Abstract: A controller of an elevator for reducing the number of execution times of uniform charging of a power accumulating device and having higher energy saving effects. The controller has a converter, an inverter, a power accumulating device arranged between DC buses, a charging-discharging control circuit for controlling charging and discharging operations of the power accumulating device, and a charging-discharging state measuring device for measuring at least one of temperature, charging and discharging currents, and charging and discharging voltages of the power accumulating device. The charging-discharging control circuit sets the execution of uniform charging of the power accumulating device on the basis of an output of the charging-discharging state measuring device, and executes only the required uniform charging. Thus, an elevator with the power accumulating device having larger energy saving effects is constructed.

Abstract: An elevator controller providing stable speed control using a cheap power accumulating device having a low capacity even in discharging. The controller has a converter, an inverter, a power accumulating device arranged between DC buses, a charging-discharging control circuit for controlling charging and discharging of the power accumulating device, a power failure detector, a current measuring instrument and a voltage measuring instrument for respectively detecting an output current and an output voltage of the inverter, a car load measuring instrument, an encoder, and a speed control circuit for controlling the inverter. The speed control circuit calculates output power of the inverter, and calculates discharging power of the power accumulating device on the basis of a measured value of charging and discharging states.

Abstract: A controller of an elevator in which space for mounting a power accumulating device can be saved and the controller can be applied to an elevator having no machine room. The controller has a power accumulating device arranged between DC buses connected to a converter and an inverter, and accumulating DC power from the DC buses during a regenerative operation of the elevator and supplying the DC power accumulated to the DC buses during a power operation; and a charging-discharging control for controlling charging and discharging of the power accumulating device with respect to the DC buses. The power accumulating device includes a secondary battery and a DC—DC converter for controlling charging and discharging of the secondary battery, and the secondary battery includes plural cells connected in series. The secondary battery is arranged at any one of four corners within an elevator shaft, near a rail, or near a cable within the elevator shaft.

Abstract: An elevator control apparatus solves a major problem with a conventional elevator control apparatus in that an elevator cannot be operated in case of a power failure of a commercial power source because the controlling apparatus constantly consumes power supplied from the commercial power source. The elevator control apparatus includes: a power storage unit for storing the DC power; a charge/discharge control circuit that controls a state of charge of the power storage unit, outputs a drive signal to charge the power storage unit with the DC power during a halt of the elevator based on operational information regarding the elevator received from the controller, and outputs a stop signal to stop charging when a voltage of the power storage unit reaches a preset predetermined voltage; and a charge/discharge circuit for starting charging the power storage unit with the DC power in response to the drive signal, and stopping the charging in response to the stop signal.

Abstract: This invention provides a controller of an elevator for stably controlling regenerated power by using a cheap secondary battery of a low capacity without damaging energy saving effects obtained by charging.

Abstract: This invention provides a controller of an elevator in which a space for mounting a power accumulating device can be saved and the controller can be applied to the elevator having no machine room. Therefore, the controller has power accumulating means arranged between DC buses between a converter and an inverter, and accumulating DC power from the DC buses at a regenerative operation time of the elevator and supplying the DC power accumulated on the DC buses at a power running operation time; and charging-discharging control means for controlling charging and discharging operations of the power accumulating means with respect to the DC buses. The power accumulating means is constructed by a secondary battery and a DC-DC converter for controlling charging and discharging operations of the secondary battery, and the secondary battery is constructed by connecting plural cells in series to each other.

Abstract: An elevator control apparatus solves a problem in that electric power produced in a regenerative mode of an elevator is thermally consumed by a regenerative resistor or the like rather than being effectively used.

Abstract: This invention provides a controller of an elevator for reducing the number of execution times of uniform charging of a power accumulating device and having higher energy saving effects. Therefore, the controller has a converter 2, an inverter 4, a power accumulating device 11 arranged between DC buses 3, a charging-discharging control circuit 15A for controlling charging and discharging operations of the power accumulating device, and a charging-discharging state measuring device 14A for measuring at least one of a temperature, charging and discharging currents, and charging and discharging voltages of the power accumulating device. The charging-discharging control circuit 15A sets the execution of uniform charging of the power accumulating device on the basis of an output of the charging-discharging state measuring device, and executes only the required uniform charging. Thus, an elevator with the power accumulating device having larger energy saving effects is constructed.

