1. Technical Field
The present invention relates generally to swimming pools and more specifically relates to disinfecting water contained in swimming pools.
2. Background Art
Chemicals used for swimming pool water disinfection must meet certain conditions in order to be useful. They should be relatively harmless and non-irritating to swimmers and attendants. They must be active in small concentrations and remain their activity for a relatively long period of time. Contrary to drinking water disinfectants, disinfectants used for swimming pool treatment must be active in the pool itself, because pollutions and pathogenic microorganisms are constantly added to the water. Therefore, it is necessary for the water to maintain a residual disinfectant concentration. The disinfectant should also be easily traced and measured and should be safe to store and use under normal operating circumstances.
Chlorine-based disinfectants are among the most frequently applied disinfectants and oxidizers for swimming pool treatment. Generally, chlorine [hypochlorous acid (HOCl) or hypochlorite (OCl−)] in the form of liquid or tablets is introduced into a swimming pool or other body of water in order to minimize the growth of undesirable algae, bacteria, mold, etc.
It is desirable to keep the concentration of chlorine in the swimming pool at a relatively stable level because either too much chlorine or too little chlorine can cause problems. The level of chlorine needs to remain relatively high because if the concentration of chlorine in the swimming is too low, the water will be unsafe for swimmers. However, if the concentration of chlorine is too high, the excess chlorine can cause eye and mucous membrane irritation, as a result of chloramine formation.
Although standards for chlorine concentration in swimming pools vary, one typical threshold for available chlorine sets a minimum concentration for swimming pools at 0.5 mg/l. A typical maximum threshold level is set to 1.5 mg/l. When using cyanic acid as a stabilizer, atypical minimum and maximum threshold values might be set respectively at 2.0 mg/1 and 5.0 mg/L. For outdoor swimming pools and indoor pools smaller than 20 m2, the maximum chlorine concentration level may be set to 5.0 mg/l.
While there are a number of devices and methods used for stabilizing the chlorine concentration in swimming pools, most fall short in one or more ways. For example, it is not uncommon to introduce liquid chlorine directly into the water. However, liquid chlorine can be very corrosive and caustic. Containers of liquid chlorine can also release chlorine gas when opened, so it is important to avoid breathing the fumes. Finally, liquid chlorine may be difficult to store over long periods of time.
Another popular chlorination method involves the use of chlorine in the form of small tablets. This method uses a “floater” device to contain the tablets for use in the swimming pool. Often manufactured in the shape of a duck or small cylindrical device, this buoyant product is designed to hold one or more chlorine tablets and float on the surface when it is placed into a body of water (e.g., swimming pool). A number of apertures or openings are typically formed in the body of the floater device and water from the swimming pool is allowed to flow though the openings, contacting the chlorine tablets and, as the chlorine tablets dissolve, chlorine is introduced into the water contained in the body of water.
While this device successfully adds chlorine to the water, there are a number of problems. Since the device floats on the surface of the water, the chlorine is added to the surface of the water where, depending on the ambient conditions, it may rapidly dissipate into the surrounding atmosphere. Additionally, the device is designed to float on the surface, making it an attractive target for young children who may view the device as a “toy” to be played with. Prolonged contact with the chlorine tablets may cause harm to any child who handles the device. Further, it is relatively difficult, if not impossible, to determine when or if the chlorine tablets contained inside the floating device have completely dissolved. This means that the floating device may be empty for some period of time and no chlorine will be added to the swimming pool until someone remembers to check the device to determine that the tablets have dissolved. So, while relatively simple to use, the floating chlorination device is far from perfect.
Accordingly, without additional improvements in the equipment and methods used in swimming pool chlorination, the ability of swimming pool owners and operators to stabilize chlorine levels at desirable levels will remain suboptimal.
An apparatus for enhanced chlorination of bodies of water (e.g., swimming pools) is disclosed. The apparatus has a variable total mass (and buoyancy) based on the combination of the mass of at least one chlorine tablet placed into the body of the apparatus and the inherent mass of the apparatus itself. When the apparatus, with the chlorine tablet(s) inside, is placed into the swimming pool, the apparatus sinks towards the bottom of the swimming pool. As the chlorine tablet(s) dissolve, chlorine is released into the water contained into the swimming pool and the apparatus begins to rise towards the surface of the pool. Once all or substantially all of the chlorine tablet(s) have dissolved, the apparatus reaches the surface of the pool where it signals the need to place more chlorine tablet(s) into the apparatus. Once the apparatus has been refilled with chlorine tablets, it can be simply placed back into the swimming pool.
