KR20100017597A - Rectifier for feeding a coil - Google Patents

Abstract

Disclosed is a circuit for operating a coil of an electrically liftable safety brake, to be connected to AC inputs having different (preferably single-phase) operating voltages. Said circuit comprises: a rectifier circuit which is connected to the input terminals and is used for generating a periodically changing direct voltage; output terminals for supplying the direct voltage generated by the rectifier to a coil; one or more electronic valves/switches for switching the direct current on or off anytime; preferably a freewheeling diode that is connected to the output terminals in order to keep the current flowing through the coil during the off-state interval of the electronic valve/switch; a control loop which is connected to the output terminals and measures the direct voltage applied to the coil or calculates or derives said direct voltage from other measured voltages (e.g. input voltage, voltage of the intermediate circuit, valve/switch voltage, etc.) and triggers the electronic valve/switch in such a way that the direct voltage applied to the coil remains constant; and a mechanical/electronic switch in the power supply to the coil in order to interrupt and quickly switch off the free-wheeling circuit.

Description

Rectifier for powering coils {RECTIFIER FOR FEEDING A COIL}

The present invention relates to a rectifier circuit for supplying current from an AC grid to a coil, for example to an electromagnet of an electrically liftable brake.

Electrically lifted brakes, such as elevator safety brakes, generally consist of a brake that is engaged with a spring and squeezed. In this context, "liftable" means that the brake is crushed or released under the action of an electric current. In short, an electromagnet is provided to raise the brake. The electromagnet acts on the armature against the elastic force. However, as soon as the electromagnet is switched to the non-current state, the spring engages the brake again and locks it in place. Therefore, for much of the operating time of the mechanical system in which the brake is operated, the coil of the electromagnet must be excited, which requires a constant current supply. This is typically done by connection to local lines. Available local system voltages near the mechanical system typically have many different standard values. The standard value may be, for example, a 400V three-phase current to heavy-current system, a European 230 / 250V home system, or a 110V home system that is used and relatively low in the United States. For each of the available voltages and brake outputs, the manufacturer of the electromagnet-raised brakes must supply suitable coils, which requires large storage of products to be manufactured, supplied and maintained.

These various grid voltage problems are addressed in DE 197 40 016 (corresponding to US 6 291 952). This German publication discloses a configuration in which the average current flow through the coil is limited by the electronic switch. Since the magnetic effect of the coil is proportional to the current flowing through the windings, the control of the average current controls the magnetic field strength to the setpoint required to raise the brake, which is independent of the voltage applied to the circuit as a limit. This configuration has the disadvantage that a unique limiting current must be set for all brake sizes. The circuit does not provide protection against thermal overload that may occur when the effective resistance of the coil rises. Typically the coils are excited for a relatively long period of time and thus heat up. With heating, the resistance of the coil rises. If the coil current then remains constant and the coil heats up accordingly, then the power delivered by the coil itself also rises, which further raises the temperature of the coil. In order to keep the current constant, a relatively higher voltage is required. Rising output and voltage can quickly cause coil failure.

SUMMARY OF THE INVENTION An object of the present invention is to provide a rectifier circuit which can also be used with various system voltages in a rectifier circuit for supplying power to an electromagnetic rising brake. Preferably the same electromagnet coil can be used for all voltages and the same rectifier circuit can be used for electromagnets of all specifications.

Summary of the Invention

According to a first aspect of the invention, the invention is a circuit for supplying an operating current to a coil,

Input terminals for connection to an alternating current system;

A rectifier circuit for generating a direct current voltage based on the alternating current supplied connected to the input terminals; And

Output terminals in which a direct current voltage generated in the rectifier circuit can be drawn so as to be connected to a coil;

There is provided a voltage supply control circuit connected to the output terminals to control the voltage flowing through the output terminals, the voltage supply control circuit comprising a control output line and an internal circuit, the internal circuit being connected to the output terminals. A request signal can be applied to the output line if more current is needed by the rectifier to maintain a controlled voltage;

The rectifier element comprises a voltage limiting circuit, which is connected to the control output line of the voltage supply control circuit and allows the current to the output terminals when a request signal is received. do.

