TH7601B - Phase-controlled power modulation system - Google Patents

Abstract

The phase-controlled power modulation system switches the modulation switch in response to the condition of the circuit threat to avoid the need for downtime. The normal operation is in the phase-reverse control mode. Return (RPC) When an inductive load sensing machine detects the presence of an inductive load, the system switches to a phase-forward control mode (FPC) to reduce the peak of the inductive load. The voltage will produce a different effect from the load resistance to the voltage transition. When the overcurrent sensor detects the overcurrent, the system switches into the asymmetrical hybrid waveform (AFPC) mode to deliver maximum power while maintaining Remain in the power of the switch's current control. In the ACHPC mod, the RPC component of the half-cycle waveform is cut off at the current limit, while the FPC component of the same half-cycle waveform is ignited after The source voltage is lowered to a definite threshold below the current limit to ensure that the current limit is not re-ignited during the same half-cycle. In response to the resulting high temperature, the end-of-switch mode is permeated to reduce the heat generated at the switch until the temperature decreases.

Claims (3)

1.Phase-controlled power modulation system for modulation of power supplied to loads from AC generating sources. Which the system consists of Switch assembly for voltage regulation across the load, where the switch assembly is placed between the said load and the AC source, provided that the switch assembly has a choice of electric current. The least two states; Transition arrester for controlling the rate of change of the voltage applied to the load. When the switch assembly changes state In which the aforementioned transitions are coupled to the said switch assembly; Phase regulator for controlling the said switch assembly to make the phase control of the said power effective, that phase regulator determines the timing of the switching interval of the switch assembly. Where the phase regulator is coupled with such a transition morphology apparatus for igniting the switch; Switch protector for the protection of such switch assemblies responding to the condition of the control circuit. The protective switch includes a detector for detecting the threat of such circuitry; And asymmetric waveform selector for selection between normal operating modes, which are characterized by asymmetric waveforms in normal and protective modules, which are characterized by asymmetric waveforms in the protection modules. Where the asymmetric waveform in the protective module is different from the asymmetric waveform in the normal module. Where each protective waveform is morphed in such a way that Power delivered through the said switch assembly during the first 90 C of the electrical half-cycle. The alternating current will differ from the power delivered through the said switch assembly during the last 90 h of the same AC power half-cycle. The asymmetric waveform selector will be paired with the protective switch for determining when the switch between the normal and the protective module can be switched. Be coupled with the said phase regulator and / or with the said modulator for successful modulation of the selected modulator. 2. The phase-controlled power modulation system is described in Clause 1, whereby the detector detects the overvoltage condition across the load. The waveform selection machine that standard. This will cause the module to switch from normal reverse phase control module to forward phase type control module to prevent responding with such detection. 3. The phase-controlled power modulation system is described in Clause 1, whereby the detector detects an overcurrent condition through the switch assembly. The protection of such switches will limit the voltage drop in response to such detection. The asymmetric waveform selector causes the modulation from the normal phase-to-phase or reverse phase-type control to the symmetric hybrid waveform control module. To prevent responding to such detection 4. The phase-controlled power modulation system is described in Clause 1, in which the detector detects excess temperature around it. Such switch assembly Such asymmetrical waveforms are selected to cause the transition channel morphology to change the normal long transition time to short transitions to prevent response to such detection. say 5. The phase-controlled power modulation system is described in claim 1, in which the said shift regulator will cause the transition time between protection modules to be the same. The direct preceding period of normal operation 6. Phase-controlled power modulation system for controlling the power supplied to the load from an AC source, which consists of: a switch assembly for the control of the voltage drop across the load, the assembly. The switch is placed between the said load and the AC source; Phase regulator for driving the said switch assembly in order to make the phase control of such power in effect, in which the phase regulator drives the switch assembly in such a way that RMS voltage delivered through the said switch assembly during any one-fourth of a given AC cycle. This differs from the RMS voltage delivered through the said switch assembly during one quarter of the AC cycle. The said phase regulator is coupled to the switch assembly to make the drive effective; Voltage limiter for limiting such voltages in response to circuit threatening conditions. The detectors for the detection of such circuitry threat conditions, where the voltage limiter is coupled to the said switch assembly, to make the voltage limitation effective. ; And a switching regulator for making the transition layout of the load-voltage as a result with a secondary derivative with a negative mean. 7. Phase-controlled power modulation system for controlling the power supplied to the load from an AC source, which consists of: a voltage-controlled switch, a first switch and a second for control. The current flowing through the said load Where such a switch is placed in a reverse series connection between the load and the source of current; An analog to digital waveform conversion device for the analog waveform encoding in which the analog-to-digital