vessels and designed in accord with the teachings of the present invention, is illustrated in FIG. 1. Siphon 100 is illustrated in a preferred further combination operatively cleaning a prior art water heater vessel 10 resting upon floor 30, with siphon 100 drawing from vessel 10 and discharging waste water into a prior art discharge receptacle 20 also resting upon floor 30. Discharge receptacle 20 may, for exemplary purposes only and certainly not limited thereto, take the form of an ordinary pail having a top opening 22. Many other suitable fluid sinks are contemplated herein and known in the art, and again without limiting solely thereto may alternatively or additionally comprise such devices as sinks, plumbing drains, the earthen ground or other ground surface, and other suitable liquid receivers, sinks or receptacles. In some instances, it may further be desirable to filter or otherwise purify the waste water and recycle the water back into inlet 110.

(15) The illustration in FIG. 1 shows water heater vessel 10 containing water therein at an upper level 12 which is just below the level of drain hole 16. The level illustrated may be obtained by ordinary use of drain hole 16, such that a balance of water filling water heater vessel 10 would have been drained by gravity out of vessel 10, either directly spilling therefrom or through some secondary discharge hose or conduit, the likes of which are known and not illustrated herein. In the case of prior art recreational vehicle water heaters, this drain hole 16 may only be approximately one-half inch in diameter, which is too small to permit or facilitate further prior art cleaning or inspection. Rust, scale, and other impurities and matter 14 will ordinarily be suspended within the water, and will also commonly include a substantial amount of sediment.

(16) Siphon hose 130 has been inserted through opening 16. Passing inside of siphon hose 130 is spray hose 140. Most preferably, spray hose 140 extends into vessel 10 just farther than siphon hose 130, such that spray hose 140 protrudes slightly therefrom. By so arranging hoses 130, 140, the inlet to siphon hose 130 cannot be blocked by accidental contact with a surface, which could in the prior art be followed by being held in this blocked position by the vacuum force created by the siphoning liquid. Instead, in the preferred embodiment siphon 100, when hoses 130, 140 approach a wall or floor of vessel 10, the discharge of water from hose 140 will repel hoses 130, 140 away. Consequently, the combination of siphon hose 130 and spray hose 140 with spray hose 140 protruding will facilitate proper movement and use of preferred embodiment siphon 100.

(17) Clean water or other suitable fluid is introduced into siphon 100 at inlet 110, where it is metered and divided between outlet 120 and spray hose 140, as will be explained in greater detail with respect to FIG. 2. Desirably, fluid sprayed from spray hose 140 will interact with matter 14 to entrain and withdraw this matter from vessel 10. Contaminating matter 14 and liquid are drawn into siphon hose 130, pass through junction 150 to outlet 120, and then pass into receptacle top opening 22 to be collected within discharge receptacle 20.

(18) FIG. 2 illustrates preferred embodiment siphon 100 of FIG. 1 in much greater detail. Most preferably fluid inlet 110 comprises a means for coupling to a pressurized water inlet. The coupling means in the simplest embodiment is inlet wall 112, which forms a tight friction fit with a suitable tube from a water source. Any of a myriad of other couplings are contemplated herein, which might commonly include such devices as a garden hose terminating in either hose threads or quick release couplings, or any other fluid couplings known in the couplings art. Fluid passing into inlet 110 might commonly include ordinary tap or household water, at typical pressure levels of approximately thirty to sixty pounds per square inch (PSI). While water is described as the preferred fluid of choice, those skilled in the art will recognize that the fluid might alternatively include or be solely composed of other compounds, ranging from RV antifreeze to storage or cleaning solutions, such as but not limited to vinegar and water solutions, phosphoric acid solutions, chlorinated solutions, soap solutions, alcohol solutions, or others of the many known solutions which are suitable for use in cleaning or otherwise treating potable water supplies.

(19) From adjacent to inlet wall 112, the fluid will divide through two outlet ports. Spray outlet port 114 is of appropriate diameter to couple with inlet 142 in an interior conduit 146 of spray hose 140. Jet port 116 will typically be of smaller diameter, and is used in two ways. The water passing through jet port 116 will serve as an initial primer to initiate a vacuum within outlet 120. In other words, as water or fluid passes through jet port 116 and into the entrance 127 into interior passage 123 of outlet 120, air will naturally be carried therewith. This flow of matter and mass out of passage 123, which is greater than the fluid input through jet port 116, will serve to build a vacuum which will extend into chamber 158. The outlet 134 of siphon hose 130 is directly coupled into chamber 158. Consequently, vacuum will also begin to build within the interior passage 136 of siphon hose 130. Eventually, sufficient vacuum forces will be generated therein to draw fluid into siphon hose 130 through siphon inlet 132, and this fluid will in many cases fill the entire space of interior passage 136.

