DE1287532B - Device for determining the high voltage resistance of pieces of material - Google Patents

Description

1 2

The invention relates to a further embodiment of the FIGS. 1 and 2 are a series of main spring patents 1247 231. The subject of main electrodes 101, 102, 103 and 104 is a device for determining the high rod 106 attached to an insulating support patent. The rod 106 is arranged over the conductive voltage resistor of irregularly shaped plate 17, and the electrodes are directed towards the non-combustible or by electrical discharge 5 plate 17. Preferably, the spring-destructible pieces of material, with devices electrodes 101 to 104 being provided in the direction of movement of the, in order to conduct the individual pieces depending on their ore pieces down to the surface of the plate 17 conductivity on particular paths. inclined.

The device is characterized by at least one pair of the spring electrodes 101 to 104 arranged in a screw sorting zone, springs with high voltage sources and having protruding free ends, the connected high voltage electrodes are at a distance from the plate 17. The electrodes net, which lie under a baffle plate and are sufficiently damped, preferably critically, to be spaced apart from one another in order to avoid the formation of a vibrations.

To prevent air discharge between them, and further at the lower end of the baffle plate 17 are a row

15 through discharge nozzles 33, 34, 35 connected to the electrodes next to one another in

detectors, which are arranged on a discharge arc at intervals across the web. the

speak while generating a signal with the nozzles near the lower end of the guide plate 17

Ejector devices controlled by this signal are arranged where the jet emerging from the nozzles

the individual pieces is particularly effective on the desired paths.

conduct. 20 The spring electrodes 101 to 104 can be

According to the present additional invention, barten groups are now arranged, in each group

the electrodes consisting of coil springs are provided via at least one spring electrode. In the

arranged on the guide plate, with a certain in FIG. 1 preferred embodiment

At a distance from the lower conductive end of the plate, electrodes 101 and 102 have one group

exhibit. 25 and together with the common electrode form the conductive

According to a particular embodiment, the plate 17 is a pair of electrodes. One pole of a high spring electrode is electrically connected to the conductive plate. Voltage source 78 is connected to electrodes 101 and 102 , while opposite the spring electrodes one and the other pole with common electrode 17 is arranged as a second group of electrodes. The free connected. The remaining spring electrodes are in sliding ends of the electrodes are connected at such a distance 30 more like manner.

attached from the conductive portion of the plate, over any part sliding down on the plate .17 just a constant discharge of air bridges the distance between at least one of the is retained, provided that it is not placed between the spring electrodes and the plate. The piece can be initiate an insulating arc discharge moving through the electrodes, which ionizes the Body interrupts the air discharge and thus causes a current path between the electrodes. the a signal is generated which the ejector strength of the current flow depends on the material in the operated. According to another embodiment, the path between the electrodes is removed. It can be a there is a light source on one side of the track in front of a detector for a specific value of the current flow seen which a bundle of light across the web to be set on. Pressed when this value is reached a plurality of opposing photocells 40 directing a signal one or more nozzles to an air, each of which is aimed at directing a pair of electrodes towards the piece and pulling it out of its path is ordered, with each photocell deflecting when shielded.

of the light beam through a body, a control signal In FIG. 3 is the current curve (in milliamps) generated, which digs the corresponding ejector device in relation to the electrode voltage (in kilovolts), if this is not shown phically by another signal from 45. The one in the graph Detector device is prevented. The electrode values given were when using a voltage should preferably be achieved with high pulse stripes mirror iron ore, with the amplitude frequency are applied, causing a number of short air-high voltage pulses during observation eject from the ejector nozzles depending on the current flow. The curve is just the size of the body to be ejected and its 50 as an example of a relationship between tension and Conductivity is generated. Current (effective resistance) given and shows that

The invention is described below with reference to the occurrence of an ionization-type discharge. the

Drawings described in more detail. It shows curve only applies to the specific ore sample.

