EP1732695A1 - Method for controlling a device for electrostatic particle deposition in gas flows, and control unit therefor - Google Patents

Abstract

The invention is based on the measured capacitance between a measuring electrode which is formed either by the corona electrode itself or a separate flue gas pipe section (7) which is arranged inside the flue gas channel (1) and through which section the flue gas flows, and the flue gas channel (1) itself. The capacitance is measured and used as a reference variable for control of the device. It consists of an electric conductive flue gas pipe section (7) which is electrically insulated inside the electrically conductive flue gas channel (1) and through which the flue gas is intended to flow. A measuring device (10) is also provided in order to measure capacitance between the flue gas pipe section (7) and the flue gas channel (1). An electronic control unit (9) is also provided in order to switch the device which uses the measured capacitance as a reference variable.

Description

 Method for controlling a device for electrostatic particle separation in gas streams, and control unit for this purpose

The present invention relates to a method of how a particular device for electrostatic particle separation in gas streams can be controlled, as well as the relevant control unit. The method and associated control unit for its use is suitable for controlling a device which serves to clean or filter the flue gas of small furnaces. These small furnaces with capacities up to about 70kW are different heat generators for the space heating needs as well as for cooking. These include, in particular, fireplaces, tiled stoves, stoves, cookers and boilers fueled with wood.

For small combustion, the responsibility for the fuel quality and the firing is primarily the operator. The optimization possibilities of the plant-side combustion technology are set relatively narrow limits. For this reason, these small fires emit a disproportionate amount of pollutants into the atmosphere in terms of total smoke emission. It happens that these dust particles from small firing before especially in urban districts and agglomerations, where such small fires are present in large numbers, that is, this large proportion of total particle emissions concentrated on heavily populated areas. In addition to this local concentration, the emissions of wood combustion also occur primarily in winter, so that this air pollution is still concentrated on a limited period.

Aerodynamically relevant to human health are particles with an aerodynamic diameter of significantly less than 10 microns, because particles can accumulate from such a small amount in the lungs. These particles also bind dioxins, which are taken up by humans after the particle deposition on soils and plants via the food chain. Since it has been shown by measurements that the emitted particles of wood firing in the critical range of less than 10 microns in diameter, it is therefore necessary to install even in the field of simple wood combustion systems suitable flue gas devices to retain these micro particles.

In EP 1 193 445 A2 of the EMPA a device for flue gas cleaning is presented to small furnaces, which can be installed in the existing flue of such a furnace: either this flue gas duct is electrically conductive by the stovepipe is approximately made of sheet steel, chrome steel or aluminum or the fireplace is built entirely of stone and masonry or plastic. In the first case, the device forms a lid which can be placed gas-tight on an associated opening on the flue gas channel. On the inside of this cover a spray electrode is held on insulators. Furthermore, the device includes a high-voltage generator for establishing a DC voltage between this spray electrode and the inner wall of the electrically conductive flue gas channel section. In the second case, a portion of an electrically conductive tube is mounted to the lid to form a collector surface. The typical connection value of the high voltage generator is between 10 and 50VA and it can be operated with 220V / 50Hz or 110V / 60Hz alternating current. The charge of Spray electrode can be negative or positive to earth. The cleaning of the collector part can easily be done by hand after removal of the electrode wire with the bracket.

In one embodiment of this device, this has a self-supporting rod electrode in the form of a metal strip, which is strong enough that he can carry himself. Instead of such a metal strip but also a wire of sufficient strength can be used. The decisive feature of the spray electrode is the presence of the smallest possible radii, where high local field strengths occur. It has now been shown that the best results are achieved with a wire as thin as possible, which extends with its free end in the middle along a flue gas tube. However, thin rod-like wires begin to vibrate as a result of the resulting charge conditions, because the high electrical charge of the wire generates image charges of opposite polarity on the proximal inner surface of the exhaust pipe. The tube wall opposite a negatively charged wire is therefore positively charged. The free-hanging tip of the electrode wire is therefore attracted to the pipe wall and due to its mechanical elastic bending it swings back after reaching the maximum deflection and is then deflected in the opposite direction and vice versa. However, this vibration can be damped by the electrode is tapered towards each free-hanging end and also the electrode is actively electrically stabilized or passively stabilized. It is thus realized an electrostatic precipitator, which has no separate separating plates, which does not require a flue gas fan, does not entail a substantial flue gas channel constriction, and whose separation zone can be dimensioned as needed.

