The current document is directed to electronic descaler units that propagate alternating currents through water in order to remove scale deposits from the surfaces of heating elements and the interiors of water heaters, pipes, and other water-containing equipment and, in particular, to an electronic descaler unit that automatically detects problems that inhibit descaler effectiveness and displays problem-identifying indications.
Scale deposits are generally composed of calcium and magnesium salts, including calcium carbonate, magnesium hydroxide, magnesium carbonate, and calcium sulfate. Precipitation of these salts is caused by thermal decomposition of bicarbonate ions as well as saturation concentrations of the dissolved salts in water resulting from temperature and pH changes. Precipitates of these salts produce scale that accumulates on the inner walls of plumbing pipes, heating elements in hot water heaters, and dishwashers. Water boilers, often used for heating buildings, have even greater scale problems because of elevated temperatures at which they operate. Any device that heats water or transports water has a potential for scaling problems. The scale builds up over time and clogs pipes, restricting water flow, and coats heating elements, rendering them far less efficient at converting energy into hot water. This, in turn, lowers the performance of appliances heat water and/or receive water from pipes and increases costs associated with heating water and storing hot water.
Descalers are electronic devices that transmit a time-varying electrical signal, referred to as a “descaling signal,” through the water in pipes, water heaters, and other water-containing equipment. Descaling signals alter the electro-chemical environment surrounding scale deposits, redissolving the calcium and magnesium salts of scale deposits and releasing the scale deposits from the inner surfaces of water pipes and on heating elements. The descaling signal also inhibits redeposition of scale build-up.
The descaling signal is introduced into water within a water pipe by either magnetic coupling or hard wiring. The majority of currently available descalers use magnetic coupling. Magnetic coupling is accomplished by either wrapping a wire coil around a pipe or by clamping a ferro-magnetic ring round the pipe. Installing a wire coil on a pipe is time consuming and often difficult when the pipe is mounted on a wall or other surface. Installing a ferro-magnetic ring is less time consuming, but ferro-magnetic-ring couplings tends to be fragile. In either case, magnetic coupling is an inefficient means of introducing a descaling signal into the water within a pipe. In comparison tests, it is common for a descaling signal introduced into water within a pipe by a direct-wire descaler to have fifty or more times greater amplitude than descaling signals introduced into water within the same pipe by magnetically coupled devices.
Hard wiring involves installing wiring directly to a short section of metal water pipe that is isolated from AC ground. An alternating voltage signal, using AC power ground for signal ground, is input to the metal water pipe through the wiring. Hard wiring inputs an electrical current into the water within a pipe far more efficiently than magnetic coupling. The short section of metal pipe is isolated from the AC ground of hot water heaters and other grounds connected to water pipes. In buildings constructed to latest building codes, water pipes are isolated from ground, allowing a descaler to be connected almost anywhere on the plumbing system. Many houses have water heaters with corrugated copper supply pipes that provide an excellent place to connect a direct-wire descaler.
AC grounded metal pipes present problems to both magnetically coupled and direct-wire electronic descalers. When a descaling signal traveling through water encounters an AC grounded metal pipe, the descaling signal shorts to AC ground and is no longer able promote descaling. The two most common causes of AC grounded metal pipes are: (1) using a metal water main for AC ground for the power system of building; and (2) not insolating metal pipes in contact with hot water heaters that are almost always connected to AC ground. Unfortunately, when descalers are installed, plumbing is generally not checked for AC grounding. Even when they are checked, events after installation can result in AC grounding of a plumbing system In many cases, currently available descalers appear to operate correctly but fail to produce sufficient descaling signals to descale the equipment to which they are coupled.
Direct-wire descaler devices may fail to effectively operate for another reason. Magnetically coupled devices may be plugged into either two-prong or three-prong outlets. Direct-wire descaler devices, by contrast, use the safety ground, referred to as the “green wire,” as signal ground for the descaler signal. When the three-prong outlet does not provide safety ground, as required by Uniform Building Code (“UBC”), the descaling device is not able to propagate a descaling signal into water within pipes and other equipment.