waveform conversion device is coupled with a power source. Such alternating current for receiving the said analogue waveform from that power source. Where the analog to digital waveform conversion device has a digital output which provides a digital representation of the analog waveform; A processing device for calculating the RMS voltage and for determining the operating modulation of such voltage-controlled switchgear, which is coupled to the output of the conversion device. Such digital analog waves for square and integral representations are said to be digital. To provide the calculated RMS pressure Where the processing device has a digital output that outputs the ignition signal. When the calculated RMS voltage is achieved to the pre-set value; And a switching regulator for controlling the operation of such voltage-controlled switches in the active region for each transition period. Such a switching control device has an input to the trigger. Voltage input And the output of the switch control In which the igniter's inputs are coupled with The digital output of such a processor, the voltage input is coupled to the AC source. And the output of the switching control is coupled to the voltage-controlled switch. The switching control device provides a transition control signal at the output of the said switching control in response to the trigger signal. The transitional control signal maintains each such voltage-controlled switch operating at the active area during the transition period. In such a way that Will cause the load's voltage waveform to drop across that load in a curve. 8. Phase-controlled power modulation system for controlling the power supplied to the load from an AC source, such as: a voltage-controlled switch, a first switch and a second for current regulation. Electricity that flows through the jars The switch is placed in a reverse series connection between the load and the AC source; Analog-to-digital waveform conversion devices for analog waveform encoding in which the analog-to-digital waveform conversion devices are coupled to the source. The aforementioned AC power for the aforementioned analog waveforms from that power source. Where the analog to digital waveform conversion device has a digital output which outputs a digital representation of the analog waveform; Processing equipment for calculating the RMS voltage and for determining the operating modalities of such voltage-controlled switches to which the processor is coupled to the output. The analog-to-digital waveform conversion device is for such digital representation and integration. To provide the calculated RS pressure Where the processing equipment has a digital output, it will output the igniting signal. When the calculated RMS voltage is achieved to the pre-set value; And a switching regulator for controlling the operation of such voltage-controlled switches in the active region for each transition period. Such a switching control device has an input to the trigger. Voltage input And the output of the switch control The inputs of the igniter are coupled to the digital output of the processing equipment. The voltage inputs are coupled to the AC source. And the output of the switching control is coupled to the switch controlled by such voltage. The switching control device provides a transition control signal at the output of the said switching control in response to the trigger signal. The transitional control signal maintains each such voltage-controlled switch operating at the active area during the transition period. In such a way that Will cause the load's voltage waveform across the load to form a curve, the switching regulator includes Current controlled source devices for supplying a constant current in which such a controlled current source device has a regulated input. The controlled inputs will be coupled with the processing device. In such a way that The state of the current controlled source device is altered by the trigger signal. When the calculated RMS voltage is equal to the said pre-set value; A component with a condition of capacitance for the provision of such a switching control signal to the first switch voltage controlled switch. The capacitive layer is coupled to the aforementioned current-controlled source device and the aforementioned switch voltage-controlled switch. In such a way that Such an energized source device is loaded onto the charged component while such a controlled source remains on state; Voltage follower for monitoring the voltage potential on a component having a capacitive state to the aforementioned switch-control voltage-controlled switch; Electrodynamic synchro regulators for the provision of electromagnetic dynamics, in which the electrodynamic sync controllers have outputs and inputs, which the inputs are coupled to the a given AC source. Where the sync-control device of such dynamic will provide such dynamic current at the output of that device. That the dynamic current is in-phase with the said AC signal; The device that is the synchro of the capacitance of the parts having a capacitive state, in which the synchro of the device has an input of the dynamic current, the input of the feedback current. And charge period port Where the input of the dynamic current is coupled to the output of the synch-control device of such dynamic current for receiving such dynamic current. And the said discharge port is coupled to the parts having such a capacitive condition; And a feedback device for providing a feedback signal, the feedback device has inputs coupled to the said current source. The feedback device has an output coupled with the syncing device to provide a feedback signal that modifies the current that flows through the sync device. Electric current, such dynamics Will dynamically offset the sync device of the said current In such a way that Such a current sync device controls the charge of the charged component in response to the igniting signal. To cause the voltage waveform of such load to be a curve 9. The system is referred to in Clause 8, in which the aforementioned switching controls also include long / short switching controls. Which the long / short change control device has an input Where the input of the aforementioned long / short change control device is connected to the said processing