ES2786780T3 - Voltage transformer, actuator and gas burner - Google Patents

Abstract

Electric buck converter (200) with a circuit input (205) and a circuit output (210) having a common reference potential (215), where the buck converter (200) comprises the following: - a current valve (245) with an input (255) and with an output (260), - where the input (255) is connected to the circuit input (205); - a coil (265) that is connected between the outlet (260) of the current valve (245) and the outlet of the circuit (210); - a diode (270) that is used in the conduction direction, from the reference potential (215) towards the outlet (260) of the current valve (245); - an output capacitor (235) between the output of the circuit (210) and the reference potential (215); and - a control device (240) for the periodic opening and closing of the flow valve (245); characterized in that - between the anode of the diode (270) and the reference potential (215) a Zener diode (275) is inserted with conduction direction towards the reference potential (215); - Parallel to the diode (270) a resistor (285) is provided.

Description

DESCRIPTION

Voltage transformer, actuator and gas burner

The present invention relates to a technique for making a current available to control an actuator. In particular, the present invention relates to the control of an actuator, which is configured to actuate a gas valve.

A gas burner for heating water comprises a fan to generate a volume flow of air, and a gas valve. The gas valve comprises a voice coil and can be proportionally controlled between a closed state and an open state, to control a flow of gas that can be burned, by the valve. The gas flow through the gas valve is usually a function of a flow through the voice coil. A current controller for the moving coil may comprise a linear regulator which, although it can be adjusted over a wide range, nevertheless has a relatively low degree of effectiveness, and usually generates so much electrical waste heat that a body is needed for its dissipation of refrigeration. In a second embodiment a synchronized current regulator, in particular a synchronized buck converter regulator (buck adjuster, step-down converter, Buck converter) is used to control the current through the voice coil. The buck converter comprises a current valve that can be periodically opened and closed by an actuation device, where a utilization factor of an actuation signal controls the voltage applied to an output of the buck converter circuit and, due to This, indirectly, also controls the current flowing through the voice coil. Since the current valve cannot be opened and closed rapidly indefinitely, the buck converter can no longer be used in the case of low utilization factors, close to 0%. Therefore, a very low gas flow can no longer be precisely controlled.

The object of the present invention is to provide an improved technique for an electrical buck converter, which solves at least one of the problems mentioned. To this end, the objects of the independent claims are provided. Preferred embodiments are indicated in the dependent claims. Description of the invention

An electrical buck converter comprises a circuit input and a circuit output, having a common reference potential, furthermore a current valve with an input and an output, where the input is connected to the input of the circuit; a coil that is connected between the outlet of the current valve and the outlet of the circuit; a diode that is used in the direction of conduction from the reference potential towards the outlet of the current valve; an output capacitor between the output of the circuit and the reference potential; and a control device for periodic opening and closing of the stream valve. Between the anode of the diode and the reference potential a Zener diode is inserted with conduction direction towards the reference potential, and a resistor is provided parallel to the diode.

The buck converter can combine in itself the advantages of a linear converter and a known buck converter. In particular, the described buck converter can cover a large dynamic range, being able to precisely regulate at its output, in an ohmic resistance, currents of between a few milliamps and several hundred milliamps. At the same time, a degree of effectiveness of the buck converter can be high. In practice, a degree of effectiveness of much more than 50% can be achieved, partially up to about 95%. In a particularly preferred embodiment, an input capacitor is provided between the input of the circuit and the reference potential. As a result, the input voltage at the input of the circuit can be stabilized in an improved manner, so that both when the current valve is opened and also when the current valve is closed, the input voltage can remain essentially stable. Thanks to this the buck converter can work more precisely. Furthermore, a voltage source for supplying the circuit input can be loaded to a lesser extent. Other consumers that are also connected to the input of the circuit may be less affected.

A current-controlled actuator comprises a moving coil and the above-described buck converter, where the moving coil is electrically connected to the output of the circuit, so that a setting position, initiated by the actuator, depends on a current flow caused by the buck converter, through the moving coil. Thanks to this, the actuator can be controlled precisely and with little loss.