Abstract: An elevator control apparatus solves a major problem with a conventional elevator control apparatus in that a state of charge of a battery is not always maintained at 100% because of the need for securing an allowance for charging regenerative electric power, causing generation of an inert material in the battery with a resultant decrease in an apparent charging capacity of the battery and a shortened life of the battery.

Abstract: An elevator control apparatus solves a problem in that charging and discharging characteristics of a battery used for a power storage unit changes with temperatures, and charging all regenerative electric power of the elevator may cause a sudden rise in the temperature of the battery especially at a low temperature, and a gas may be generated in the battery, leading to significant deterioration of the battery. The elevator control apparatus includes: a converter; an inverter; a controller for controlling a motor based on the AC power of a variable voltage and a variable frequency supplied from the inverter so as to operate an elevator; a power storage unit for storing the DC power; a thermistor for detecting a temperature of the power storage unit; a charge/discharge control circuit for controlling a charging and discharging electric energy based on the detected temperature and issuing a drive signal; and a charge/discharge circuit for charging and discharging the power storage unit based on the drive signal.

Abstract: This invention provides a controller of an elevator capable of performing smooth speed control by using a cheap power accumulating device of a low capacity even at a power failure time.

Abstract: This invention provides a controller of an elevator for stably controlling charging and discharging operations of a power accumulating device by using a cheap secondary battery of a low capacity, without damaging energy saving effects obtained by charging.

Abstract: This invention provides a controller of an elevator capable of performing stable speed control by using a cheap power accumulating device of a low capacity even at a discharging control time. Therefore, the controller has a converter 2, an inverter 4, a power accumulating device 11 arranged between DC buses 3, a charging-discharging control circuit 15 for controlling charging and discharging operations of the power accumulating device, a power failure detector 22, a current measuring instrument 23 and a voltage measuring instrument 24 for respectively detecting an output current and an output voltage of the inverter, a car load measuring instrument 25, an encoder 20, and a speed control circuit 21A for controlling an operation of the inverter. The speed control circuit 21A calculates output power of the inverter, and calculates discharging ability power of the power accumulating device on the basis of a measuring value of charging and discharging states.

Abstract: An elevator control device includes: a convertor which rectifies an a.c. power and converts the a.c. power into a d.c. power; an inverter which converts the d.c. power into an a.c. power having a variable voltage and a variable frequency; an electric motor which is driven by the a.c. power having a variable voltage and a variable frequency to drive an elevator; a power storing unit which is charged with an electric power; a required-power arithmetically operating circuit which calculates a required power of the elevator which is an electric power required for the operation of the elevator or an electric power caused by the operation of the elevator; and a charging/discharging control circuit which controls the charging operation or the discharging operation of the power storing unit based on the required power of the elevator.

Abstract: To reduce a total power amount required to drive an elevator by a commercial power supply during a peak power-consumption time period, for instance, afternoon in summer time, a control apparatus for this elevator is arranged by employing: a converter for rectifying AC electric power to be converted into DC electric power; and inverter for inverting the DC electric power into AC electric power having a variable voltage and a variable frequency; a motor driven by said AC electric power having the variable voltage and the variable frequency so as to operate an elevator; a power storage apparatus for charging thereinto electric power; and charge/discharge control means for controlling charging/discharging operation with respect to the power storage apparatus based upon a charging target value every time with respect to the power storage apparatus.

Abstract: To reduce a total power amount required to drive an elevator by a commercial power supply during a peak power-consumption time period, for instance, afternoon in summer time, a control apparatus for this elevator is arranged by employing: a converter for rectifying AC electric power to be converted into DC electric power; and inverter for inverting the DC electric power into AC electric power having a variable voltage and a variable frequency; a motor driven by said AC electric power having the variable voltage and the variable frequency so as to operate an elevator; a power storage apparatus for charging thereinto electric power; and a power controller for using both the power storage apparatus and the commercial power supply so as to supply the electric power to the inverter, and for controlling at least any one of the power storage apparatus and the commercial power supply in order to supply electric power which is required for the inverter.

Abstract: A DC-DC converter for outputting dc voltage whose peak value is higher than an input dc voltage value and high-frequency voltage corresponding to a command value is superimposed. An insulated switching power supply 27 and a series regulator 26 are connected in parallel to a dc power supply 1. The insulated switching power supply 27 generates output voltage V.sub.2 having a certain level, and the series regulator 26, output voltage V.sub.1 whose voltage varies depending on a command value (command voltage varying at a high frequency). Then, the sum of the output voltages V.sub.1 and V.sub.2 is fed to the load 9.