SE454556B - LIGHT REAR HEATING DEVICE FOR HIGH SPEED FLOWING GAS - Google Patents

Description

454 556 electric arc between the ignition electrode and the second or first electrode, whereby an electric arc is lit between the first and the second electrode.

Suitably, an arc heater with a first substantially cylindrical electrode is located at an axial distance from a second substantially cylindrical electrode, so that a plasma or gas with a high flow rate can pass between them. An ignition device, which may consist of a plurality of electrodes, is arranged in the space between the first and the second electrode, whereby an arc ignition space is formed between the first and the second substantially cylindrical electrode. A potential source is connected to the ignition device, whereby an arc is formed in the space between the first and the second cylindrical electrode, whereby a heating takes place of gases which possibly pass in the space between the electrodes.

The invention will be described in more detail below with reference to the accompanying drawings.

Figure 1 shows a vertical section through an arc heater showing the location of the electrodes.

Figure 2 shows in magnification a part A of figure 1 with an ignition electrode.

Figure 3 is a top view of the lower electrode shown in Figure 2. e Figure 4 shows in section an electrode using a machining method to provide an electrode tip.

Figure 5 shows a top view of the electrode shown in Figure 4.

Figure 6 is an isometric view of a portion of the electrode shown in Figures 4 and 5.

Figure 7 shows in magnification a part A of the device shown in figure 1 with connected ignition electrode.

Figure 8 shows an enlargement of the part A of the device shown in figure 1 with a centrally arranged ignition electrode.

Figure 9 shows on an enlarged scale a modification of the part A of the device shown in Figure 1 with an ignition electrode having a separate power source.

Figure 1 shows a vertical section. A description of the construction and operation of an arc heater 12 is found in U.S. Pat. No. 4,214,736. The arc heater 12 is provided with an upstream electrode 14 and a pointed electrode 16. The electrodes 14 and 16 are spaced apart from each other, e.g. 1 mm in the ignition gap, whereby they leave room for a power source (not shown) with, for example, a voltage of approximately 4 kv, which voltage in the device according to the invention can be either alternating voltage or direct voltage. An arc 20 appears in the space 18, where incoming gas 22 blows the arc from the space 18 into the interior of the arc chamber 24.

The light bag 20 can rotate at a speed of about 1000 revolutions per second by the interaction between the arc current (several 1000 amperes) and a magnetic field generated by internally mounted field coils 26, 28. The speeds produce a very strong action, which results in the the elongated arc 20 is finally thrown by the gas downstream towards and possibly into a melting chamber (not shown). Power is supplied to the device 12 by power cables 30, 32. In addition, the device 12 comprises a mounting flange indicated at 36 and designated 34 in its entirety. The flange 38 is attached to the outer metal surface 40 of a melting chamber (not shown). The flanges 36 and 38 are fixed by means of radially spaced members 42 each consisting of a nut and a bolt. The flange 36 is provided with a water inlet 44 and a water outlet 116, through which cooling water is circulated in the arc heater to cool the electrodes 111, 16. Similarly, a gas inlet 23 is arranged to conduct gas 22 to the space 18 and to the upstream end of the arc heater.

Figure 2 shows on a larger scale a part A of figure 1 with an ignition electrode. Since Figure 2 shows a part of the components of Part A of Figure 1, the components which are the same as those shown in Figure 1 have been provided with the same reference numerals in Figure 2. The upstream electrode 14 has a dowel fan member 50 and the pointed electrode 16 with a spacer 52 is spaced apart by an insulating plate B1 and contact rings S1 and 53. The insulator 54 and contact rings 51, 53 provide a carefully defined gap between the electrodes 14 and 16 without necessitating complicated measurement or control procedures. The incoming gas 22 is introduced through the gas inlet 23 and heated by an arc 20 in the space between the electrodes 14 and 16. The ignition electrode 1: 8 may be of the same material as the electrode 16 or of another material such as e.g. copper-tungsten or silver-tungsten. The ignition electrode 1: 8 allows the gap 18 to be large, such as for example 2 mm to 4 mm, whereby the gas 22 can enter the gap 18 at a high flow rate, at the same time as a relatively small breakthrough gap is present, which gap can be 1 mm . Thus, the cross-sectional area of the gas stream is increased by increasing the gap between adjacent electrode ends 14, 16 while obtaining a relatively small breakthrough gap. This facilitates an adaptation to the dielectric properties of the gas 22 to the arc voltages that can be expected, as well as power supply conditions. The ignition electrode 48 has been shown to be threaded into the tip of the electrode 16, but as will be readily appreciated, the electrode 48 may be pressed, brazed, welded or incorporated. In addition, the shape of the tip of the electrode 48 may be other than the rounded one as shown, e.g. square or hexagonal. In addition, since different gases have different dielectric properties, the dimension 66 of the breakthrough gap can be changed simply by changing the size of the ignition electrode 14, thereby eliminating the need to use insulating plates 54 of different thicknesses. Admittedly, only one electrode 48 is shown, but it will be appreciated that other ignition electrodes may be and are usually located on the end of an electrode. A number of ignition electrodes 48 may, for example, be located either on the upstream electrode 14 or the electrode 16, as shown, or on both electrodes 14, 16. Figure 3 shows a cross section of the electrode 16 shown in Figure 2. In a suitable embodiment of the invention there are two ignition electrodes 48, which are located diametrically opposite each other. Figure 4 shows a cross section of a machined electrode tip 58.