(20) As this occurs, and chamber 158 similarly fills, the movement of fluid through jet port 116 will begin to interact directly with the fluid passing from interior passage 136 into chamber 158. As a result, this same fluid will be accelerated by kinetic energy transferred from the fluid jet into siphon flow. Consequently, fluid passing through jet port 116 will not only serve to initiate a priming of siphon 100, but this same fluid stream will act as a jet pump through the transfer of kinetic energy. Consequently, once operational, siphon 100 is not only able to act through siphon to transfer fluid from a container of higher surface or head to a container of lower surface or head, as is known in the siphon art, but the present invention is able to transfer from a container of lower surface or head to one of higher surface or head. This is of particular benefit in the case of a water heater that rests immediately adjacent to the ground or other surface, and which has a drain hole only a few inches higher. Rather than only being able to fill a discharge receptacle with a small quantity of the fluid within the water heater, preferred embodiment siphon 100 may fully discharge fluid until siphon hose inlet 132 no longer remains fully submerged, and so instead begins to draw air into siphon hose interior passage 136. If siphon hose inlet 132 is subsequently re-submerged, then the priming and jet pumping process will restart.

(21) Proper selection of the diameter of jet port 116 is important to the successful operation of preferred embodiment siphon 100. The size is a function of the inlet pressure, the available cross-section of siphon hose interior passage 136 and outlet passage 123, and the temperature and associated viscosity of the fluids being used. In the case of water, temperatures above freezing will result in no consequential changes in viscosity, and the preferred apparatus is quite tolerant of pressure variations. Consequently, those skilled in the art, without undue experimentation, will be able to select an appropriate jet port size for use within a siphon designed in accord with the present teachings. Another important factor is the material from which jet port 116 is fabricated. Since size is important to proper operation, it is desirable for a higher quality siphon 100 to include a jet port 116 which is fabricated from a material or alloy which is both reasonably hard or durable and which also exhibits excellent corrosion resistance. The extent of durability and corrosion resistance chosen will depend upon how long a designer wishes the present invention to last, cost considerations, and the expected operating pressures.

(22) Proper orientation of jet port 116 with respect to outlet 120 and chamber 158 is also very important. While not specifically illustrated, a number of means are contemplated herein and known in the industry for obtaining this alignment. The particular means selected may further depend in part upon the methods of fabrication and coupling of each of the components. For exemplary purposes, and not solely limited thereto, inlet 110 may be threaded into junction 150, in which case an alignment mark or the like will preferably be provide on the exposed side of inlet 110 distal to port 114. As another exemplary means, a keyway and associated key may be provided to force alignment between inlet 110 and junction 150, such as the formation of a small slot partially penetrating inlet 110 and a small protrusion extending from junction 150 into this slot. With such arrangement, inlet 110 may only be placed in alignment where the slot and protrusion align, thereby ensuring proper alignment. In this type of arrangement, inlet 110 might for exemplary purposes be press-fit into junction 150 adjacent to junction inlet 152, or may be soldered, welded, adhesively bonded or otherwise rigidly affixed. Just as inlet 110 may be coupled through a myriad of appropriate methods, so exist a myriad of possibilities for the other couplings and junctions illustrated in the present invention. Furthermore, it is contemplated herein that ones of the various components illustrated herein may either be consolidated into a single unitary device, or they may be fabricated from a plurality of discrete components. In either case, the component assembly and methods of affixing are not critical, so long as the finished siphon remains functional. As aforementioned, there are a myriad of other suitable keying or alignment techniques that are known and applicable to the present invention.

(23) An additional coupler 125 is illustrated in the preferred embodiment siphon 100. This is so because it is anticipated that the spatial orientation of siphon 100 may be changed during use to help redirect spray outlet 144 about the interior surfaces of vessels to be cleaned. Nevertheless, outlet 120 will be expected to remain within discharge receptacle 20 or other discharge receptacle. Consequently, to best accommodate this movement, outlet 120 will most preferably include a conduit 121 which is flexible and pliant, such as one fabricated from pliable polymers, elastomers, rubbers, or rubber-like compounds. In such case, coupling may be readily achieved through many techniques, but the flared barbed end 126 of coupler 125 will in most cases serve to hold the end 124 of conduit 121 distal to outlet 120 termination 122 in place. Likewise, coupler 125 may be securely coupled to junction 150 adjacent junction outlet 156 using a threaded coupling 128 or by any other suitable means.

