This invention relates to the chlorination of swimming pools.
“Swimming pools” as used herein is used interchangeably with “pools” to refer to swimming pools, spas, Japanese hot tubs and like bodies of water for bathing.
Electrolytic chlorinators are used in swimming pools to produce sanitizer. Typical electrolytic chlorinators include a cell and a remotely mounted control unit for controlling the cell. A set of spaced electrodes are mounted in the cell and energised by the control unit. Water from the pool is driven by a pump to move through the cell. As the water moves through the cell it is electrolysed to convert dissolved salts into sanitizer.
In some existing pool water treatment systems, the pump is powered by an outlet socket in the chlorinator controller. The outlet socket is turned on and off by an inbuilt timer system in the chlorinator controller to ensure there is sufficient water flow to safely operate the cell. The outlet socket provides power to the pump which operates at a predetermined speed or flow rate.
The performance of the pump should match the performance of the chlorinator. If the water is flowing too slowly, the gaseous products of electrolysis, predominantly hydrogen and oxygen, may accumulate in the cell, filter or other equipment. This is dangerous. On the other hand, if the water is flowing faster than needed the pump is likely consuming significantly more power than needed. This is wasteful. Moreover the pump is likely generating more noise and heat and is likely to wear out sooner.
In the past pumps have been selected to effectively back wash or clean a sand filter and circulate water to all parts of the pool. This may well be a compromise between a flow rate best suited for the filtration cycle and circulation of water and the requirement to back wash a sand filter or vacuum the pool. The inventor has realised that the flow rate of the selected pump is typically not ideal for electrolytic chlorination. Moreover, suppliers must carry a range of pumps to suit a range of desired flow rates.
More recently variable speed pumps, including multi-speed pumps and continuously variable speed pumps, have been applied to swimming pools. While such pumps go some way to addressing the problems of single speed pumps their introduction has complicated the control arrangements associated with swimming pools. An existing approach involves the addition of a control panel which sends control signals to the chlorinator and the pump.
It is an object of the invention to simplify the control arrangements associated with swimming pools.
It is not admitted that any of the information in this patent specification is common general knowledge, or that the person skilled in the art could be reasonably expected to ascertain or understand it, regard it as relevant or combine it in any way at the priority date.
Accordingly the invention provides a control unit for a swimming pool electrolytic cell, comprising:
In preferred forms of the invention the pump is configured to operate at a plurality of discrete performance settings, e.g. three discrete performance settings. The logic module may be configured or configurable to specify one, e.g. a lowest, of the discrete performance settings to suit electrolytic chlorination. By way of example each discrete performance setting may deliver a respective constant speed (rpm), pressure or flow.
Preferably the logic module is configured or configurable to selectively supply power and control in accordance with a timetable. Most preferably the schedule includes two or more periods in which the pump is active and the logic module is configured or configurable to control the output of the pump to deliver during at least one of the periods an output which differs from the output during at least one other of the periods in which the pump is active.
According to another aspect, the invention features a water treatment system including the control unit, electrolytic cell, and the pump.
According to a still further aspect, the invention features a pool installation including the water treatment system and a body of water.
Various exemplary features are illustrated.
The following examples are intended to illustrate the scope of the invention and to enable reproduction and comparison. They are not intended to limit the scope of the disclosure in any way.
The system 1 further includes a control unit 10 for controlling the pump 2 and the cell 5 in a coordinated manner. As illustrated in
The control unit 10 further includes a second, output electrical connection component 18, e.g., in the form of a socket, adapted to connect the electronics of the control unit 10 to the cell 5 so as to provide energizing electrical power to the electrodes of the cell 5. For example, a lead 16 could terminate in a plug cooperable with the socket 18 to connect the control unit 10 and the cell 5.
The control unit 10 also includes a data outlet 22 in the form of a socket adapted to send control signals to the pump 2. A lead 20 could terminate in a plug cooperable with the socket 22 to connect the unit control unit 10 and the pump 2.
The control signal may take a variety of forms. Preferably a transformer (not shown) is interposed along the lead 20 and connected to the mains supply to supply a voltage of 24 volts to the lead 20, and the electronics of the module 10 receive this voltage and generate a signal by varying a milliamp current along the lead 20. Alternatively the electronics of the control unit 10 may supply a voltage to the lead 20. Indeed, power sufficient to power the pump 2 and data may be simultaneously transmitted along the line 20 in the manner of power line communication (PLC). The use of PLC could allow a conventional power socket to be a data outlet. In a simple implementation of the invention, the lead 20 and the socket 22 may define multiple conduction paths corresponding to separate speed windings within the pump motor, in which case the control signal would be the selective energisation of the conduction paths.
In a preferred form of the invention the control unit 10 powers the pump 2 via a separate power lead 21.
The control unit 10 includes a logic module 11 for controlling the efficient operation of the pump 2 and of the cell 5, which logic module 11 could be implemented via hardware, software, or a combination of hardware and software. In the illustrated arrangement, the logic module 11 includes a timing arrangement to operate the pump and the cell in accordance with a timetable 11a. It is also contemplated that the control unit may simply operate the pump and the cell in response to various inputs, e.g. in response to a sensor 13 indicative of sanitizer concentration in the pool water and/or a sensor 15 located within the cell 5 (e.g., right by the cell's positive and negative electrodes, as schematically illustrated) indicative of sanitizer production levels in the cell 5. Preferably the timetable is structured for an operating period in the vicinity of four hours each morning and each evening to treat the pool water before and after the sun is out. Sunlight tends to destroy pool sanitizer. Treating the water outside of daylight hours is more efficient because the sanitizer lasts longer to destroy more undesirable biological species.
The described pump 2 may be a three-speed pump incorporating an infinitely variable motor and a variable frequency drive configured to define the three speeds. Desirably each of the three speeds may be selectably varied to suit different operations. The electrodes may not be energised during all periods when the pump is active. Preferred variants of the control unit are configured to control the output of the pump to suit filter system and pool circulation requirements.
The control signals from the control unit 10 tell the pump 2 at which of the three speeds it should operate. Typically the lowest speed setting will be configured to suit chlorination. The higher speed settings are reserved for other operations such as operating a vacuum cleaning apparatus or more rapidly filtering and cleaning a cloudy pool.
The control unit 10 preferably includes a user interface 24, illustrated in
Via the interface 24, a user can set the on-time for the cell 5 and the speed at which the pump is to operate while the cell is on (e.g. high, medium, or low) and then select the time at which the chlorinator and pump should turn off. The described variant of the invention allows for up to four operating periods per day to be scheduled in the timetable. The operating periods may have different durations and pump operating speeds. The control unit 10 is desirably mounted remotely from the pool to permit convenient access to its user interface 24, although it is also contemplated that the logic module might be integrated with one of the pump 2 and the cell 5.
Preferably the logic module is configured to deliver a low pump output for most of the day and to periodically throughout the day increase the output of the pump. Operating at a low output is energy efficient but carries the risk of voids of uncirculated, or poorly circulated, water in the pool. Periodically operating the pump at higher output desirably moves the water in these voids.
It is desirable that the control unit be configured to de-energise the electrodes prior, say about five minutes prior, to deactivating the pump. This reduces the risk of sanitizer, such as chlorine, concentrations sitting in components of the pool water treatment system and in turn reduces the risk of accelerated corrosion of these components. In particular, gas heaters are susceptible to corrosion caused by accumulated sanitizer.
It will be appreciated that various modifications to and departures from the exemplary disclosed embodiments will occur to those having skill in the art. What is deemed to be protected is set forth in the following claims.
Number | Date | Country | Kind |
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2012901107 | Mar 2012 | AU | national |