The electrode 58 is provided with a spacer S2 'similar to that shown in Figure 2. In addition, an electrode tip 60 is provided at the top of the electrode 58, and unlike that described with reference to Figure 2, the electrode tip 60 is part of the electrode 58. The electrode 58 seen from above is shown in 'figure 5, where two electrode tips 60 and 60' are shown, which are located diametrically opposite each other. An isometric view of the electrode 58 shown in Figures 4 and 5 is shown in Figure 6.

Figure 7 shows on a larger scale a part A of the device shown in Figure 1 modified to utilize a nearby ignition electrode 62.

The upstream electrode 14 with a spacer S0 'and the downstream electrode 63 with a spacer 52' are held apart by the insulating plate 54 'and the contact rings 51' and 532. The insulator 54 'and the contact rings 51' and 53 'provide an exact gap between the electrodes 14' and 63 without to necessitate complicated measurement or control procedures. The incoming gas 22 is introduced through the gas inlet 23 and heated by the arc 20 in the space between the electrodes 14 and 63. The adjacent ignition electrode 62 may be of the same material as the electrode 63 or of some material such as copper-tungsten or silver-tungsten . The ignition electrode 62 is ._, ..._-. 454 556 electrically connected to the contact ring 53 ', whereby the ignition electrode 62 has the same potential as the downstream electrode 63. The ignition electrode 62 extends into the space 18' and thereby provides a break-through gap 56 'similar to that found in the embodiment of Figures 2 and 4. It may be pointed out that the ignition electrode 62 may be curved or bent to conform to the desired 'position to form the desired breakthrough gap 56'.

In addition, the ignition electrode 62 can be placed on the upstream electrode 14 'using the contact ring 51'. Furthermore, a number of ignition electrodes 62 can be placed, for example, in the vicinity of the upstream electrode 14 or the downstream electrode 63 (as shown), or on both electrodes 14 'and 63. Thereby a gas flow ratio is obtained, similar to that obtained with the electrodes according to Figures 2 and 4. .

Figure 8 shows on a larger scale a part A of the device shown in Figure 1 modified for use with a centrally arranged ignition electrode 64. The construction and mode of operation of this embodiment is similar to that of the embodiment according to Figures 2 and 7, except for the centrally located ignition electrode 64. The centrally located ignition electrode 64 may be completely electrically insulated from the electrical potential applied to the electrodes 14 'or 63k. The centrally located ignition electrode 64 is supplied with electrical voltage using a ring 66 located where the insulating plate 54 or 54' (shown in Figures 2). and 7) would have been placed, thereby making electrical contact with the bath rings 51 ', 532 In the embodiment of Figure 8, the connecting ring 66 would make electrical contact with the contact ring S3' and thereby supply the centrally located ignition electrode 64 with the same potential as the downstream electrode 632. The centrally located ignition electrode 64 is therefore located close the electrode having another potential, namely the upstream electrode 14 '. Adjustment of the ignition electrode 64 can be performed by making a bend in the ignition electrode 64. In addition, the ignition electrode 64 can have other shapes and be, for example, round or hexagonal.

In addition, a plurality of centrally arranged ignition electrodes 64 may be connected e.g. to the same potential as the upstream electrode 14 'or the downstream electrode 63' (as shown) or in combination, different ignition electrodes being at the same potential as either the upstream electrode 14 'or the downstream electrode 63'. Figure 9 shows on a larger scale a part A of the embodiment shown in Figure 1 modified with an electrically insulated ignition electrode 68. The insulated ignition electrode 68 can be supplied with power from a completely separate 454 556 power source other than that connected to the electrodes 14 ' and 63k This secondary power source (not shown) can be activated e.g. only during start-up, thus eliminating the need for the device's power supply to have a large pole voltage. In addition, devices for regulating the power factor sasonw capacitors can be considerably reduced due to the desired voltage requirement for the power supply of the apparatus and associated transformers. The insulated ignition electrode 68 is connected to the support rod 70, which is held in place by electrical insulation from surrounding equipment of the insulation plate 542. The support rod 70, which is made of electrically conductive material, extends to the contact 72 which in turn is connected to the socket 78 and thus to a secondary power source (not shown) through the cable 8D.