Descaling devices that work in one installation fail to work in others. “Power on” LEDs which appear to indicate that a descaling device is functioning, in fact only indicate that power is on, but do not indicate whether the power is being conducted to AC ground or whether, instead, the power is generating an effective descaling signal. As a consequence, there is widespread dissatisfaction in the descaling-device industry.
The current document discloses a ground-detecting direct-wire descaler that detects and indicates whether or not a descaling signal with sufficient current and voltage is produced or, in other words, detects and indicates whether the pipe or other equipment to which the ground-detecting direct-wire descaler is coupled is isolated from AC ground. AC-ground detection occurs both on initial power on and at regular monitoring intervals. In certain implementations, ground-detecting direct-wire descaler additionally detects and indicates whether or not the three-pronged outlet, into which the power-cord plug of the ground-detecting direct-wire descaler is inserted, conforms to UBC standards and therefore has safety ground available for use as signal ground. The ground-detecting direct-wire descaler only attempts to produce a descaling signal when safety ground is detected.
As discussed above, there are several problems associated with installation and operation of currently available direct-wire descalers. A direct-wire descaler needs to be coupled to a pipe or other equipment that is isolated from AC ground and a direct-wire descaler uses the safety ground provided by correctly wired three-prong outlets. When a direct-wire descaler is coupled to pipes or other equipment that is not isolated from AC ground and/or when a direct-wire descaler cannot access safety ground, the direct-wire descaler fails to produce an effective descaling signal. Currently available direct-wire descaler devices do not detect, indicate, or otherwise address these two problems, as a result of which they often fail to produce an adequate descaling signal. The currently disclosed ground-detecting direct-wire descaling device addresses both problems by detecting and indicating whether or not the three-pronged outlet, into which the power-cord plug of the ground-detecting direct-wire descaler is inserted, conforms to UBC standards and therefore has safety ground available for use as signal ground and by detecting and indicating whether or not the pipe or other equipment to which the ground-detecting direct-wire descaler is coupled is isolated from AC ground. Ground-detection occurs both on initial power on and at regular monitoring intervals. The AC grounding problem can be avoided or minimized by installing a descaler as far away from AC ground as possible. The currently disclosed ground-detecting direct-wire descaling device continuously outputs an indication of the strength of the output descaling signal as well as indicating whether or not the output descaling signal has a current or voltage less than a threshold current and voltage, with greater-than-threshold values indicating a short to AC ground. The currently disclosed ground-detecting direct-wire descaling device thus assists an installer in determining a direction in which a descaler can be moved along a pipe ameliorate lack of AC-ground isolation in addition to indicating whether or not an adequate descaling signal is being introduced into the water within a pipe or other equipment. This gives an installer of the currently disclosed ground-detecting direct-wire descaling device an opportunity to detect and correct AC ground problems and/or to find a connection point with an optimum decaling signal. AC-ground detection may also be added as a new feature to magnetically coupled descalers, according to the current document.
The ground-detecting, direct-wire descaler includes four status-indicator lights 104 and 114-116. In addition, the ground-detecting, direct-wire descaler includes a series of descaler-signal-strength-indicating lights, starting with a low-voltage light 118 and ending with a high-voltage light 120. The power light 104 is illuminated when the descaler is powered on. The AC-ground light 114 is illuminated when safety ground is detected by the descaler. The shorted light 115 is illuminated when the descaler determines that the voltage of the output descaling signal is sufficiently low to indicate that the water pipe 110 is not isolated from AC ground. The operating light 116 is illuminated when the descaler is properly functioning and outputting an effective descaling signal. The descaler-signal-strength-indicating lights are illuminated from the low-voltage light 118 rightward to indicate the voltage level of the output descaling signal. When a very high-voltage output signal is being generated, all of the descaler-signal-strength-indicating-lights are illuminated while, for descaling signals of less voltage, only a portion of the descaler-signal-strength-indicating lights are illuminated from the low-voltage light 118 rightward along the series of descaler-signal-strength-indicating lights. When the descaler fails to detect safety ground, only the power light 104 remains illuminated and the descaler does not attempt to output a descaling signal.
