Patent Application
20100309601
1. Field of the Invention
The present invention relates generally to electronic circuits that generate output pulses. More particularly to a controller for driving a 2-position magnetic latching solenoid or any other similar devices.
2. Description of the Prior Art
Digital magnetic latching solenoids, latching relays and solenoids are very useful and widely are used in the industrial, defense and consumer fields. The main attraction for this type of solenoid is a much less power required for operating then comparable non-latching devices. Because coils in magnetic latching devices are energized only for a short time, using non-latching devices, the applied power must be present continuously during the energized state.
There are a number of means for controlling (driving) a magnetic latching devices on the market, but most of them use microprocessor-based devices, and all of them require substantial power for operations. This has precluded existing devices from being useful for long-term, battery operation. What is badly needed is a device capable of working with a single switch to generate a corresponding output pulse.
The present invention relates to a controller for driving a 2-position magnetic latching solenoid or any other similar devices. It is adapted for use with 3-wire control magnetic latching electrically operated solenoid valves. More specifically, the present invention relates to a micro-power device designed for continuous battery power operations and installed in remote locations and/or used in long-term unattended operations.
The controller can replace many residential and light-commercial irrigation controllers such as those manufactured by Hunters Industries Inc., Hit Products Inc., Irritrol Systems, Omega Engineering Inc. and many others. It is designed for a long-terms (years) of unattended operation to automatically maintain a pressure but limited to many other similar application with two three auxiliary devices, a pressure switch, a 2-position magnetic latch solenoid valve and a power source (battery).
An embodiment of the controller containing a thermostat (temperature measuring device) can maintain temperature via controlling a heating element.
Attention is now directed to several figures that better described the present invention:
Several illustrations and drawings have been presented to aid in understanding the present invention. The scope of the present invention is not limited to what is shown in the figures.
The controller of the present invention is designed to provide a large pulsing current onto a coil to insure a fast movement of the plunger of a solenoid. This, in turn, allows the controller to be adapted for use in activating the magnetic-latching solenoids and other similar devices.
The controller of the present invention can work with any auxiliary devices that have a dry contact (like a relay's terminal, a thermostat, or pressure switch) and a solid-state output (like a transistor). The input circuitry of the controller detects transitions from either a closed input (shorted—an input switch is turning-on); or open (an input switch is turning-off). The controller of the present invention generates an internal pulse, the duration of which can be adjusted to the required width to insure creation of a proper output pulse for activating an auxiliary device that can be any type of existing device that can be controlled by a pulse.
The controller of the present invention can detect and recognize the state of the input (either closed or open) and direct the gate control signal to the appropriate output which is a power driving device (such as a power MOSFET).
The controller of the present invention can have two outputs. Each output can independently include a powerful MOSFET or IGBT device that is capable of conducting a large amount of current with an extremely low power control signal applied onto the gate.
The controller of the present invention is designed for years of operation from a low-power battery when another power source is used for driving the auxiliary load. It consumes an extremely low power and needs less then 10 uA for operation.
The controller is designed to minimize current consumption achieved by selecting micro-power semiconductors and selecting resistors of extremely high resistance value. Turning to
During stationary operation, when the input is either maintaining an open or a closed position, the controller does nothing, and its status is very similar to a stand-by status or a “sleeping” mode. The controller reacts only when the input condition is changing (dynamic); either when the input is closing or the input is opening. The device U7A performs three functions. It works as a comparator comparing the input voltage with the reference voltage; it is a buffer amplifying an extremely a low power input voltage; and it is a formatting circuit for falling and rising slopes.
Amplified input voltage is applied onto a differential (C−R) network which consists of capacitor C8 and resistors R26/Rimp (the input impedance of the U7B) and R1. That differential network formats short duration pulses from a falling (negative going) edge and rising (positive going) edge, and inverts the negative pulse. In short, U7B performs two functions: it amplifies a positive input signal and inverts and amplifies a negative input signal thus generating two positive pulses on its output pin #7. Positive pulses via the OR gate U12A are applied onto the input of a one-shot generator U8.
The one-short generator U8, generates a narrow pulse with duration defined by around 0.73×C9×(R24+R18). The potentiometer R18, helps to set the most optimum pulse width for delivery of the right amount of power to the coil. The U8 output pulses from pin #10 are applied onto AND gates, U11A and U11B (pins #2 and pin #5 respectfully). Both AND gates along with inverter U13A perform the input status detection and direct the output pulse from U8 into the proper output channel. A first channel is chosen when the input is in a first state, and a second channel is chosen when the input is in a second state. U15A and U15B are MOSFET or other power drivers. MOSFETs are preferred because of their low on resistance; however any power output device can be used including bipolar power transistors. Also, while two channels are shown, the controller can be made with any number of channels that can be controlled by various combinations of input signals. It should be noted that while the circuit in
The controller can be reset two ways. Reset can be accomplished by an external device such as a switch or any other “smart” device remotely, or by internal circuitry during application of power onto the controller. The internal circuitry to reset the controller includes C1 and R5 as a differential network which produces a positive going pulse during the power supply (from a battery for an example) turn on. In both cases, a trigger pulse is created via the OR gate onto the input of the pulse formation circuitry on the power-up. That circuit, together with the input status detection circuit, performs an important function. It insures generation of an output drive pulse onto the corresponding output; even when the input switch is in a stationary position (either in an on or off). Generating an output pulse on a power-up eliminates a chance of a false position of a solenoid (valve) at initial connection to a power source (battery) such as replacement of an old battery or accidental power supply interruption.
Several descriptions and illustrations have been provided to aid in understanding the functioning and construction of the present invention. One with skill in the art will realize that numerous changes and variations are possible without departing from the spirit of the invention. All of these changes and variations are within the scope of the present invention.