(24) A first alternative embodiment siphon 200 adapted for cleaning vessels in accord with the teachings of the present invention is illustrated in FIG. 3. For sake of brevity, components which are like in geometry and function to those illustrated in the preferred embodiment siphon 100 will not be numbered or separately discussed. Nevertheless, for this and the subsequent alternatives, it will be understood that these components are in fact present and function as already described herein above.

(25) In siphon 200, two noteworthy changes have been made. The first change is to inlet 210, which differs from inlet 110 by the placement and orientation of jet port 216 relative to outlet entrance 127. More particularly, jet port 216 will direct high pressure fluid directly into and parallel with outlet passage 123, thereby fully preserving the kinetic energy of the fluid flowing through jet port 216. Whether such kinetic energy remains primarily with that fluid and adjacent entrained air, or whether the kinetic energy is transferred into a siphon flow originating at siphon inlet 132 depends upon whether siphon 200 has been primed, and fluid is being conveyed from siphon inlet through to adjacent jet port 216. Nevertheless, less kinetic energy is lost in siphon 200 than in siphon 100.

(26) The second noteworthy change illustrated in FIG. 3 is in the arrangement and geometry of the spray outlet. In contrast to simple tubular spray outlet 144, spray tip 246 is held within a termination 244 of spray hose 240 by barbs or similar suitable means. Termination 244 is within the confines of siphon hose 130, but spray tip 246 most preferably extends beyond inlet 132 of siphon hose 130, for the same reasons as did spray outlet 144. Rather than a single tubular stream or jet, spray tip 246 is configured for at least three jets, emanating from jet outlets 247-249. While three smaller jet outlets are shown, it will be recognized that any suitable geometry may be provided within spray tip 246, and that a plurality of tips may be designed for different functions or capabilities. Further, one or more of a variety of cleaning attachments such as brushes, squeegees or the like may be coupled within termination 244 or formed in association with spray tip 246, the specific geometries which are taught for example by the Scarpine patent and others incorporated herein above by reference.

(27) FIG. 4 illustrates a second alternative embodiment source water flow control by enlarged partial cross-sectional view, such that siphon hose 330 and spray hose 340 are only visible in small part adjacent to inlet 310, and the entrance 327 to outlet 120 is visible, while outlet 120 is not. In this second alternative embodiment, fluid inlet 310 is divided between ports 314 and 316, but neither of these ports is limited to a small enough diameter to generate a jet therefrom. Instead, port 314 passes valve body 311 and valve seat 313 into spray hose inlet 342 of spray hose 340. Fluid entering port 316 will similarly pass valve body 315 and valve seat 317, before being expelled from jet port 318. Most preferably, jet port 318 is sufficiently small relative to the opening defined by valve seat 317 that, when desired, the pressure developed on the side of jet port 318 adjacent to seat 317 will build to nearly the pressure at fluid inlet 310. In this way, valve seat 317 will not act as a detrimental flow restriction. Otherwise, valve seat 317 will reduce the kinetic energy being transferred by fluid passing through jet port 318. From jet port 318, fluid will pass into inlet 327, from where it will most preferably couple co-axially with outlet 120 for discharge therefrom. Valve bodies 311, 315 may each separately be adjusted, allowing a person to control both the amount and pressure of spray fluid emanating from a spray house outlet such as spray outlet 144 and also to control the priming and extent of jet pumping from jet port 318. As but one example, when valve body 311 is closed, fluid will cease to be delivered into the fluid vessel. Nevertheless, the siphoning action persists, and any fluid within the vessel such as 12 illustrated in FIG. 1 may be drained. Particularly in those vessels where the bottom is lightly bowl-shaped or concave, remaining fluid will collect in the center of the bottom. In such case, it may be possible to remove almost all of the fluid from within the vessel. The vessel may be left in this state, or, if the operator so elects, valve 311 may once more be opened to run through another cleaning cycle.