F i g. 1 is a partial front view of an embodiment at low values of the electrode voltage

form according to the invention, 55 the current proportional to the voltage according to the

F i g. Figure 2 is a partial side view of the Implementation Ohm's Law. This linear section of the curve

shape according to Fig. 1, 110 extends from zero to a glow chip

F i g. 3 shows a voltage point 111 useful for explaining the invention. The voltage at which the ionization graph, discharge begins, is a narrow voltage range.

F i g. Fig. 4 is a partial side view of one opposite to Fig. 60. Because of the scale used, the one is linear

F i g. 1 and 2 modified embodiment, section 110 of the curve shown slightly inclined.

Fig. 5 is a partial front view of the device when the voltage across the first glow voltage

according to FIG. 4, point 111 is increased, the ionization increases

F i g. Figure 6 is a partial front view of another extension as indicated by portion 112 of the curve.

Implementation of the invention with another elec- 65 This section describes the relationship between current

electrode arrangement and thickness and voltage are no longer linear, and

F i g. 7 is a partial side view of the embodiment. The same voltage change occurs in section 112

according to FIG. 6. greater change in current than in section 110 . To the

j ν ■

To distinguish between the individual pieces of ore, it is therefore more desirable to use the area of section 112 , since, moreover, in section 112 there is a greater current flow for a given voltage.

As the voltage increases, a second glow voltage point 114 is reached. A further increase in electrode voltage causes a current increase, as shown by section 115 , until zone 116 is reached. The portion of the curve that can be used for the purpose of the invention extends only to zone 116.

The following table shows the glow voltages and effective resistances in the linear range for some different ore samples indicated. The values depend on various factors outside of the Properties of the rock pattern. The measurements were made using a high voltage pulse on the electrodes and not one constant, rectified voltage. As a result, the calculated, effective resistance is in the low-voltage zone not exactly linear as it should be according to Ohm's law.

Tabel

Rock or ore Glow voltage
in kilovolts Supplied
Field voltage
in kilovolts Calculated effek
tive resistance
in megohms Dyke basic intrusive limestone
limestone 1.1
3.5
2.5
(8.5)
0.9
(1.9) 0.1 to 1
0.1 to 3
4 to 9
0.1 to 2
3 to 8
9 to 10
0.1 to 0.8
1 to 1.8
2 to 2.5 33 to 44
33 to 47
20 to 6
50 to 69
20 to 4
3 to 0.04
40 to 48
3 to 1.1
0.71 to 0.16 Quartz sulfide ore (greatly increased current 9 to 10 kV) ...
Layered mirror iron ore

Depending on the properties of the ore to be investigated, e.g. B. used a high DC voltage or the frequency of the pulsating current can be changed. You can also go for the impulses use different waveforms.

The ejector device according to the invention can respond to the presence or absence of a signal from the detector devices. It can the voltage can also be increased until there is a permanent ionization-like discharge between the electrodes exists, whereby the air jet is prevented until the discharge is interrupted. Dielectric Bodies are then distracted. A light beam and an opposing photocell can also be used can be used to initiate the steady discharge immediately before a body approaches. The light beam and the opposite photocell can be arranged so that the interruption of the light beam through a body initiates the emission of an air jet, if not the air jet through a signal from the detector devices is suppressed. A corresponding device is in the F i g. 4 and 5 shown.

As before, a series of spring electrodes 101 to 104 on a rod 106 of insulating material are arranged on top of the baffle 17th In the F i g. 4 and 5, however, the blast nozzles are arranged 33 to 35 at a distance from the lower end of the trajectory determining plate 17, wherein a light source 120 (F i g. 2) and a plurality of opposed photocells 121,122,123 on the opposite sides of the web portion immediately below the End of the plate 17 are provided. The light source 120 extends over the entire width of the sorting zone and throws a beam of light across the path of the falling pieces. A photocell is preferably provided for each blower nozzle. The photocells 121 to 123 advantageously have narrow openings, and the light source emits a correspondingly narrow light beam. This enables a more precise determination of the point in time at which the edges of a piece pass the photocell.

The voltage at which an ionization discharge occurs can be increased if the body in a liquid medium, such as. B. oil, moved past the electrodes.

