DE102006016748A1 - Rectifier for feeding a brake coil - Google Patents

Abstract

Circuit for operating a coil of an electrically releasable safety brake for connection to AC power supplies with different operating voltages (preferably single-phase) with: a rectifier circuit connected to the input connections for generating a periodically changing DC voltage; Output terminals for supplying a coil with the DC voltage generated by the rectifier; an electronic valve / switch to turn the DC power on or off at any time; preferably a freewheeling diode which is connected to the output connections in order to maintain the current flow through the coil during the blocking times of the electronic valve / switch; a control circuit connected to the output connections, which measures the DC voltage applied to the coil and controls the electronic valve / switch in such a way that the DC voltage applied to the coil remains constant; and a mechanical / electronic switch in the power supply to the coil for the purpose of interruption and rapid disconnection of the freewheeling circuit (Fig. 1).

Description

Territory of invention

The The present invention relates to a rectifier circuit for feeding a coil - eg. the electromagnet of an electrically releasable brake - with power from an AC mains.

Technical background

electrical ventable Brakes such as the safety brakes of elevators generally exist from a brake that is pressed into engagement with springs. In this context, "ventilatable" means the brake by the action the current solved or is released: An electromagnet is provided to the Release brake. He counteracts the spring force on an anchor; as soon as he does de-energized, the springs engage the brake back. For one a significant proportion of the operating time of the machinery at the the brake is working, therefore, must be energized the coil of the electromagnet be what a constant power supply requires. Typically, this is done by connecting to the local Power grid. The voltage of the local available near the machinery Power grid typically has one of a number of different ones Defaults. It may, for example, to the 400V rotary or high-voltage or around the 230 / 250V home networks in Europe or around the lower 110V house networks acting in the US. For every available voltage and braking power the manufacturer of the electromagnetically releasable brake must use a suitable Supply coil, which requires an extensive stock of products, which must be manufactured, kept and maintained.

This problem of different mains voltages is in the document DE 197 40 016 (corresponding US 6,291,952 ), which describes an arrangement in which the average current flow through the coil is limited with an electronic switch. Since the magnetic effect of the coil is proportional to the current flowing through the windings, regulating the average current also regulates the magnetic field strength to the desired set point for releasing the brake, regardless of the voltage applied to the circuit as a whole , A disadvantage of this arrangement is that for each brake size, a separate limiting current must be set. The circuit provides no protection against thermal overload, which can occur when the effective resistance of the coil increases. Typically, the coil is energized for extended periods of time; she warms up therefore. With the warming their resistance increases. If the coil current is kept constant and the coil heats up, the power converted into it also increases, which raises its temperature further. To keep the current constant an even higher voltage is required. The increasing power and voltage can quickly lead to a failure of the coil.

aim The present invention is a rectifier circuit for dining Electromagnetically ventilated Brakes, which can be used with different mains voltages. Preferably is for all Voltages the same electromagnetic coil and for all sizes of Electromagnet the same rectifier circuit used.

Summary of the invention

According to a first aspect of the present invention, this provides a circuit for feeding a coil with operating current, comprising:
Input terminals for connection to an AC mains;
a rectifier circuit connected to the input terminals for generating a DC voltage based on the supplied AC current; and
Output terminals at which a DC voltage for connection to the coil is detachable at the rectifier circuit;
characterized by a power supply control circuit connected to the output terminals for measuring and regulating the voltage applied to the output terminals, the power supply control circuit having a control output line and an internal circuit for applying a request signal to the output line; if more power is needed from the rectifier to maintain the regulated voltage at the output terminals;
wherein the rectifier element has a voltage limiting circuit connected to the control output line of the power supply control circuit and allowing a current to the output terminals when the request signal has been received.

According to a second aspect of the invention, this provides a circuit for operating a coil for connection to AC power supplies of different operating voltages, comprising a rectifier circuit connected to the input terminals for generating a periodically varying DC voltage; Output terminals for supplying a coil with the DC voltage generated by the rectifier; an electronic valve / switch with which a direct current can be switched on or off at any time; a freewheeling diode connected to the output terminals, with which the current flow through the coil can be maintained during the blocking periods of the electronic valve or switch; one attached to the output terminals closed loop, which measures the voltage applied to the coil DC voltage and controls the electronic valve or the switch to keep the DC voltage applied to the coil constant; and a mechanical / electronic switch in the power supply of the coil, with which the freewheeling circuit is interrupted for an emergency shutdown.

The arrangement according to the invention regulates the voltage applied to the coil. If the temperature of the coil increases, the power converted in the coil decreases as a function of the resistance (P = U ² / R). This reduces the heating effect of the coil. Further, since the voltage on the coil is stabilized, the circuit can be used over a wide range of different supply voltages and for a wide range of coil currents. The arrangement also has the advantage that for each desired current only one of a rectifier and a coil voltage existing retrofit kit, but not a separate unit for each current / voltage combination is to produce. This achieves a drastically reduced number of manufactured and vorzuhaltender components. Even if one sets different target coil currents, but there is a fairly wide current range for a single rectifier circuit is sufficient. Other aspects of the invention include a conversion or retrofit kit from the rectifier and a brake coil and a full brake from the rectifier, the coil and the associated brake components such as the brake plates and the springs for engaging the brake. The design of such brakes themselves is known and can be found in several patent pending in the name of the applicant.

description

It Now some embodiments of the present invention with reference to the accompanying drawings described.

1 is a circuit of the rectifier connected to a brake coil;

2 is a circuit of a second embodiment of the rectifier circuit also in connection with a coil; and

3 is a circuit of a third embodiment.

