DE29980204U1 - Dust binding device - Google Patents

Description

Dust binding device

The invention relates to a dust-binding device comprising corona electrodes, voltage supply means for supplying the corona electrodes with high voltage and a control unit for controlling the function of the dust-binding device.

It is often necessary to install at least some form of dust removal system in conjunction with conveyors for bulk material, for example mine ore. Dust is typically removed in an ionization-based dust suppression device, with corona electrodes fed at high voltage. The wall and other steel structures of the dust suppression device housing and the material being conveyed create a grounded surface, and an electric field is created between the electrodes and the grounded surface. If the voltage at an electrode is high enough, the electric field near the electrode exceeds the dielectric strength of the air, resulting in ionization of the air. A partial electrical discharge on the electrode surface is called St. Elmo's Fire. In a negative St. Elmo's Fire, the electrode emits free electrons which drift away from the electrode under the influence of the electric field. Between the electrode and the grounded surface there is an electric field where an electric current begins to flow under the influence of free charge carriers. When negative ions and free electrons come towards the grounded surface under the influence of the electric field, they collide with dust particles in the air, causing the dust particles to become charged. Dust particles accumulate through two different mechanisms.

First, most of the accumulation occurs under the influence of an external electric field, where charged dust particles drift against the grounded surface and adhere to it. The second mechanism by which particles accumulate is the so-called space charge-induced accumulation.

The voltage required by a corona electrode is typically generated by a high voltage unit comprising a high voltage feeder and a voltage multiplier in the same enclosure. A high voltage unit generates the voltage required by corona electrodes and the said voltage is fed to a distribution unit and from there to each dust control unit. The high voltage unit is controlled by a manually adjustable control transformer which allows the

the voltage supplied to the high-voltage unit is adjusted. High-voltage units are extremely large and heavy. In addition, the high-voltage cables required are thick and expensive, and they must be installed over fairly long distances. Distribution units are also large and expensive. It is also complicated to adjust the system because each individual dust-binding unit cannot be adjusted individually, but all units are adjusted simultaneously. Solutions using such an arrangement are disclosed, for example, in SU publications 1208265 and 1574828.

In another known solution, the voltage required by corona electrodes is generated by a device comprising a high voltage unit with a high frequency unit, a transformer and a multiplier. The function of the high voltage unit is controlled with a separate control unit. The mentioned structure allows the high voltage unit to be made smaller than in the above mentioned solution and therefore a separate high voltage unit can be mounted for each dust suppression unit. However, the high voltage unit is still quite large and thus requires a rather large, cumbersome and expensive housing, especially if the unit is to be placed near the dust suppression unit. If, on the other hand, the unit is not placed near the dust suppression unit, expensive high voltage cabling must be used.

The present invention is based on the object of providing a dust-binding device which avoids the disadvantages mentioned above.

The dust binding device of the invention is characterized in that the voltage supply means comprise a medium voltage unit and a voltage multiplier, which voltage multiplier and which medium voltage unit are placed at a distance from each other, which voltage multiplier is arranged in connection with the corona electrodes, and which medium voltage unit and which voltage multiplier are coupled to each other by a medium voltage cable.

An essential idea of the invention is that the device has a medium voltage unit for generating the medium voltage and a voltage multiplier for generating the final high voltage and the

The medium-voltage unit and the voltage multiplier are arranged at a distance from each other and connected by a medium-voltage cable.

An advantage of the invention is that essentially only the voltage multiplier is placed in connection with the corona electrode and the medium voltage unit is placed at a distance from the dust-binding unit, whereby difficult dusty conditions only have to be taken into account when encapsulating the voltage multiplier and the rest of the equipment required to generate the high voltage can be located in an environment with much simpler external conditions. In this case, high voltage does not have to be conducted over long distances along an expensive high voltage cable, but the voltage is conducted from a medium voltage along a medium voltage cable. The device thus created is small and inexpensive to manufacture. Each dust-binding unit can be adjusted separately and the control unit has the task of monitoring various error situations and adjusting the device precisely.

The invention is described in the accompanying drawing.

Figure 1 is a block diagram of a device of the invention,

Figure 2 is a schematic side view of a dust binding unit of the invention in partial section, and

Figure 3 is a block diagram of a second device of the invention. Figure 1 is a block diagram of a device of the invention. A voltage feeder 1 is used to feed a medium voltage unit 2 with operating voltage. The medium voltage unit 2 consists of a high frequency unit 3 and a voltage transformer 4. The high frequency unit 3 and the voltage transformer 4 can be mounted on the same circuit board, resulting in a small device that is easy to manufacture. In the high frequency unit 3 the frequency of the electric current is increased high, for example to approximately 15 kHz. The voltage is then increased to the maximum of a few kVs with the voltage transformer 4. After the medium voltage unit 2 the maximum voltage can be for example 10 kV. A voltage varying for example between 0 and 24 V can be fed to the medium voltage unit 2 and the medium voltage unit 2 generates a voltage varying for example between 0

and 2 kV. The medium voltage generated by the medium voltage unit 2 is fed via a medium voltage cable 5 to a voltage multiplier 6. In this case, the voltage multiplier 6 and the medium voltage unit 2 are located at a distance from each other. The voltage multiplier 6 generates the final voltage, which can vary for example between 0 and 60 kV, and is fed to the corona electrodes 7. In the case of dust binding, the voltage of the corona electrodes 7 must be above 40 kV so that the device can bind dust in conjunction with a bulk material processing device. The function of the various parts of the device is monitored and controlled by a control unit 8.