When a high voltage with a high frequency is used, a particular body becomes accordingly the number of high-voltage pulses many times as it passes through the high-voltage electrodes be electrically charged. The number of high voltage pulses a body is exposed to, therefore depends on the length of the body, the speed with which it moves past the electrodes, and the frequency of the high voltage pulses. When the rock bridging the electrodes is sufficiently conductive, ionization takes place and a brief surge of ionization current flows. If, on the other hand, the part of the rock that bridges the electrodes is non-conductive, there will be no current surge, or at least not a sufficiently strong current surge. So while the high voltage pulses are continuously applied to the electrodes, a surge of ionizing current will only be then flow if the rock has a sufficient amount of conductive material, and only one such a surge will create a current of air.

Air is saved by adapting the air jet to the size of the rock. Simultaneously the device is able to sort the rocks according to their quality.

If the number of air jet impulses is insufficient to deflect the body, the body will follow normal path, for example by falling onto the conveyor belt 18 (see FIG. 7). The length of time each Air jets can be varied from about 4 milliseconds to a duration that is sufficient for passage the largest body is sufficient.

In the device according to FIGS. 1, 2, 4 and 5

it could happen that a spring electrode moves so far sideways under the action of a falling piece of ore that it touches an adjacent spring electrode of the next group. In this way, an air jet could be generated from the two nozzles 33 and 34 if only one of the nozzles is to be actuated. This is made possible by the embodiment according to FIGS. 6 and 7 avoided. Here a number of flat, elongated electrodes 73 ', 74' are provided, which are embedded in a block 150 made of insulating material. As before, spring electrodes 101 ', 102', 103 ' and 104' are arranged with their fastening ends on a support rod 106 . The rod 106 is located above the guide plate 17, and the spring electrodes are directed with their free ends towards the plate 17 and end at a certain distance from the same.

The blow nozzles 33 and 34 can also be embedded in the block 150.

The spring electrodes are connected to each other to form a common electrode.

One pole of the high-voltage source 78 is connected to the spring electrodes 101 ' to 104' and also to the guide plate 17, which, as before, consists of conductive material at least at the lower end. The other pole of the high voltage source 78 is connected to the electrode 73 '. Likewise, one pole of a further high-voltage source 79 is connected both to the spring electrodes 101 ' to 104' and to the conductive plate 17, while the other pole is connected to the electrode 74 '. The spring electrodes 101 ' to 104' and the guide plate 17 are expediently grounded. If the high-voltage electrodes are only arranged on one side of the track, the rock passing the electrodes, which has an ore-bearing and a deaf side, can be accepted or ejected depending on its random position between the electrodes. The embodiment of the device according to the invention according to FIGS. 6 and 7 allow two ways of generating an ionization current flow and make the random position of the falling lump less critical. This improves the sorting efficiency. In addition, with this electrode arrangement it does not matter if two spring electrodes touch each other.

The invention provides a simple, cheap and robust device for sorting bodies created with different electrical properties.

Claims (5)

Patent claims: 1. Device for determining the high-voltage resistance of pieces of material according to Patent 1,247,231, wherein. Devices are provided to guide the individual pieces depending on their conductivity on specific paths, characterized in that the electrodes consisting of helical springs (101 to 104) are arranged above the guide plate (17) and a certain distance from the lower conductive end of the plate (17). 2. Device according to claim 1, characterized in that the spring electrodes (101 ' to 104') are electrically connected to the guide plate (17), while a second group of electrodes (73 ', 74' etc.) is arranged opposite the spring electrodes. 3. Device according to one of claims 1 and 2, characterized in that the free ends of the electrodes (101 to 104) are arranged at such a distance from the conductive portion of the plate (17) that a constant air discharge is just maintained. 4. Device according to one of claims 1 to 3, characterized in that a light source (120) is provided on one side of the web, which directs a light beam over the web onto a plurality of opposing photocells (121 to 123) , each of which one is assigned to a pair of electrodes (101, 102) . 5. Device according to one of claims 1 to 4, characterized in that the electrode voltage with a high pulse frequency, causing a number of short puffs of air from the ejector nozzles can be generated depending on the size of the body to be discarded and its conductivity. 1 sheet of drawings