JPH0261800B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a method for stabilizing low-temperature plasma forming an arc burner in an arc burner device.

[Conventional technology]

Basically, the flow of cold plasma that forms an arc burner is stabilized by an electric arc created in a channel between a cathode and an anode, surrounded by a vortex of injected stabilizing fluid.

Conventional methods for stabilizing low-temperature plasmas include the use of predetermined stabilizing liquids to protect the channel material from the thermal effects of the electric arc and the resulting plasma, and to protect the cathode from oxidation. ing. In this case, particularly ionized water is introduced into the arc burner device through tangential inlets arranged near the cathode and between each orifice plate and is slit-shaped in such a way that a vortex is formed within this arc burner device. Water is drained from the outlet.

The electric arc burns through a sufficiently dense vortex to ensure the formation of a plasma and to cool the arc burner device. The use of water as a stabilizing liquid for plasma stabilization is important to ensure all necessary functionality, but while it simplifies the design and operation of plasma generation, it also reduces the high plasma temperature. limit the possibility of reaching. Furthermore, it increases cathode wear and the reducing effects of the recombined plasma limit its applicability to certain plasma sprays, especially in the field of ceramic oxides.

West German Patent No. 2028193 is formed as a basic structure by a cathode and its surrounding accessories,
Furthermore, a compact arc burner device is disclosed which is formed by a nozzle and an intermediate ring, an inlet and two outlets to ensure the circulation of the stabilizing liquid. However, the design of this type of arc burner equipment
It is not possible to use different kinds of stabilizing liquids.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a method for stabilizing low temperature plasma in an arc burner, which overcomes the drawbacks and limitations of conventional single stabilizing liquids in arc burner devices.

[Means to solve the problem]

The present invention is a method for stabilizing the low-temperature plasma of an arc burner by introducing a stabilizing liquid into the discharge chamber and stabilizing channel of an arc burner device. The first stabilizing liquid contains chemically bonded carbon or nitrogen and is introduced into the discharge chamber, and the second stabilizing liquid has a boiling point different from that of the first stabilizing liquid. is characterized by introducing into the stabilization channel.

The arc burner device to which the present invention is applied consists of a discharge chamber around a rod-shaped cathode, a stabilization channel formed by a nozzle and a ring device, an external rotating anode and a circuit for the circulation of a stabilizing liquid, and a discharge chamber and a stabilizing channel. It is constituted by the transition spaces between the channels.
The transition space is provided with a slit-like outlet for at least one stabilizing liquid. A tangential inlet for the first stabilizing liquid introduced into the discharge chamber is mounted on each stabilizing liquid line, as is a second stabilizing liquid introduced into the stabilizing channel. The orifice plate is installed in the transition space.

Suitable combinations of two or more stabilizing arc burners can improve operating parameters in some configurations. The use of a carbon-containing stabilizing liquid in the discharge chamber of an arc burner device can consequently suppress inappropriate shrinkage of the carbon cathode due to surface oxidation.

By using a stabilizing liquid containing chemically combined carbon and nitrogen, the disadvantages of stabilizing liquids are overcome and metal electrodes such as tungsten or thorium can be used, which makes it possible to stabilize liquids until now. Applications not previously available in plasma arc burners become possible. The use of a liquid with a higher dissociation energy than water allows an increase in the output parameters of the arc burner, in particular the temperature of the recombinant plasma.

The appropriate combination of stabilizing liquids, that is, the liquid introduced into the discharge chamber is selected from the viewpoint of the arc burner's startup ability, and the liquid introduced into the stabilization channel is selected from the viewpoint of the influence of the temperature of the generated plasma. By this, the composition of the recombined plasma is
In particular, its oxidation and reduction properties can be controlled simultaneously. The values of enthalpy, temperature, velocity, chemical reactivity, etc. of plasma generation according to the present invention are improved, which is very advantageous when using plasma in other applications. At the same time, the life of the arc burner is increased as the negative factor of plasma generation is reduced as mentioned above.

Due to the arrangement of the stabilizing liquid outlets, in the discharge chamber the stabilizing liquid flows from the cathode to the anode, thereby increasing the stability of the arc burner, and in the stabilizing channel, it flows from the anode to the cathode, thereby increasing the output of the plasma generator. It is possible to select the plasma flow such that the

〔Example〕

FIG. 1 is a configuration diagram of an embodiment of an arc burner device according to the present invention. This figure shows an example equipped with a transition space and an orifice plate. The arc burner device 1 has a transition space 2 with an orifice plate 3, which is divided into a stabilizing channel 7 and a discharge chamber 5, surrounding a rod-shaped cathode 6. At the opening of the stabilizing channel 7 there is a nozzle 8, and inside the channel a stabilizing orifice plate 9 is provided. In the discharge chamber 5 there are tangential inlets 10 for the stabilizing liquid, while tangential inlets 11 are provided in the stabilizing channel 7, these tangential inlets 10 being each attached to a distribution tube 15 for the stabilizing liquid. A distribution tube 15 is provided for a first stabilizing liquid which stabilizes the discharge chamber 5 and a distribution tube 16 is provided for a second stabilizing liquid which stabilizes the stabilization channel 7. The arc burner device 1 furthermore has on both sides of the orifice plate 3 an outlet 12 leading to the discharge chamber 5 and an outlet 13 leading to the stabilization channel 7 .

