The subject matter disclosed herein relates to a unitary enclosure housing apparatus for protecting and cooling voltage conditioning and filtering circuitry components conventionally used for providing a current-controlled pulsing high-voltage waveform to an electrostatic precipitator device.
Some of the primary sources of industrial air pollution today include particulate matter produced from the combustion of fossil fuels, engine exhaust gases, and various chemical processes. An electrostatic precipitator provides an efficient way to eliminate or reduce particulate matter pollution produced during such processes. The electrostatic precipitator generates a strong electrical field that is applied to process combustion gases/products passing out an exhaust stack. Basically, the strong electric field charges any particulate matter discharged along with the combustion gases. These charged particles may then be easily collected electrically before exiting the exhaust stack and are thus prevented from polluting the atmosphere. In this manner, electrostatic precipitators play a valuable role in helping to reduce air pollution.
A conventional single-phase power supply for an electrostatic precipitator characteristically includes an alternating current voltage source of 380 to 600 volts having a frequency of either 50 or 60 Hertz. Typically, silicon-controlled rectifiers (SCRs), which may be controlled using a conventional automatic voltage control circuit device, are used to manage the amount of power and modulate the time that an alternating current input is provided to the input of a transformer and a full-wave bridge rectifier (called a TR set). The full-wave bridge rectifier converts the alternating current from the output of the transformer to a pulsating direct current and also doubles the alternating current frequency to either 100 or 120 Hertz, respectively. The high-voltage direct-current output produced is then provided to the electrostatic precipitator device. Typically, a low pass filter in the form, of a current limiting choke coil/reactance device such as an inductor and/or resistor is electrically connected in series between the silicon-controlled rectifiers and the input to the transformer for limiting the high frequency energy and shaping the output voltage waveform.
The electrostatic precipitator essentially operates as a big capacitor that has two conductors separated by an insulator. The precipitator discharge electrodes and collecting plates form the two conductors and the exhaust gas that is being cleaned acts as the insulator. Basically, the electrostatic precipitator performs two functions: the first is that it functions as a load on the power supply so that a corona discharge current between the discharge electrodes and collecting plates can be used to charge/collect particles; and the second is that it functions as a low pass filter. Since the capacitance of this low pass filter is of a relatively low value, the voltage waveform of the electrostatic precipitator has a significant amount of ripple voltage.
During operation, one phenomenon that can limit the electrical energization of the electrostatic precipitator is sparking. Sparking occurs when the gas that is being treated in the exhaust stack has a localized breakdown so that there is a rapid rise in electrical current with an associated decrease in voltage. Consequently, instead of having a corona current distributed evenly across an entire charge field volume within the electrostatic precipitator, there is a high amplitude spark that funnels all of the available current through one path across the exhaust gas rather than innumerable coronal discharge paths dispersed over a large area of the exhaust gas. Sparking can cause damage to the internal components of the electrostatic precipitator as well as disrupt the entire operation of the electrostatic precipitator. Therefore, an automatic voltage control circuit device is used to interrupt power once a spark is sensed. The current limiting reactance device then acts as a low pass filter to cut off delivery of any potentially damaging high frequency energy to the transformer. During this brief quench period, the current dissipates through this localized path of electrical conduction until the spark is extinguished and then the voltage is reapplied.
Therefore, to improve particle collection efficiency, it is necessary that the ripple voltage in the electrostatic precipitator be reduced. This is important since the presence of a ripple voltage results in a peak value of the voltage waveform for the electrostatic precipitator that is greater than the average value of the voltage waveform for the electrostatic precipitator. Therefore, since the peak value of the voltage waveform for the electrostatic precipitator must not exceed the breakdown or sparking voltage level due to the problems associated with sparking described above, the average voltage for operating the electrostatic precipitator must be kept at a lower level. Unfortunately, this lower level of average voltage adversely affects the particle collection efficiency of the electrostatic precipitator.