1 shows a half-controlled bridge. The measuring and control element controls the electronic switches T1 and T2 so that the nominal DC voltage is applied to the coil. The switch S1 is used for optional DC side shutdown. The voltage regulation can be done by phase control, phase sequence control or pulse width modulation (PWM). The switch S1 is used for optional DC side shutdown.

In the arrangement according to 1 Thus, the SCRs T1 and T2 replace the rectifiers in the positive half of the rectifier bridge. When power is required to maintain the coil voltage setpoint, the SCRs at their gate electrodes are energized, causing the bridge rectifiers to switch through.

The 2 shows a bridge rectifier circuit. The measuring and control element acts on the alternating voltage side on the electronic switch T1, so that the setpoint DC voltage is applied to the coil. The voltage regulation can be done by phase control, phase control or pulse width modulation. The switch S1 is used for optional DC side shutdown.

In the arrangement of 2 For example, a triac or other AC electrical switching element is connected in series with one of the phases of the AC line to supply current to the bridge rectifier as needed and driven by the measuring and regulating element.

3 shows a bridge rectification. The measuring and control element controls the DC-side electronic switch T1 so that the target DC voltage is applied to the coil. The voltage regulation can be done by phase control, phase control or pulse width modulation. The switch S1 is used for optional DC side shutdown.

In This arrangement is therefore the AC input directly to a bridge rectifier placed. The electronic switch, e.g. IGBT regulates the coil voltage applied on the DC side according to the signals the measuring and control element.

In All the circuits described above can be parallel to the coil put a diode that after an interruption of the power supply the ensures further flow of electricity. In series with this freewheeling diode can optionally be a switch, which open leaves, to ensure a maximum current drop of the coil current. After all let yourself install a protection circuit, which causes an excessive increase in the return voltage prevented on the coil, which could damage the electronics.

The "measuring and control element" in the block diagram may be an RC element with voltage divider for detecting the output voltage and an evaluation circuit, which corresponds to the height of the off voltage drives the electronic switch. It can be implemented, for example, with an operational amplifier or a microprocessor.

The Coil Y1 is preferably nothing but the coil itself, due to the temperature change their Resistance changes, so that the coil current decreases when the coil voltage is kept constant.

For all above described embodiments is an optional up or down control of the control voltage thought to be over-excitement and / or to achieve a reduced holding voltage. typically, the coil will be at the initial Excitement over-excited, to build up the magnetic field as quickly as possible, and after complete excitement kept energized with reduced voltage. The circuit arrangements are for any mains frequencies suitable, including in particular 50 Hz or 60 Hz (e.g., USA). It has been proven that mains voltages over a Range of magnitude of 3: 1 are operable.

Claims (11)

Circuit for the operation of a coil for connection to AC power supplies with different operating voltages (preferably single-phase) With: a rectifier circuit connected to the input terminals for generating a periodically changing DC voltage; Output connections to Supplying a coil with the DC voltage generated by the rectifier; one electronic valve / switch to turn DC power on and off at any time; preferably a freewheeling diode, which is connected to the output terminals, during the Blocking times of the electronic valve / switch the current flow to maintain through the coil; a control circuit connected to the output terminals, which measures the voltage applied to the coil DC voltage and the electronic Valve / electronic switch controls that on the coil lying DC voltage remains constant; and a mechanical / electronic Switch in the power supply to the coil for interruption and quick shutdown of the freewheeling circuit. The circuit of claim 1, wherein the rectifier is designed as a half-controlled bridge circuit and the controls (preferably thyristors, transistors, MOSFETs or IGBTs) are driven by the control loop. The circuit of claim 1, wherein the rectifier as bridge or half-wave rectifier is and electronic in the circuit of the output terminals of the coil Valve / electronic switch (preferably thyristor, transistor, MOSFET or IGBT), which is driven by the control loop. The circuit of claim 1, wherein the rectifier as bridge or half-wave rectifier is and in the circuit of the input terminals an electronic valve / a electronic switch (preferably a triac) located by the control circuit is controlled. Circuit according to one of the preceding claims, wherein the control loop is switchable to a higher voltage to over-excite and to generate a lower voltage for holding the electromagnet. Circuit according to one of the preceding claims, wherein the electronic valve / electronic switch as of Control circuit is driven in phase or section control. Circuit according to one of the preceding claims, wherein the electronic valve / electronic switch from the control loop is switched in pulse width modulation (PWM). Circuit according to one of the preceding claims, wherein in the freewheeling circuit of the coil, a switch (preferably mechanically or as an electronic valve / electronic switch) Circuit according to claim 8 with a voltage-limiting electronic component (preferably a varistor, a Zener diode or a suppressor diode) at the output terminals for limiting the turn-off voltage at the coil. Electronically ventilated Brake or other electromagnetic components according to VDE580, with: Feathers, the brake pads press in a braking state; one Electromagnet, which is connected to the forces of Counteract springs and so release the brake; and a circuit according to one of the preceding claims, the output terminals are connected to the coil of the electromagnet. A method of controlling the terminal voltage of an electromagnet, comprising the steps of: connecting a rectifier circuit to a (preferably single-phase) AC power supply to produce a periodically varying DC voltage; Energizing a coil with the DC voltage generated by the rectifier under the control of an electronic valve / switch to equalize constantly switching power on and off; preferably, connecting a freewheeling diode to the output terminals to maintain current flow through the coil during the off-time of the electronic valve / switch; Measuring the DC voltage applied to the coil and driving the electronic valve / switch such that the DC voltage applied to the coil remains constant; and preferably interrupting the power supply of the coil in the freewheeling circuit for rapid shutdown.