A step-down converter control device can activate the current valve by means of a pulse-modulated signal (Pulse Width Modulation: PWM) with a utilization factor D, so that the adjustment position of the voice coil can be controlled by utilization factor D. The generation of the PWM signal can take place by means of a PWM generator, so that the control device only has to predetermine the utilization factor D and thus only a little is loaded with the generation of the control signal. The current-controlled actuator can be used in particular to control a valve, for example a gas valve. In this way the actuator preferably acts on the gas valve so that a degree of opening of the gas valve depends on the current flow caused by the buck converter. The gas valve, by means of the actuator, can be controlled very precisely, from a minimally open position to a maximally open position.

Preferably, the buck converter control device controls the current valve by means of a pulse modulated signal, with a utilization factor, so that an adjustment position of the voice coil can be controlled by the utilization factor.

The utilization factor can be easily generated by an integrated microcomputer or other integrated control device. Due to this, the actuator activation can also be integrated in an improved way in a more complex apparatus, in which other processes are already controlled by the control device.

A gas burner comprises a gas valve that can be controlled, with a voice coil and the above-described actuator, to control the gas valve. By improved control of a gas flow through the gas valve, improved combustion can be controlled, so that an efficiency of the gas burner is increased. At the same time, a burden on the environment can be reduced by harmful substances.

Preferably, the gas burner further comprises a fan for generating a volume flow of air in the area of a gas outlet of the gas valve, where the fan can be controlled by the same control device. In particular, a rotational speed of the fan and a passage of gas through the gas valve can be synchronized with respect to each other in an improved manner by the control device. Synchronization can take place as a function of a parameter that is influenced by the combustion of gas with oxygen from the air, for example a flame temperature. Brief description of the figures

The invention is now described more precisely, referring to the attached figures, in which they represent:

Figure 1: a schematic representation of a ventilated gas burner; Y

Figure 2: a wiring diagram of an electrical buck converter.

Figure 1 shows a schematic representation of a gas burner 100. The gas burner 100 preferably comprises a fan 105 to provide a volume flow of air, and a control device 110 to control the fan 105. In In particular, the control device 110 is configured to control a rotational speed of the fan 105. The volume flow of air provided by the fan 105 passes through a gas outlet 115 of a gas valve 120, so that the gas that exiting from the gas outlet 115 can mix with the volume flow of air and can ignite forming a flame 125. The flame 125 can be used in particular to heat a liquid, in particular water, for example by means of a heat exchanger. The gas burner can be used in particular in a hot water installation, for example in a hot water tank. The hot water tank can be configured to provide hot water in a house or in a house.

The gas valve 120 is connected to an actuator 130 to open and close the gas valve 120. The actuator 130 comprises a voice coil 135, also called an oscillating coil, and a control device which, in the embodiment shown, is integrated with the control device 110. The voice coil 135 comprises a permanent magnet 140 with a recess and a support for the voice coil 145, which is prepared to be inserted into the recess. On the support of the moving coil 145 is placed an electric coil that, when it is crossed by current, generates a magnetic field that carries the support of the moving coil 145, in the magnetic field of the permanent magnet 140, into the recess or towards outside of it. This principle is known for example from the technical area of loudspeakers. An elastic element, for example a membrane, provides adequate restoring force on the voice coil holder 145, such that the voice coil holder 145 returns to a normal position when no current is already flowing through the coil. The voice coil holder 145 is preferably connected to the gas valve 120 such that the position of the voice coil holder 145 in the recess is proportional to a degree of opening of the gas valve 120.

To control the combustion of the flame 125, the control device 110 must usually be configured to activate both the fan 105, as well as the actuator 130, with the moving coil 135. A change of the position of the actuator 130 usually takes place. relatively slowly.

Figure 2 shows a connection diagram of an electrical buck converter 200. Buck converter 200 comprises an input of circuit 205 and an output of circuit 210, which are related to a common reference potential 215. Between the input of circuit 205 and the reference potential 215 is provided with a voltage source 220. Between the output of the circuit 210 and the reference potential 215 is provided a consumer 225, which in particular may comprise the actuator 130 and more preferably the voice coil 135. Preferably, an input capacitor 230 is connected in parallel with respect to the voltage source 220. It is also considered preferred that an output capacitor 235 is connected in parallel with respect to the consumer 225.