(28) An alternative embodiment arrangement of spray and siphon hoses is also illustrated in FIG. 4. More particularly, while the previous embodiment hoses 130, 140 were illustrated as being generally co-axial, with spray hose 140 of smaller cross-sectional area than siphon hose 130, the co-axial arrangement is not necessary to the operation or functioning of the present invention. Nevertheless, it is most preferable to incorporate a smaller spray hose 140 within the cross-section of a larger siphon hose 130, or to at least share a common exterior wall with at least a portion of the exterior of spray hose 140 serving as a portion of the interior surface defining siphon hose interior passage 136. In this way, the limited cross-sectional area which is available in RV water heaters and in other applications will be most efficiently utilized by apparatus designed in accord with the teachings of the present invention. In the case of this figure, it is also conceived herein that spray outlets may be provided at any point and in any suitable pattern and size along the length of spray hose 340 as may be desired.

(29) FIG. 5 illustrates a third alternative embodiment siphon 400 adapted for cleaning vessels in accord with the teachings of the present invention. In siphon 400, several changes have been made. One change is to inlet 410, which differs from inlet 210 by the incorporation of two ball valves 411 and 415 therein. While ball valves are illustrated herein as exemplary valves, those skilled in the art of fluid valves will recognize that a myriad of other valve types may be substituted herein, and such substitution is contemplated and incorporated herein. Valve 411 is used to solely control the amount and pressure of fluid emanating from spray outlet 448, independent of flow through outlet 420 and siphon hose 430. Valve 415 is used to control all water input, both to spray outlet 448 and to jet port 416. While manufacture is somewhat more difficult than previous embodiments illustrated herein, the addition of these valves with the placement shown provides an operator with more convenient control over the operation of siphon 400. As may be apparent, in the siphon 400 embodiment, inlet wall 412 in combination with valve 411, spray outlet port 414, and jet port 416 together form the divider that splits the incoming pressurized cleaning fluid into the two streams. Valve 411 when open ensures that the two streams are simultaneously flowing, and, if closed, blocks the spray outlet stream. In contrast, in the siphon 100 embodiment, inlet wall 112 in combination with spray outlet port 114, and jet port 116 together form the divider that splits the incoming cleaning fluid into the two streams, and the two streams are always simultaneously flowing.

(30) Another noteworthy change illustrated in FIG. 5 is in the arrangement and geometry of the spray outlet. While a simple tubular spray outlet is shown that ends adjacent to siphon inlet 432, a protruding blocking member 460 of any suitable geometry serves to block siphon hose 430 from direct contact with aqueous vessel wall 18. For exemplary purposes only, and not solely limiting thereto, protruding blocking member 460 may simply be one or more protrusions about siphon inlet 432, or may alternatively take the form of one or more hemispherical arches. While it is less preferable to terminate spray outlet 448 adjacent to siphon inlet 432, as will be further described herein below, protruding blocking member 460 will at least ensure that siphon 400 remains operational even when pressed against vessel wall 18 inadvertently.

(31) FIG. 6 illustrates the third alternative embodiment siphon, focusing on junction 450, by a bottom view with the spray outlet and drain lines disconnected. As visible therein, inlet wall 412 may be sloped or tapered from the inlet side towards ports 414, 416. This is also illustrated in FIGS. 7 and 8. This taper, which forms a wedge that subtends less than 180 degrees, and in this preferred embodiment only ninety degrees, keeps junction outlet 456 as open as possible. Inlet wall 412 thereby forms only a minimal obstruction to the outflow of fluid from tank 10. Additionally, in this embodiment jet port 416 is relatively centered with respect to junction outlet 456, and thereby, with respect to outlet 420.

(32) FIG. 8 additionally illustrates an optional jet port extension 417 which may be used to reduce turbulence within the output jet flow. While not critical to the operation of the invention, there may be times where the incorporation of this extension 417 are beneficial and preferred.

(33) FIGS. 9 and 10 illustrate an alternative embodiment inlet wall 512 by bottom and side elevational views, respectively. Rather than the wedge of inlet wall 412, these figures illustrate a beveled face 519 that similarly helps to reduce the impact of the protrusion of inlet wall 512 into the outlet fluid stream flow. As may be apparent, other geometries which through ordinary technical evaluation optimize the flow of the outlet fluid stream are contemplated herein, and considered to be incorporated herein.

(34) FIG. 11 illustrates a prior art cleaning system with the spray conduit retracted from the drain conduit. As illustrated therein, since return conduit 630 has a suction therein, fluid passing out of spray outlet 644 will tend to be drawn directly back into return conduit 630. Fluid will follow flow path 645 from spray outlet 644 into return conduit 630 without even exiting return conduit inlet 632. All fluid that flows directly from spray outlet 644 into return conduit 630 is wasted, since this spray outlet fluid never has an opportunity to contact vessel wall 18, or interact with the water within vessel 10 or matter 14 which is to be removed. While some fluid from spray outlet 644 may ultimately contact vessel wall 18, any fluid that does must first flow counter to fluid from vessel 10 flowing into return conduit 630. This will lead to turbulence, and substantially reduced flow either from vessel 10 into return conduit 630 or from spray outlet 644 into vessel 10.