Now, it is so that the equipped with such an electrostatic precipitator wood fires are usually only very occasionally behave in operation. For heating purposes, they run only in the winter months and they are operated on an hourly or daily basis as required, and rarely for several weeks and months. On the other hand, wood in many cheminees is almost more burnt for decorative purposes for targeted heating. One wants to create with such chemines primarily residential atmosphere, although the heating effect is used simultaneously.

So because these wood fires are operated at very irregular intervals and over irregular periods of time, it is unreasonable to leave the built-filter device for electrostatic particle separation permanently turned on and to keep under grid voltage. But if a special switch is installed, just to turn it on as needed, it can be assumed that it is probably forgotten by most operators often turn. While the switch-on is even more likely, it is even more true that the switch-off is forgotten, because you let burn out the wood and cool the stove, unless you put wood after. From GB 769 457 a control of the operating voltage of electrostatic precipitators during their operation is disclosed, but which does not serve the switching on and off of the separator and is not suitable for it. It has not the detection of the presence of flue gas for the purpose of switching on and off of the filter device to the target, but rather the mere control of the operating voltage. For this purpose, the frequency of flashovers between the electrodes is used as the guide size. However, no capacity measurements are made and no other properties of the dielectric are determined which could serve to turn the separator on or off.

The object of the present invention is therefore to automatically design the switching on and off of a device for the electrostatic particle separation in the flue gas stream of wood firing and thus to provide a method for this and the associated control unit for operating the method. Once the wood firing is put into operation, the particle separation is to be reliably activated, and as soon as the flue gas stream subsides, it should be switched off with the same reliability. This object is achieved by a method for controlling a device for the electrostatic particle separation in gas streams, which is characterized in that the changes in the dielectric properties are detected within the flue gas duct as a result of combustion, by the electric capacity between the flue gas duct and a measured in the flue gas flow spray or measuring electrode.

The object is further achieved by a control unit for a device for electrostatic particle separation in gas streams, consisting of a spray or measuring electrode and an electrically conductive flue gas channel section as a collector surface, further comprising a measuring device for measuring the capacitance between the flue gas duct and the spray or measuring electrode and an electronic control unit for the circuit of the device using the measured capacitance as a guide size.

In the drawings, the operation of the method is illustrated and it will be described and explained below. Also described is a schematically illustrated control unit for the apparatus for electrostatic particle separation in gas streams and especially for the flue gas cleaning of small furnaces.

It shows:

Figure 1: An embodiment of a device for electrostatic particle separation in gas streams;

FIG. 2 shows a measuring arrangement for connecting upstream of a device for particle separation, for measuring the capacitance between, on the one hand, a flue-gas pipe section, which is arranged inside a flue-gas channel, and, on the other hand, the flue-gas channel, with associated exemplary measuring diagram; Figure 3: A control unit for the circuit of the apparatus for electrostatic particle separation, ^" downstream of the measuring device.

In principle, electrostatic precipitators function according to the principle that electrically charged, solid or liquid particles are deflected in an electric field. The soot particles must therefore first be charged electrically. The unipolar charged particles subsequently deposit on separation plates as a result of the action of the electrostatic field. With such electrostatic precipitators, dust and aerosols with particle sizes of 0.01 to 60 μm can be deposited. The efficiency of the deposition also depends on the flow velocity of the particles and the dust concentration in the gas flow, as well as on the temperature and humidity in the inflowing gas.