The preferred embodiments of the present invention will hereinafter be described in conjunction with the appended drawings, wherein like designations denote like elements, and:
In general, according to the fifth proposition of Archimedes, any object, wholly or partially immersed in a fluid, is buoyed up by a force equal to the weight of the fluid displaced by the object. In the real world, this principle is observed by noticing that an object tends to become more buoyant in water as it loses mass, due to the relationship between mass and weight.
In accordance with the most preferred embodiments of the present invention, an apparatus is configured to accept one or more chlorine tablets into the body of the apparatus. When the apparatus, with the chlorine tablets inside, is placed into the swimming pool, the apparatus sinks towards the bottom of the swimming pool. The combined weight/mass of the chlorine tablet and the apparatus changes over time as the chlorine tablets inside the apparatus dissolve. As the chlorine tablets dissolve, chlorine is released into the water contained into the swimming pool and the apparatus begins to rise towards the surface of the pool. Once all or substantially all of the chlorine tablet(s) have dissolved, the apparatus reaches the surface of the pool where it signals the need to place more chlorine tablet(s) into the apparatus.
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When apparatus 100 is to be deployed for chlorinating the water in the swimming pool, one or more of caps 110 may be removed and the interior space of body 120 is provided with one or more chlorine tablets (not shown this FIG.). The inner diameter of body 120 is manufactured to be compatible with the outer diameter of standard chlorine tablets, allowing the chlorine tablets to be positioned within the interior space of apparatus 100. The addition of the chlorine tablets to the interior space of body 120 will increase the effective mass of apparatus 100, thereby creating a less buoyant apparatus 100.
When placed into a body of water, apparatus 100 will gradually sink towards the bottom of the swimming pool by virtue of the combined mass of apparatus 100 and the chlorine tablets that have been positioned inside apparatus 100. Further, once apparatus 100 has been placed into the water, water will enter body 120 via apertures 130, allowing the water to contact the surface of the chlorine tablets. The chlorine tablets will gradually dissolve and release chlorine into the water via apertures 130, thereby chlorinating and disinfecting the water. As the chlorine tablets dissolve, the combined mass of apparatus 100 and the chlorine tablets will be reduced and less water will be displaced by apparatus 100. The result will be that apparatus 100 will gradually rise to the surface of the water, chlorinating the water as it rises. By controlling the number of apertures 130 formed in body 120 and by controlling the number of chlorine tablets placed into body 120, the appropriate amount of chlorine for various amounts of water can be provided by apparatus 100. In the most preferred embodiments of the present invention, apparatus 100 will be configured with some type of buoyant material in one cap 100, thereby urging apparatus 100 to maintain a substantially vertical position in the water along a vertical axis 150.
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Once in the water, the chlorine tablets in the interior space of the apparatus will gradually be dissolved via surface contact with the water in the swimming pool (step 740) and the chlorine from the dissolving tablet(s) will provide chlorination for the water in the swimming pool and, as that combined mass of the apparatus and the chlorine tablets is reduced, the apparatus will begin to rise towards the surface of the water (step 750). Once the apparatus is once again floating at or near the surface of the water, the operator of the swimming pool will be able to make visual contact with the apparatus and the cycle of method 700 can be repeated.
From the foregoing description, it should be appreciated that an enhanced apparatus and methods for chlorinating swimming pools is provided by the various preferred embodiments of the present invention and that the various preferred embodiments offer significant benefits that would be apparent to one skilled in the art. Furthermore, while multiple preferred embodiments have been presented in the foregoing description, it should be appreciated that a vast number of variations in the embodiments exist. Lastly, it should be appreciated that these embodiments are preferred exemplary embodiments only and are not intended to limit the scope, applicability, or configuration of the invention in any way. Rather, the foregoing detailed description provides those skilled in the art with a convenient road map for implementing a preferred exemplary embodiment of the invention, it being understood that various changes may be made in the function and arrangement of elements described in the exemplary preferred embodiment without departing from the spirit and scope of the invention as set forth in the appended claims.
This non-provisional patent application claims the benefit of U.S. Provisional Patent Application Ser. No. 61/267,428, under 35 U.S.C. §120, which application was filed on 7 Dec. 2009, which application is now pending and which application is incorporated by reference herein.
Number | Date | Country | |
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61267428 | Dec 2009 | US |