According to a second aspect of the invention, the invention provides a circuit for operating a coil so that it can be connected to an alternating current supply device having a variety of operating voltages, the circuit being connected to the input terminals to generate a periodically varying DC voltage. Rectifier circuit; Output terminals for supplying an alternating voltage generated by the rectifier to the coil; Solenoid valves / switches capable of supplying or interrupting direct current at any time; A freewheeling diode connected to the output terminals to maintain current flow through the coil during the shutoff time of the solenoid valve or switch; Connected to the output terminals to measure the DC voltage flowing through the coil, or to calculate or derive a corresponding voltage from another measured voltage (e.g., input voltage, intermediate circuit voltage, valve-switch voltage, etc.) A control circuit for controlling the solenoid valve or the switch so as to keep the flowing DC voltage constant; And a mechanical / electronic switch provided at a current supply of the coil so that the freewheeling circuit can be interrupted for a rapid shutoff.

The arrangement according to the invention controls the voltage flowing in the coil. In other words, the temperature of the coil rises, and the output delivered from the coil drops as a function of resistance (P = U ² / R). By doing so, the heating effect of the coil is reduced. In addition, because the voltage is stabilized in the coil, the circuit of the present application can be used over a wide range of various system voltages to supply voltages and coil currents. The configuration of the present invention also has the advantage of only manufacturing an extension kit consisting of a rectifier and a coil voltage supply for each set current, and no separate unit for each current / voltage combination. By doing so, the number of component parts to be manufactured and stored can be significantly reduced. Although it is necessary to connect various set coil currents, only one rectifier circuit is sufficient for a fairly wide current range. A further aspect of the invention is in particular a brake assembly consisting of a rectifier and a brake coil, as well as a conversion or expansion kit, as well as a corresponding brake component such as a rectifier, a coil and a spring for engaging the brake with the brake plate. . The configuration for the brake itself is known and can be found in a number of publications filed in the name of the applicant.

Some embodiments of the invention are described below in connection with the accompanying drawings.

1 is a circuit diagram of a rectifier connected to a brake coil.

Figure 2 is a circuit diagram of a second embodiment of a rectifier circuit similarly connected to a coil.

3 is a circuit diagram for a third embodiment.

1 shows a half-controlled bridge. The measuring and control member controls the electronic switches T1 and T2 in such a way that a set direct current voltage is applied to the coil. The switch S1 is used to cut off the DC current side according to the selection. Voltage control can be performed through phase angle control, reverse phase control or pulse width modulation (PWM). The switch S1 is used to cut off the DC current side according to the selection.

In other words, in the configuration according to FIG. 1, SCR T1 and SCR T2 replace the rectifier at the anode half of the rectifier bridge. If current is needed to maintain the coil voltage set point, the SCRs excite their gate electrodes, thereby energizing the bridge rectifier.

2 shows a bridge rectifier circuit. The measuring and control member acts on the electronic switch T1 on the alternating voltage side, whereby a set direct current voltage is applied to the coil. Voltage control can be performed through phase angle control, reverse phase control or pulse width modulation. The switch S1 is used to cut off the DC current side according to the selection.

In the configuration according to FIG. 2, the TRIAC or other electrical AC opening and closing member is in series with the phase of one of the phases of the WS grid so as to be controlled by the measurement and control member and supply current to the bridge rectifier as required. Connected.

3 shows a bridge rectifier. The measurement and control member controls the DC voltage side electronic switch T1 so that the set DC voltage flows through the coil. Voltage control can be carried out through phase angle control, reverse phase control or pulse width control. The switch S1 is used to cut off the DC current side according to the selection.

Thus, in this configuration, the AC input stage is connected directly to the bridge rectifier. An electronic switch, such as an IGBT, controls on the direct current side the voltage applied to the coil corresponding to the signals sent out from the measuring and control member.

In all the circuits described above, diodes are placed in parallel to the coil. The diode ensures additional current flow after the interruption of the current supply. In series with such a freewheeling diode, an optional switch can be placed that opens to ensure maximum current drop in coil current. Finally, a protection circuit is built in to prevent excessive rise of the voltage in the region in the coil and not allow the allowable voltage to be exceeded.

In the block diagram, a "measurement and control member" is a voltage divider for detecting an output voltage or other voltages that can calculate or derive an output voltage (eg, input voltage, intermediate circuit voltage, valve-switch voltage, etc.). In addition to the RC member included, it may be an evaluation circuit that controls the electronic switch in accordance with the level of the output voltage. This absence is realized for example with operational amplifiers or microprocessors.

The coil Y1 is preferably no different from the coil itself, which causes the coil current to drop when the coil voltage is kept constant by changing its effective resistance based on temperature changes.