In Figure 1, a possible device for electrostatic particle separation in gas streams is shown, which is also suitable for flue gas cleaning of small furnaces. It is designed for installation in a straight section of an existing, electrically conductive stovepipe 1. The device comprises an electrode holder 6 made of metal, preferably made of stainless steel, which is provided for receiving the electrode 4 with a bore. The socket 6 has an electrode thickness of 0.3 mm in the socket area a diameter of several millimeters and is held by a clamp or bayonet connection in a metallic holder 7, as shown in enlarged section. The holder 7 is attached to a support rod 2, which is also preferably made of stainless steel. The holding bar 2 is guided by an insulator 3 in the flue gas pipe 1. The insulator 3 is advantageously made of a plastic, for which polyetheretherketone (PEEK) is suitable, because this material allows a certain charge migration, so that no charge nests can form, but discharges continuously. In contrast, in a porcelain or ceramic insulator under DC voltage charge nests, which then migrate to the outside and lead to spontaneous breakthroughs (TE). The insulator 3 is firmly connected to the lid 5. The version 6 can be cylindrical or as shown here spherically shaped, with a diameter of about 10mm and a central bore in which the electrode 4 is seated and held. The opening on the furnace tube 1 is designed so large that the holder 7 is inserted under elastic bending of the wire 4 in the furnace tube 1, and thereafter, the opening 1 is closed gas-tight with the lid 5, including offering about suitable clamps, clamping lever or clamping screws , A high voltage generator with rectifier function is both electrically and thermally isolated from the furnace tube 1 and is powered by a power cable. The high voltage output is passed through the insulator 3 via the socket 6 to the spray electrode 4, which advantageously consists of a tungsten wire. The other pole is at ground potential and is electrically connected to the furnace tube 1, which acts opposite the electrode 4 as Abscheidefläche. Thus, an electrostatic filter is formed, wherein the wire 4 forms the spray electrode, and the inside of the furnace tube 1 over the length of the electrode wire 4 also forms the collecting electrode or collector surface, so that the entire chimney, so far as it consists of conductive material, can act as a collector surface ,

For regular cleaning of the collecting electrode, that is, the inner wall of the furnace tube 1, the high voltage is first turned off. Then, the holder 7 is removed with the electrode 4 from the furnace tube 1. Thereafter, the inside of the stovepipe 1 can be rubbed off with a damp cloth, whereby the electrically retained particles are wiped off and stuck on the cloth. Alternatively, the collected particles can also be wiped off and vacuumed with the vacuum cleaner brush. The electrode 4 is then reintroduced into the furnace tube 1 and the lid 5 placed gas-tight on the opening and clamped. The cleaned collector surfaces are now free again to be fogged with new particles, because now also the electrical attraction is fully effective again. With such an electrode, namely a tapered tungsten wire, it is possible to deposit up to 90% of the particles in the flue gas. Such a device or similar, it is now to put automatically when needed in operation. It turns out that a capacity measurement leads to the goal. FIG. 2 shows a measuring arrangement for connection upstream of a device for particle separation, which has been practically tested. Every 30 minutes, the flue gas flow was interrupted, resulting in a very significant drop in measured capacity. The measurement took place here over 10 hours and shows a reliable reproducible capacity change, which correlates with the presence of the flue gas stream. Without flue gas, a consistently lower capacity is measured than with flue gas. Therefore, the measured value of the capacity can be used as a guide size for a control unit. The actual capacitance measurement can be done by measuring the charging or discharging time of the capacitor, which is formed from the electrodes - ie either of spray and flue gas duct or flue gas pipe section and flue gas duct. It is also advantageous to integrate the capacitance of this capacitor into a resonant circuit or an unstable flip-flop so that the capacitance changes are reflected in the oscillation frequency. A change in the oscillation frequency then gives the signal for switching on or off the operating voltage.