(35) FIG. 12 illustrates alternative embodiment siphon 400 with spray conduit 440 terminating adjacent with siphon hose conduit termination 432. In this embodiment, fluid flowing from spray outlet 444 will follow flow path 445, and at least pass outside of siphon hose conduit 630 inlet. As a result, there will be some interaction between the cleaning fluid, vessel wall 18, and matter 14, which is a significant improvement over flow path 645 of FIG. 11.

(36) FIG. 13 schematically illustrates preferred embodiment siphon 100 adapted for cleaning vessels with spray hose 140 protruding from siphon hose 130. With sufficient separation between spray outlet 144 and siphon inlet 132, cleaning fluid exiting spray outlet 144 will mix into vessel fluid while traversing fluid flow path 145, and thereby entrain matter 114 therein. Further, the flow will form an eddy current as shown by the arrow for flow 145 that reinforces the entrainment and removal of matter 114 from vessel 10. As might be apparent from a comparison of the three FIGS. 11-13, the protruding spray hose 140 of FIG. 13 is vastly more effective at cleaning vessel wall 18 and removing matter 14 than either of the alternatives of FIGS. 11-12.

(37) The specific materials used in the fabrication of the various components within siphon 100 are generally not critical to the invention. Where importance has been given to the selection of materials, some suitable materials have been identified. Nevertheless, it will be obvious to one skilled in the art, upon a review of the present disclosure, to substitute other materials. Furthermore, the components as identified herein do not have to be fabricated in as few or as great a count as shown. Instead, several components may be fabricated as a single integral unit, or one component illustrated may be fabricated from several, as the needs of manufacturing become known for a particular design. Such substitutions are contemplated herein, in consideration with the functions which are outlined herein above.

(38) As aforementioned, a number of different chemical compositions are contemplated for use herein. Exemplary of these, but not solely limited thereto, are RV antifreeze, other storage solutions, and cleaning and treatment solutions such as vinegar and water solutions, phosphoric acid solutions, chlorinated solutions, alcohol solutions, and soap or surfactant solutions. Rather than supply such cleaning solutions to both inlet 142 and jet port 116, in some instances it may be desirable to introduce this solution solely to inlet 142. In such case, a separate injector, metering device, venturi, or other suitable means may be provided subsequent to the division of pressurized fluid and adjacent to or even within spray hose 140, through which additional ingredients may be introduced.

(39) While the most preferred application for the present apparatus is the cleaning of potable water vessels such as RV water heaters, the invention is not limited solely thereto. In the case of a pair of aquariums, with a first one elevated with respect to a second one, and with the inlet of a typical aquarium pump and filter combination inserted into the lower second aquarium, the present invention can be used to assist with circulation between the two aquariums, permitting the single aquarium pump and filter combination to service both tanks. This is accomplished by connecting the outlet from the aquarium pump and filter to fluid inlet 310 of FIG. 4. The spray outlet 344 is placed into the first elevated aquarium with siphon hose 330, and must protrude therefrom such as illustrated in FIG. 13. Next, outlet 320 is placed into the second lower aquarium. Valves 311 and 315 may then be controlled to adjust the amount of filtered water that passes into each tank. The height of siphon inlet 332 is what sets the top level of the first elevated tank. Should the elevated first tank receive an excess of water, this water will rise to the siphon inlet 332, and from there siphon through siphon hose 330 into the second lower tank without consequence.

(40) Similarly, the present apparatus may be used to clean aquariums, use the fluid stream to clean hard surfaces such as floors and counter-tops, and drain liquid from clogged plumbing fixtures. In one particularly diverse application, a spray outlet may be used to loosen and entrain earth and remove the earth through the siphon hose. As long as the spray outlet is advanced into the earth, this technique can be used to drill small diameter holes in the ground while continuously extracting the earth in the process.

(41) Consequently, while the foregoing details what is felt to be the preferred embodiment of the invention, no material limitations to the scope of the claimed invention are intended. Further, features and design alternatives that would be obvious to one of ordinary skill in the art are considered to be incorporated herein. The scope of the invention is set forth and particularly described in the claims herein below.