The AC-ground-detector circuit 204 receives AC hot 224, AC ground 226, and the second output voltage Vdd 230 and outputs an AC-ground-detect signal 232. When there is no AC ground, the AC-ground-detector circuit outputs a constant signal of voltage Vdd. When AC ground is present, the AC-ground-detector circuit produces a time-varying signal that oscillates between digital ground and Vdd. The AC ground-detector signal is converted, by an analog-to-digital converter or digital input 234 within the microprocessor module 208, to a digital AC ground-detector signal input to the microprocessor 236. The microprocessor module 208 additionally contains a non-volatile memory 238 and two additional analog-to-digital converters 238 and 240 that convert analog signals V1242 and V2244 into digital signals input to the microprocessor 236. The microprocessor executes control logic, implemented as microprocessor instructions stored in the non-volatile memory 238, to control operation of the descaler and the descaler display based on the input signals 232, 242, and 244. The microprocessor also controls a microprocessor-controlled relay 211 to connect digital ground to AC ground, when the relay is closed, and to disconnect digital ground from AC ground, when the relay is open. AC ground is disconnected from digital ground during monitoring of the AC-ground-detect signal by the microprocessor. The microprocessor 236 produces a digital square wave output 246 that is input to the amplifier/filter module 212. The amplifier/filter module 212 outputs a nearly perfect oscillating sine-wave descaling signal 250. The voltage drop across resistor 218 is measured by the microprocessor using a first voltage signal V1242 and a second voltage signal V2244, the voltages of which are equivalently reduced by resistor pairs 217/216 and 219/220. From the measured voltage drop across resistor 218, the microprocessor can determine the output voltage and/or current of the output descaling signal 250. Finally, the capacitor 222 acts as a filter that passes the outgoing descaling signal but blocks incoming oscillating signals of lower frequencies and also blocks the DC component of the descaling signal.
Using AC ground for signal ground presently requires additional FCC compliance. Magnetically coupled devices are required to pass FCC part 15a for industrial applications and FCC part 15b for home use. However, using AC ground for signal ground requires the descaler to also pass FCC part 18, which requires very careful design. The power supply both provides DC power to the internal circuits of the currently disclosed descaler and protects these circuits from the high voltage AC input. The AC ground detector connects to 90 to 250V AC to detect AC ground. The output of the ground detector is only a few volts DC so that the output does harm the microprocessor.
The AC-ground-detector circuit is included within the AC power supply, as shown in
The output load causes the power amplifier output to droop. This droop varies among different types of power amplifier. The circuit of
Although the present invention has been described in terms of particular embodiments, it is not intended that the invention be limited to these embodiments. Modification within the spirit of the invention will be apparent to those skilled in the art. For example, as discussed above, many different types of displays may be alternatively employed by the currently disclosed the scaler, including liquid crystal displays or even output to cell-phone applications for display of information on cell phones. In certain embodiments, the descaler may output indications to the Internet for access from various computer systems. Additional implementations that use fewer, a greater number of, or different electronic components are possible. Similarly, by varying any of many different design and development parameters, including choice of microprocessor, assembler or compiler, control structures, modular organizations, a variety of alternative implementations of the control logic are possible. As discussed above, the currently described ground-detection futures may additionally be incorporated within a magnetically coupled to the scaler.
It is appreciated that the previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present disclosure. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the disclosure. Thus, the present disclosure is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.
This application claims the benefit of Provisional Application No. 62/308,028, filed Mar. 14, 2016.
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Number | Date | Country | |
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62308028 | Mar 2016 | US |