The support rod 70 can be moved by means of the regulating mechanism 73 whereby its position in the gap 18 'is changed so that the distance of the ignition gap between the' insulated ignition electrode 68 and the electrode 14 'or 63' is changed. The socket 78 and the contact 72 are supported by insulators 76, 77 arranged on different sides of the housing 74 of the apparatus. It can be pointed out that the insulated ignition electrode 68 can have different shapes and sizes and thereby be adapted to different gases with different dielectric breakdown strengths as well as different supply currents. voltages applied to the electrodes 14 'and 63'. The insulated ignition electrode 68 may also be curved so as to provide a tight ignition gap not one electrode or the other. In addition, a plurality of insulated ignition electrodes 68 may be located in the space 18 '. Furthermore, the voltage applied to the ignition electrode 68 may have a potential equal to the potential of any of the electrodes 14 ', 63' or a potential greater or less than the potential of the electrodes 14 ', 63' and may also be at a potential which is between the potentials of the electrodes ll fl, 63k Once the arc heater has started when the insulated ignition electrode 68 utilizes the secondary power source (not shown), the power supplied to the ignition electrode 68 through the cable 80 may be connected to the power source of the apparatus to cause re-ignition, if the arc would go out Lex. if the voltage drops.

The invention can be varied in many ways within the scope of the inventive concept. Thus, for example, different mutual distances between the electrodes and other electrodes can also be used. Furthermore, different gaps than those shown can be used to effect adaptation to even greater plasma flow rates, lower plasma flow rates, different light bag rotation, supply voltages as well as different dielectric properties of the gases. 454 556 The gap can be changed without major modification. The described invention further allows less complicated power supply systems or more Optimal self-starting properties. The invention thus entails a less complicated and cheaper way of designing and operating a light bag heater for high speed flowing gas.

Claims (13)

_ 454 5l56 PATENT REQUIREMENTS A high speed flow bag gas protection apparatus, characterized in that it comprises a chamber (24), a first electrode (14) arranged inside and coaxial with said chamber, a second electrode (16) arranged inside and coaxially with said chamber , the second electrode being located at an axial distance from the first electrode so as to form a gap (18), which allows a gas (22) with a high flow rate to pass therebetween, and ignition devices (48) arranged between the first and the second electrode for lighting an electric arc (20) between the igniters and the second or first electrode, whereby an electric arc (20) is formed between the first and second electrodes. Apparatus according to claim 1, characterized in that said first and second electrodes are substantially cylindrical. Apparatus according to claim 1 or 2, characterized in that said ignition devices (48) are attached to the first or the second electrode, and that an ignition electrode in the ignition devices extends into said gap (18) and thereby forms a relatively small gap between the ignition electrode and the second or first electrode relative to the size of the first-mentioned gap. 4. Apparatus according to claim 3, characterized in that a plurality of ignition electrodes are attached to the first and / or the second electrode. Apparatus according to any one of claims 1-4, characterized in that the ignition electrodes are parallel to the first or second electrode. Apparatus according to any one of claims 1 to 1, characterized in that the ignition electrodes are arranged between the first and the second electrode and perpendicular to their common longitudinal axis. 7. Apparatus according to claim 5 or 6, characterized in that the ignition electrode is electrically connected to the first electrode or the second electrode. 8. Apparatus according to claim 7, characterized in that the ignition electrode is arranged closer to said second electrode than the first cylindrical electrode. 9. Apparatus according to claim 7, characterized in that the ignition electrode is arranged closer to the first cylindrical electrode than the second cylindrical electrode. Apparatus according to any one of claims 1-9, characterized in that the ignition electrode has a curved shape. Apparatus according to any one of claims 1 to 10, characterized in that the ignition electrodes are located at an electric potential between the first and the second electrode during ignition of the electric light bag or at an electric potential different from the first or second electrode. Apparatus according to claim 1, characterized in that a plurality of ignition electrodes are arranged between the first and the second electrode. Apparatus according to any one of claims 1-12, characterized in that the ignition electrode has a hexagonal or square shape or is substantially rounded.