For all the embodiments described above, one can also consider up or down control depending on the selection of the control voltage to achieve excess excitation and / or reduced holding voltage. Typically the coils are overexcited upon initial excitation to form a magnetic field as quickly as possible, and are maintained in such a way that they are excited with a reduced voltage after being fully excited. The circuit arrangement is suitable for all grid frequencies, in particular for all frequencies including 50 Hz to 60 Hz (eg US). In short, we found that we could control grid voltages beyond the 3: 1 magnitude range.

Claims (11)

A circuit for operating a coil so that it can be connected to an alternating current supply having various operating voltages (preferably single-phase voltages). A rectifier circuit connected to the input terminals to generate a periodically varying DC voltage; An output terminal for supplying a DC voltage generated in the rectifier to the coil; One or more solenoid valves / switches provided for supplying or interrupting direct current at any time; A freewheeling diode coupled to the output terminals to maintain current flow through the coil during the shutoff time of the solenoid valve / switch; Connected to the output terminals to measure a direct current voltage flowing in the coil, or calculate or derive a corresponding voltage from other measured voltages (e.g., input voltage, intermediate circuit voltage, valve-switch voltage, etc.) A control circuit for controlling the solenoid valve / switch to maintain a constant direct current voltage; And A circuit for operating the coil to be connected to an alternating current supply having various operating voltages, comprising a mechanical / electronic switch provided at the current supply to the coil for the purpose of intermittent and rapid shutdown of the freewheeling circuit. . 2. The rectifier according to claim 1, wherein said rectifier is formed as a semi-control bridge circuit, and control elements (preferably thyristor, transistor, MOSFET or IGBT) hold various operating voltages, characterized in that they are controlled by said control circuit. Circuit for operating the coil to be connected to an alternating current supply. The rectifier of claim 1, wherein the rectifier is formed as a bridge or a one-way rectifier, and the current circuit of the output terminals of the coil includes one or more solenoid valves / switches (preferably thyristors, transistors) controlled by the control circuit. Circuit for operating the coil so that it can be connected to an alternating current supply having a variety of operating voltages. The rectifier according to claim 1, wherein the rectifier is formed as a bridge or one-way rectifier, and in the current circuit of the input terminals one or more solenoid valves / electronic switches (preferably TRIAC) controlled by a control circuit are located. A circuit for operating a coil to be connected to an alternating current supply having various operating voltages. 5. The control circuit of claim 1, wherein the control circuitry can be switched to produce a relatively higher voltage to exceed the electromagnet and generate a relatively lower voltage to hold the electromagnet. Circuitry for operating a coil to be connected to an alternating current supply having a variety of operating voltages. 6. The AC valve according to any one of claims 1 to 5, wherein the solenoid valve / switch is controlled by a control circuit in a phase angle control or a reverse phase control manner. Circuit for operating the coil. The AC valve according to any one of claims 1 to 6, wherein the solenoid valve / switch can be connected to an AC supply device having various operating voltages, which are opened and closed by a control circuit in a pulse width modulation scheme (PWM). Circuit for operating the coil. 8. The alternating current supply device according to claim 1, wherein a switch (preferably a mechanical or electronic valve / electronic switch) is located in the freewheeling circuit of the coil. 9. Circuit for operating the coil so that it can be connected to the circuit. 9. The device of claim 8, having an electronic element (preferably a varistor, zener diode, or suppression diode) for limiting the voltage at the output terminals to limit the blocking voltage at the coil. Circuit for operating the coil to be connected to an alternating current supply. Electromagnetism brakes or other electromagnet components in accordance with VDE580, A spring for crimping the brake lining in a braking state; An electromagnet connected to react with the spring force of the spring, thereby squeezing the brake; And A circuit according to any one of claims 1 to 9; The circuit comprises an electro-raising brake or other VDE580 according to claim 1, wherein the output terminals are connected to the coil of the electromagnet. As a method for controlling the connection voltage of an electromagnet, Coupling a rectifier circuit to an AC supply (preferably single phase) to produce a periodically varying DC voltage; Supplying a direct current voltage generated from the rectifier to the coil under conditions of controlling one or more solenoid valves / switches to continuously supply or interrupt direct current; Coupling a freewheeling diode to the output terminals to maintain current flow through the coil during the shutoff time of the solenoid valve / switch; Measuring the direct current flowing through the coil, or calculating or deriving the coil voltage from other measured voltages (e.g., input voltage, intermediate circuit voltage, valve-switch voltage, etc.), and Controlling the solenoid valve / switch in a constant manner; And Preferably interrupting the current supply of the coil in a freewheeling circuit for the purpose of fast disconnection.

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