The voltage supply 1 and the control unit 8 can be connected to each other, for example, by a serial bus. The control unit 8 measures the voltage and current of the voltage supply 1 and sets the voltage and current to a level suitable for the function of the device. Furthermore, the control unit 8 receives error information from the voltage supply 1. The control unit 8 switches the high frequency unit 3 on and off, and overcurrent, overheating alarms and current measurement can be fed from the high frequency unit 3 to the control unit 8. For example, an overheating alarm can be fed from the voltage transformer 4 to the control unit 8. For example, current and voltage measurements can be fed from the voltage multiplier 6 to the control unit 8. The control unit 8 can be coupled to the rest of the data system, for example, by a serial bus.

Figure 2 shows the device of the invention arranged in connection with a conveyor 9. Instead of a conveyor 9, the dust-binding device can be placed in connection with another bulk material processing device such as a feeder, a screen or a crusher. The dust-binding device can also be placed in, for example, a warehouse, a silo or a bulk material receiving station.

The conveyor 9 conveys material, for example mine ore, in the direction of arrow A. The conveyor 9 is provided with a dust-binding housing 10. The dust-binding housing 10 has the corona electrodes 7 in a manner known per se. Since the medium voltage unit 2 and the voltage multiplier 6 are coupled by the medium voltage cable 5, they can be placed at a distance from each other, whereby in addition to the electrodes 7 only the voltage multiplier 6 in connection with the dust-binding

The voltage multiplier 6 is placed in connection with the corona electrodes 7 within an insulator. The medium voltage unit 2 can be placed in less demanding environmental conditions. In any case, a very high voltage does not have to be conducted in the medium voltage cable 5, and the medium voltage cable 5 can be dimensioned such that it has a maximum voltage of e.g. 10 kV.

Figure 3 shows a block diagram of a second device of the invention. In the solution of Figure 3, the medium voltage unit 2 is used to generate a high frequency medium voltage, which varies for example between 0 and 20 V and is fed by means of the medium voltage cable 5 to a unit consisting of the voltage transformer 4 and the voltage multiplier 6 and which feeds the corona electrodes 7 with the required voltage of over 40 kV. In this case, the permissible voltage in the medium voltage cable 5 does not need to be very high. Since a power of about 100 W is sufficient for the device, the current in the medium voltage cable 5 in the solution of Figure 3 does not need to exceed 10 A, whereby losses and heating of the medium voltage cable 5 do not cause any problems. The voltage transformer 4 and the voltage multiplier 6 can be arranged within the same insulator, for example by casting them in the same resin housing.

The drawing and the associated description serve only to illustrate the idea of the invention. The details of the invention may vary within the scope of the claims.

Claims (6)

1. Dust-binding device to be arranged in connection with a bulk material processing device, which dust-binding device has corona electrodes ( 7 ), voltage supply means for feeding the corona electrodes ( 7 ) with high voltage and a control unit ( 8 ) for controlling the function of the dust-binding device, characterized in that the voltage supply means comprise a medium-voltage unit ( 2 ) and a voltage multiplier ( 6 ), which voltage multiplier ( 6 ) and which medium-voltage unit ( 2 ) are placed at a distance from one another, which voltage multiplier ( 6 ) is arranged in connection with the corona electrodes ( 7 ), and which medium-voltage unit ( 2 ) and which voltage multiplier ( 6 ) are coupled to one another by a medium-voltage cable ( 5 ). 2. Dust-binding device according to claim 1, characterized in that the medium-voltage unit ( 2 ) has a high-frequency unit ( 3 ) and a voltage transformer ( 4 ). 3. Dust-binding device according to claim 2, characterized in that the high-frequency unit ( 3 ) and the voltage transformer ( 4 ) are mounted on the same circuit board. 4. Dust-binding device according to protection claim 1, characterized in that the dust-binding device has a voltage transformer ( 4 ) arranged in connection with the voltage multiplier ( 6 ). 5. Dust-binding device according to any one of the preceding claims, characterized in that the voltage multiplier ( 6 ) is arranged within an insulator. 6. Dust binding device according to any one of the preceding claims, characterized in that the voltage of the corona electrodes ( 7 ) during dust binding exceeds 40 kV.