device. In such a way that When voltage-controlled switch, that one such switch is thermally overloaded. The processor determines the operating module in which the first switch voltage-controlled switch operates. And if such a voltage-controlled switch operates in a reverse phase type control module The processing device causes such a long / short switching regulator to send a signal that accelerates such a current sync device to discharge the charged component. In such a way that The first such switch voltage controlled switch operates in the phase control module. The processing device causes such a long / short switching regulator to send a signal which blocks the synchro of such current from carrying the charged part of such a capacitor, thus causing the switch. Such a voltage-controlled first switch is a state-of-the-art 1 0. The system is referred to in Clause 8, in which the aforementioned dynamic synchroelectric device is a critical component. Resistance 1 1. The system is referred to in claim 9, where the long / short transition control device includes a resistance class 1 2. The system is referred to in claim 8, where In it, the feedback device is a component with a charge condition 1. 3. The system referred to in Clause 8 consists of an overcurrent detection device received between the said processing device and the device. Control that transition The overcurrent detection device is coupled to the voltage-controlled switch through sensing parts. The overcurrent detection device is coupled with the processing device for providing the switching signal to the switching regulator when an overcurrent occurs. The switching signal will turn the current-controlled source into an off state, so the charged parts will be discharged by the synch of the aforementioned current. 1 4. The system is mentioned in the hold. Article 13, in which the overcurrent detection device consists of: Sensing device for detecting current. In which the recognition device will be coupled with the said recognition piece To provide a sensory signal at the output when an overcurrent occurs; Detection device for comparing the aforementioned signal to a predetermined threshold and providing the comparison output. When the perceived signal is higher than the aforementioned threshold In which such detection equipment will have Benchmark device for comparing the aforementioned threshold threshold to the perceived signal, which generates the output of the comparison when the threshold is greater. Start such a predetermined replacement; And the flip-flop device receives a two-output logic output. The flip-flop device generates a first logical output and a second logical output in response to the output of the comparison. Where the first logical output is to be supplied to the processing device. To establish a phase control operation mod When an excess of electric current arises; And a logical gate for providing such a switching signal. The switching signal is coupled to the said current-controlled source device and the triggered signal from the processing device 1 5. The system referred to in Clause 8 also. This is an inductive load-sensing device, where the inductive load-sensing device provides a sensory output to the processor every time when the voltage is dropped. The load is greater than the reference potential and when the sequential pulse output is pre-set number. Which the processing device will send the said ignite signal To switch the operating mode of such voltage-controlled switch to phase 1 control operating module 6. The system is referred to in Clause 8, in which, during the warm-up period of the said load. The processor puts a voltage-controlled switch into an off state at the moment when the AC voltage rises, drawing an overcurrent threatening voltage. And the processor puts the voltage-controlled switch on again when the AC voltage drops to a pre-set value lower than the overcurrent threatening voltage. Such In such a way that Two power pulses are applied to the load during the AC voltage half-cycle. 1 7. A controlled power modulation system. Phase for the control of the phase angle of the current flowing through the load from an alternating current source (AC), which includes: a pair of voltage-controlled switches for controlling the current flowing through the jars. say Which the switch is controlled by the second switch voltage Where the two switches are in reverse-series connection between the load and the AC source; Analog to digital conversion device (A / D) for converting analog signals from the said AC source into digital signals. Which device to convert A / D is coupled to the a given AC source and delivers digital output; The processing device accepts the calculation of RMS voltage and for determining the operating modulation of such voltage-controlled switches; The processing device must be coupled to the output of the a / A / D conversion device for the average square calculation. (RMS) of the digital output signal. The processor calculates the said RMS value, which is compared with the aforementioned predefined value. The processing device outputs a control signal to make the first switch voltage-controlled switch off state.The processing device calculates the phase angle, the transition interval of the second switch-controlled voltage. Such on the basis of the said phase-change angle of the aforementioned voltage-controlled switchgear; The processor monitors the thermal overload of the voltage-controlled switch. And when there is an overload of the heat generated The processing device provides such a control signal to quickly perform the total rapid switching of such voltage-controlled switches, so the thermal overload will be moderated; An overcurrent detection device for the detection of overcurrent, which is to be coupled to the processing device and when there is an overcurrent, it receives the control signal from the processing device. Such result The overcurrent detection device sends an igniter signal; And switching regulators for the control of such voltage-controlled switches are operated at the active area for each transition period. In such a way that The voltage waveform supplied to the load is curved to reduce the interference that the switching regulator will have. Current controlled source devices for stable power