One method of accomplishing a reduction in ripple voltage involves using a pulsating direct current voltage mechanism that is operable to receive power from a single-phase alternating current voltage source along with a spiral wound filter capacitor in an arrangement where the pulsating direct current voltage mechanism is electrically connected in parallel to the spiral wound filter capacitor and the spiral wound filter capacitor is electrically connected in parallel to the electrostatic precipitator. An example circuit diagram of this type of prior art electrostatic precipitator is illustrated in
Conventionally, the above described high voltage electrical components required for this type of electrostatic precipitator are not manufactured and housed all together in a single common enclosure. In fact, all of the components together occupy a significant amount of space and consequently impose significant space and footprint requirements for an installation. Unfortunately, locations in which such electrostatic precipitators and their associated voltage controlling electronics are typically used suffer from a dearth of available installation space. Accordingly, there is great need for an electrostatic precipitator system having a housing arrangement that encloses all or most of the above electrical components within a single compact housing that is safe, reliable, easy to install, occupies a relatively small volume and spatial footprint, is cost effective and provides sufficient and efficient heat dissipation for all of the housed components.
A single housing apparatus and arrangement is described and disclosed for housing and cooling the electronic components associated with operating a high-voltage electrostatic precipitator used in industrial processes. The non-limiting illustrative example housing apparatus and arrangement disclosed herein is intended to enclose both a transformer-rectifier (T-R) set as well as a high-voltage resistor-capacitor (R-C) filter network of an electrostatic precipitator device together within a single enclosure and dissipate all of the excess heat generated by those components. To improve heat dissipation, the housing apparatus is filled with a high-dielectric non-conducting liquid coolant and fitted with heat-dissipating fin structures on one or more sides. The housing apparatus may be constructed of metal or other suitable materials and may be provided with a removable top portion and an coolant drain spigot or the like for simplifying coolant changes. The top portion of the housing may also be outfitted with an additional smaller access panel for enabling direct and easy access to the R-C filter network components contained within. In one beneficial aspect, since all of the high-voltage components of an electrostatic precipitator are conventionally not housed together in a single same enclosure, the exemplary housing apparatus disclosed herein provides an improvement over prior art electrostatic precipitators in that a much smaller spatial footprint may be achieved than previously available.
The disclosed non-limiting illustrative example implementation of the electrostatic precipitator component housing apparatus and arrangement of component housed therein is designed to have the T-R set and R-C filter network electronic components packaged within the housing, thus allowing it offer significant cost savings to a buyer when compared to conventional arrangements used for commercial HV electrostatic precipitators. Size and space requirements at the installation site can be reduced since the conventional practice of mating the T-R set and R-C filter network gear on-site is eliminated. Installation site labor is also reduced since the precipitator voltage control component housing apparatus/arrangement includes the high voltage T-R set and R-C filter network components.
In
For example, an alternating current voltage, which is in the form of a sinusoidal waveform that goes between a negative value for one-half cycle and a positive value for one-half cycle with a value of zero volts between each half cycle, is applied to the line input terminals. This alternating current line input voltage may typically range from 380 to 600 volts and have a frequency of 50 or 60 Hertz. One line input terminal is electrically connected in series to a cathode of a first silicon-controlled rectifier and is also electrically connected in series to an anode of a second silicon-controlled rectifier in an inverse parallel relationship. Only one of the silicon-controlled rectifiers and conducts during any particular half cycle. The gate of the first silicon-controlled rectifier and the gate of the second silicon-controlled rectifier are both electrically connected to a conventional automatic voltage control circuit/device. This automatic voltage control circuit applies a positive trigger voltage to either the gates of the two silicon-controlled rectifiers (SCRs) to initiate a current carrier avalanche within an silicon-controlled rectifier to allow current during either the positive or negative portion of the alternating current cycle to flow from either the anode of one SCR or the cathode of the other SCR, respectively. This enables the SCRs to turn on (conduct current) at the same voltage level during a half cycle and remain, turned on until the current through one or the other SCR falls below a predetermined level.