3 shows a device for electrostatic particle separation in a schematic representation, and the associated control unit 9 for switching on and off of the device, which is connected to the mains. This control unit 9 is grounded and includes a measuring device 10 for the capacity and a control logic 11 for the associated high voltage source 12 of the device. The measuring arrangement for the capacitance measurement as shown in Figure 2 is connected upstream of this device, so that a flue gas first flows through the electrically conductive flue gas tube 7 inside the electrically conductive flue gas channel 1 and thereby affects the capacity between these two parts 1, 7. The variables measured by the measuring device 10 are then processed by the control logic 11 in the control unit, and accordingly the high-voltage source 12 is switched on or off, which ensures the ionization voltage at the electrode 4 with respect to the flue gas channel 1. This ensures that the Device for the electrostatic particle separation is always reliably put into operation as soon as and as long as flue gas flows through the flue gas pipe section 1 upstream in the flue gas duct 1, while after the fading of the flue gas flow due to the then reduced measured capacity, the device is turned off.

Claims

Claims

1. A method for controlling a device for electrostatic particle separation in gas flows, characterized in that the changes in the dielectric properties within the flue gas channel (1) due to the combustion are detected by the electrical capacity between the flue gas channel (1) and one located in the flue gas stream Spray or measuring electrode (4) is measured.

2. A method for controlling a device for electrostatic particle separation in gas flows according to claim 1, characterized in that the capacitance is determined by measuring the charging or discharging time of the capacitor, the capacitor being formed from the electrodes, that is to say either from the spray electrode and flue gas duct or of flue gas pipe section and flue gas duct.

3. A method for controlling a device for electrostatic particle separation in gas flows according to claim 2, characterized in that the capacitance of the capacitor is integrated in an oscillating circuit or in an unstable flip-flop, so that the changes in capacitance influence the oscillation frequency, and that due to the change in the oscillation frequency a signal for switching the operating voltage on or off is generated.

4. Control unit for a device for electrostatic particle separation in gas flows, consisting of a spray or measuring electrode (4) and an electrically conductive flue gas duct section (7) as a collector surface, further a measuring device (10) for measuring the capacitance between the flue gas duct (1 ) and the spray or measuring electrode (4) and an electronic control unit (11) for the Switching of the device using the measured capacitance as a guide size.

5. Control unit for a device for electrostatic particle separation in gas flows according to claim 4, characterized in that the measuring electrode (4) is intended to act as the spray electrode at the same time.

6. Control unit for a device for electrostatic particle separation in gas flows according to claim 4, characterized in that the measuring electrode (4) forms an electrically conductive flue gas pipe section (7), which is arranged in the interior of the likewise electrically conductive flue gas duct (1) and is electrically insulated and through which the flue gas is intended to flow, and that there is a measuring device (10) for measuring the capacitance between the flue gas pipe section (7) and the flue gas duct (1), and an electronic control logic (11) for switching the device, which the measured capacity is used as a leader.

7. Control unit for a device for electrostatic particle separation in gas flows according to claim 6, characterized in that the electrically conductive flue gas pipe section (7) is arranged concentrically in the interior of the electrically conductive flue gas duct (1) in an electrically insulated manner.

8. Control unit for a device for electrostatic particle separation in gas flows according to one of claims 6 to 7, characterized in that the electrically conductive flue gas pipe section (7) with a flue gas duct (1) of 130 mm inner diameter, a length of approximately 1 m and an outer diameter of about 100mm.

9. Control unit for a device for electrostatic particle separation in gas streams according to one of the preceding claims, characterized characterized in that the capacity can be determined by means for measuring the charging or discharging time of the capacitor, the capacitor being formed from the electrodes, that is to say either from the spray electrode and the flue gas duct or from the flue gas pipe section and flue gas duct.

10. Control unit for a device for electrostatic particle separation in gas streams according to claim 7, characterized in that the capacitance of the capacitor is integrated in a resonant circuit or in an unstable flip-flop, whereby the changes in capacitance influence the oscillation frequency, so that a signal by a change in the oscillation frequency can be generated to switch the operating voltage on or off.