distribution where regulated inputs have regulated inputs. Where such a regulated input is coupled to the said overcurrent detection device. To receive the fuze signal, which determines the operating modulus of the source of such current control; Part with a capacitive condition for the provision of such a switching control signal to the aforementioned switching voltage control switch. Such capacitive parts are coupled to the said current-controlled source device and the gate of the voltage-controlled switch. Where the charged parts will be charged by the current controlling device. Voltage follower for making the voltage potential on such a capacitive layer equal to the gate of the aforementioned voltage-controlled switchgear; A dynamic synchro controller for providing the output of a dynamic synchro, a dynamic synchro controller has inputs and outputs that are coupled to the a given alternator. Where the synch-control device of such dynamics provides the output of such dynamic control; Feedback device for the feedback signal arrangement The feedback device has an input that is coupled to the a given alternator. Where the feedback device has an output for providing feedback; The device that is the synchro of the discharging current of the parts having such a capacitive state, the device that is the synch of such current has an input of dynamic current, the input of the feedback current. And charge port Where the input of such dynamic current is coupled to the output of such dynamic current regulator, the input of such dynamic current is coupled to the output of the feedback device. It will be coupled with parts having parts having such capacitive conditions. Where such dynamic currents and feedback currents are dynamically altered the current through the synch of the apparatus; And a long / short changeover regulator for the sync current control of such current sync devices where the long / short switching regulator has inputs and outputs. Where the input is connected to the said processing device And the said output coupled with the said electrolytic device; When a voltage-controlled switch, the first such switch produces thermal overload. The processing equipment provides a contract for such a long / short transition control device. To change the sync current; When the first such switch voltage-controlled switch is operating during a reduced transition period of the reverse phase-controlled modulation. The output signal of such a processing device causes such a long / short changeover regulator to send a signal that will accelerate the sync device of such a current, causing the discharge of the charged parts. Such In such a way that This will turn the first switch voltage-controlled switch into a fast off state; And when the first such switch voltage-controlled switch is operating during an incremental shift of the phase control operating module. The processor causes the long / short switching regulator to send a signal that interferes with the synced current device from discharging the charged component. In such a way that The first switch voltage-controlled switch will quickly become an on state. 1. 8. The system is referred to in Clause 17, wherein the load will operate during the warm-up period. Which such processing equipment The first switch voltage-controlled switch becomes off state at the time when the AC voltage across the first-controlled switch voltage rises to the voltage threatening current. over; This will cause the switch to be controlled by such first switch voltage to be on state at the time in which the alternating phase voltage drops to a pre-determined value below the voltage that threatens the overcurrent half-cycle. The first machine; It records the phase angle at which the first switch voltage-controlled switch is made off-and-on; And will switch such a second switch voltage controlled switch to the on state during the second half cycle as a function of the recorded phase angle 1 9. The system is referred to in Clause 17. It also consists of an inductive load sensing device where an inductive load sensing device has a detection input coupled to that load. The inductive load recognition device provides the output of the sensing signal to the processing device. When this device detects an inductance The processing device sends such a control signal. For such voltage-controlled switch-over, it is operated in the phase-forward control module (FPC) 2 0. The system is described in the claim. Article 17, in which the processing device performs such voltage-controlled switching on the first half-cycle. Will measure the frequency of the first half cycle. And will calculate the delay time to do the switching interval of the said second switch voltage controlled switch. In such a way that Such first and second switch voltage controlled switches have a phase difference of 180C2. 1. The phase-controlled power modulation system is described in Clause 1, in which such a switching regulator makes the load-voltage transition layout to, with a second-order derivative with a mean of Minus 2 2. Phase-controlled power modulation system for controlling the power supplied to the loads from an AC source. It includes: A switch assembly for controlling the voltage drop across the load. Where the aforementioned switch assembly is placed between the load, the a given alternator; Phase regulator for driving the said switch assembly to make the said phase control effective. In which the said phase regulator will crack the switch assembly In such a way that RMS voltage delivered through the said switch assembly during any one of the assigned a.c. This differs from the RMS voltage delivered through the said switch assembly during one-fourth of the AC power cycle. In which the control phase will be connected to the coupling In such a way that Such a switch assembly will make such driving effective; And a transition control device for the resulting pressure load transition layout, with a second derivative with a negative mean 2. 3. The phase-controlled power modulation system is described in Clause 7, in which the processing device calculates such a pre-determined value as a function of the ar value. RMS of the aforementioned AC waveforms and RMS voltage delivered to such loads as Func. The steepness of the period of the said transition period