The arc burner device of FIG. 1 uses graphite as a cathode, and a styrene liquid is introduced into the discharge chamber of the arc burner device. Styrene has a boiling point of 145°C and is insoluble in the liquid (water, boiling point 100°C) introduced into the stabilizing channel of the arc burner device. Water and liquid styrene flow unmixed from the cathode to the anode. These two types of stabilizing liquids significantly increase the lifetime of the cathode and at the same time strengthen the plasma flow.

If graphite is used as the cathode of the arc burner device shown in Figure 1 and nitrobenzene is introduced into the discharge chamber of the arc burner device, nitrobenzene has a boiling point of 211°C and the liquid ( Insoluble in water). This 2
Both types of liquids flow from the cathode to the anode. This 2
A combination of types of stabilizing fluids has a similar effect to the combination of water and styrene described above.

FIG. 2 is a block diagram of another embodiment of the arc burner device of the present invention. This figure is an example in which the transition space is shown as a slit. The outlets 12 and 13 leading to the discharge chamber 5 and the stabilizing channel 7 are provided in the inner wall facing the slit 4 at different distances from the central axis of the arc burner device 1, depending on the physical properties of the stabilizing liquid used. The two outlets 12 and 13 can be replaced by one. A preliminary outlet 14 is provided in the nozzle 8 leading to the stabilizing channel 7 to reduce losses of stabilizing liquid.

The arc burner device shown in FIG. 2 uses tungsten thorium as a cathode. Toluidine with a boiling point of 201°C is introduced into the discharge chamber of the arc burner device, and this toluidine is mixed with other stabilizing liquids (toluene,
It melts with a boiling point of 111℃). The flow of toluidine from the cathode to the anode and the flow of toluene from the anode to the cathode stabilizes the arc burner and increases the number of recombined particles. That is, toluidine in the discharge chamber of the arc burner device flows from the cathode to the anode, and toluene flows in the opposite direction. This method improves the stability of the arc burner.

Further, graphite is used as a cathode in the arc burner device shown in FIG. 2, and ethyl alcohol is introduced into the discharge chamber of the arc burner device. Ethyl alcohol has a boiling point of 78
°C and melts with a liquid (picoline, boiling point 144 °C) that is introduced into the stabilization channel of the arc burner device. This combination significantly improves the start-up performance of the plasma generator.

Good results have also been obtained with other types of stabilizing liquids, such as methyl alcohol and ethyl nitrate. The lifespan of the cathode with the combination of the above stabilizing liquids is
Improved by 30-35%.

〔Effect of the invention〕

As explained above, according to the present invention, in plasma generation in an arc burner device, two types of plasma stabilizing liquids with different properties are used,
By dividing the structure into a discharge chamber and a stabilizing channel, and introducing one stabilizing liquid into the discharge chamber and the other stabilizing liquid into the stabilizing channel, stable plasma generation is achieved and the cathode life is extended. Can be done.

[Brief explanation of drawings]

FIG. 1 is a cross-sectional view of one embodiment of the arc burner device of the present invention, and FIG. 2 is a cross-sectional view of another embodiment of the arc burner device of the present invention. (Explanation of symbols), 1... Arc burner device, 2
...Transition space, 3,9...Orifice plate, 4
... slit, 5 ... discharge chamber, 6 ... rod-shaped cathode,
7... Stabilization channel, 8... Nozzle, 10,1
1... Inlet, 12, 13... Outlet, 14... Reserve outlet, 15, 16... Distribution pipe.

Claims (1)

[Claims] 1. In an arc burner device comprising a discharge chamber surrounding a rod-shaped cathode and a stabilizing channel having a nozzle at one end and leading to the discharge chamber at the other end via a transition space. , a method for stabilizing low-temperature plasma in an arc burner, which comprises: introducing a stabilizing liquid into the discharge chamber and the stabilization channel to stabilize the low-temperature plasma; introducing a first stabilizing liquid containing bound carbon or nitrogen; and introducing into the stabilizing channel a second stabilizing liquid having a boiling point different from the boiling point of the first stabilizing liquid. A method for stabilizing low-temperature plasma in an arc burner. 2. The method of claim 1, wherein the first stabilizing liquid has a lower dissociation energy than the second stabilizing liquid and a higher dissociation energy than water. 3. The method of claim 1, wherein the first stabilizing liquid flows from the cathode to the anode and the second stabilizing liquid flows from the anode to the cathode. 4 The first stabilizing liquid is 37 to 93% by weight.
2. The method of claim 1, comprising chemically bonded carbon. 5 The first stabilizing liquid is 25 to 80% by weight.
of chemically bonded carbon and 20 to 20% by weight
2. The method of claim 1 comprising 25% chemically bound nitrogen. 6 The first stabilizing liquid is 50 to 93% by weight.
of chemically bound carbon, and the second stabilizing liquid comprises 25 to 80% by weight of chemically bound carbon and 10 to 25% by weight of chemically bound nitrogen. A method according to claim 1.