A conventional automatic voltage control circuit/device is provided for power control and for regulating the amount of time that, the ac voltage line which is electrically connected to the input line terminals remains conducting. In addition, when a spark occurs, the automatic voltage control circuit/device stops providing an trigger/avalanche voltage to the gates of the SCRs to allow the spark to extinguish. A representative automatic voltage control device is disclosed in U.S. Pat. No. 5,705,923, which issued to Johnston et al, on Jan. 6, 1998 and is assigned to BHA Group, Inc. and entitled “Variable Inductance Current Limiting Reactor Control System for Electrostatic Precipitator”. The anode of the first SCR and the cathode of the second SCR are electrically connected in series to a current limiting reactor device. The current limiting reactor filters and shapes the voltage waveform leaving the SCRs. Ideally, the shape of the voltage waveform leaving the current limiting reactor will be broad since the average value equates to total work and since such a voltage waveform typically yields the best collection efficiency for an electrostatic precipitator. Ideally, the peak and average values of the voltage signal entering the electrostatic precipitator device should be very close. Moreover, enhanced power transfer is attained when the toad impedance matches the line impedance. Therefore, the reactance value of the current limiting choke coil reactance device is preferably predetermined so that the inductance of the current limiting reactor device matches the total circuit impedance including the load of the electrostatic precipitator device.
Referring next to
A high-voltage insulating bushing 25 is located at the top of tank/housing 20 and includes a portion which passes through cover plate 24 into the interior of tank/housing 20. An end portion, of bushing 25 is preferably submerged within dielectric liquid coolant 21 and acts as an output terminal conductor pass-through to the outside of tank/housing 20. A protective guard ring 26 on cover plate 24 surrounds insulator 25. Handle structures 35 are provided on cover plate 24 for assisting removal of the cover plate. External mounting brackets 27 are also provided beneath flange 23 on two upper sides of tank/housing 20 near each of the corners. Holes are provided along flange 23 and along the edge of cover plate 24 for insertion of bolts to secure the cover plate to the tank/housing. Likewise, bolt holes may also be provided in cover access panel 34 and cover plate 24 for use in securing the access panel to the housing top cover plate. A support base 28 is provided on the bottom of tank/housing 20. In addition, an liquid coolant drain valve/spigot 29 is provided on one side near the bottom of tank/housing 20.
Attached to each of two opposite sides of tank/housing 20 is a conventional panel type radiator 30 comprising a plurality of vertically-extending hollow panels 31 disposed in face-to-face, horizontally spaced-apart relationship with vertical passages between the exterior faces of the panels. Each radiator 30 includes a pair of vertically-spaced header pipes 32 and 33 at its upper and lower ends communicating with the interior of the tank 20 at its upper and lower ends, respectively. The normal liquid level of coolant 21 in the tank/housing 20 is above the location of the upper header pipe 32.
When the electrostatic precipitator is in operation, the liquid coolant in tank/housing 20 becomes heated. The heated coolant rises to the top of the tank/housing through natural convection, entering the radiator through the upper pipe 32. As the coolant is cooled within the radiator 30, it flows downwardly within hollow panels 31, returning to the tank interior through the lower pipe 33 as relatively cool liquid. The coolant continues circulating in this manner, moving upwardly within the tank 20 and downwardly within the radiator 30, as the electrostatic precipitator is operated. Each radiator 30, of course, serves to extract heat from the coolant as it flows downwardly through and within each radiator portion, thus limiting the temperature of the coolant within tank/housing 20.
Referring now to
As more clearly illustrated in
Referring now to
This written description uses various examples to disclose exemplary implementations of the invention, including the best mode, and also to enable any person skilled in the art to practice the invention, including making and using any devices or systems and performing any incorporated methods. The patentable scope of the invention is defined by the claims, and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they have structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal languages of the claims.
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Number | Date | Country | |
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20110043999 A1 | Feb 2011 | US |