A control device 240 which may be made integrated with the device 110 of FIG. 1, activates a flow valve 245, for which a controller 250 may be provided intermediate connected. The current valve 245 usually comprises a semiconductor, in particular a transistor, for example of the FET or IGBT type. An inlet 255 of current valve 245 is connected to the inlet of circuit 205. An outlet 260 of current valve 245 is connected to a coil 265, the second end of which is connected to the outlet of circuit 210. At outlet 260 of the current valve 245 also conducts a diode 270, the anode of which, in a known circuit, is directly connected to the reference potential 215.

In the present embodiment, the anode of diode 270 is driven by a Zener diode 275 at reference potential 215, where the cathode of Zener diode 275 points toward reference potential 215. Preferably, parallel to the diode Zener 275 a capacitor 280 is connected. Parallel with respect to diode 270 a resistor 285 is provided.

Control device 240 is configured to periodically open and close current valve 245, for which a pulse width modulated (PWM) signal may be used, with a predetermined utilization factor. The utilization factor can usually be changed in a range between 0% and 100%. A period duration of the PWM signal is markedly shorter than the period of a utilization factor setting.

The voltage at the consumer 225 is determined in a typical buck converter 200, as a product of a degree of effectiveness, a voltage of the voltage source 220 and the utilization factor D. The consumer 225 has a predetermined resistive (ohmic) resistance , so that a current flows through the consumer 225 which is determined as a quotient of the voltage at the output of the circuit 210 of the buck converter 200 and the resistance 285. It must be taken into account that the degree of effectiveness, in the case of a constant resistance of consumer 225, is a function of the voltage at the input of circuit 205 and the utilization factor D.

In the circuit depicted above, the output voltage is reduced by a value K, which is determined by the Zener voltage of the Zener diode 275.

The capacitor 280, via the Zener diode 275, is used for attenuation, to improve a stable behavior of the regulation and, with it, the voltage at the consumer 225. The resistor 285 biases the diode 270.

The buck converter 200 shown, by properly selecting a utilization factor D of the PWM signal from the control device 240, can ensure very precise, and repeatable, control of the voltage at the consumer 225 as well as the current flowing through it. In this way, advantageously, the control device 240 can also be used to control another parameter, as in the example of figure 1, of the fan 105.

Claims (6)

1. Electrical buck converter (200) with a circuit input (205) and a circuit output (210) having a common reference potential (215), where the buck converter (200) comprises the following: - a flow valve (245) with an inlet (255) and with an outlet (260), - where the input (255) is connected to the input of the circuit (205); - a coil (265) that is connected between the outlet (260) of the current valve (245) and the outlet of the circuit (210); - a diode (270) that is used in the conduction direction, from the reference potential (215) towards the outlet (260) of the current valve (245); - an output capacitor (235) between the output of the circuit (210) and the reference potential (215); Y - a control device (240) for the periodic opening and closing of the flow valve (245); characterized because - between the anode of the diode (270) and the reference potential (215) a Zener diode (275) is inserted with conduction direction towards the reference potential (215); - parallel to the diode (270) a resistor (285) is provided. Buck converter (200) according to claim 1, wherein between the input of the circuit (205) and the reference potential (215) an input capacitor (230) is provided. Current-controlled actuator (130), comprising a voice coil (135) and a step-down converter (200) according to one of the preceding claims, wherein the voice coil (135) is electrically connected to the output of the circuit ( 210), so that an adjustment position, initiated by the actuator (130), depends on a current flow caused by the buck converter (200), through the moving coil (135). Actuator (130) according to claim 3, wherein the control device (240) of the buck converter (200) activates the current valve (245) by means of a pulse modulated signal, with a utilization factor (D), so that the adjusting position of the voice coil (135) can be controlled by the utilization factor (D). 5. Gas burner (100) comprising a controllable gas valve (120), as well as an actuator (130) according to claim 3 or 4, to control the gas valve (120), where the actuator (130) acts on the gas valve (120), so that a degree of opening of the gas valve (120) depends on the current flow caused by the buck converter (200). 6. The gas burner (100) according to claim 5, further comprising a fan (105) for producing a volume flow of air in the area of a gas outlet (115) of the gas valve (120), where the fan (105) can be controlled by the same control device (110, 240).