RU2042287C1 - Device for processing products in vacuum - Google Patents

Abstract

FIELD: electric engineering. SUBSTANCE: heater of vacuum chamber 1 has vacuum-arc discharge integral cold electrode 3 and anode 8 which are connected to power supply. In addition heater has tube which is made from non-conducting material which is resistant to heat and unit 5 which does not pass through metal ions. Anode 8 is located in chamber of tube setting piece 7, unit 5 is located between non- attached end of tube and cathode 3. Ratio of cross-sections of setting tube piece 7, tube working piece 6 and working surface of anode is given in invention specification. EFFECT: increased functional capabilities. 1 dwg

Description

 The invention relates to the field of processing products in vacuum, in particular, can be used for vacuum firing of products in a reactive gas medium, as well as for carrying out the process of chemical-thermal treatment.

In metallurgical processes during the vacuum melting of metals, devices (furnaces) are widely used, in which a vacuum arc discharge is used. In these furnaces, a molten metal is used as a cathode, and the anode is a cooled crucible into which the molten metal flows. A vacuum-arc discharge is excited between a cathode and an anode in a vacuum, in which ionized metal vapors are a medium conducting electric current in the interelectrode gap [1]
A disadvantage of the known furnaces is that, as a rule, they operate at currents of hundreds and thousands of amperes. In this regard, the resistance of the plasma column decreases proportionally with increasing current. Therefore, the power released in the discharge is proportional to the discharge current. Thus, in order to increase the power of the furnace, it is necessary to increase the discharge current, which complicates the design of the furnace due to the large cross section of the current-supply circuits.

The closest to the invention in technical essence and the achieved result is a device for processing products in a vacuum (vacuum oven), heated by the Joule heat generated during the passage of electric current through a conductor of refractory metal (W, Mo, Ta, Nb) [2]
The disadvantages of such a device include the high cost and scarcity of heaters made of refractory metals, the gradual destruction of the material of the heater due to reactions of the metal at high temperature with a residual gas atmosphere or reactive gas medium, if any, and serves to carry out the necessary technological process. These reasons increase operating costs.

 The purpose of the invention is to increase the reliability and durability of the heating device mainly when it is operating in a reactive gas environment.

 A comparative analysis showed that the proposed technical solution in comparison with those known in science and technology meets the criteria of patentability, since the totality of the claimed features reflected in the claims is not found in this and related fields of science and technology to solve the problem. It should also be noted that the achieved result can be realized only by the totality of the characteristics declared in the formula, since the specified result is not a simple summation of the properties of individual signs, since it does not appear when using either of them separately in known solutions, and also cannot be achieved when removing any of the signs from the total set of signs.

 The drawing shows a device for processing products in a vacuum, a longitudinal section.

 The device comprises a vacuum chamber 1, in which workpieces 2 are installed on the periphery. A heater is installed along the axis of the vacuum chamber 1, which consists of an integral cold cathode 3 of a vacuum arc discharge isolated from the vacuum chamber 1 by an insulator 4, means 5 impermeable to metal ions pipes made of heat-insulating heat-insulating material with a working section 6 and an installation section 7 and an anode 8. A means 5 is installed between the cathode 3 and the working section 6 of the pipe. An anode 8 is installed in the cavity of the installation section 7 of the pipe.

 The cross-sectional area of the installation section 7 of the pipe, as well as the area of the working surface of the anode 8 is greater than the cross-sectional area of the working section 6 of the pipe.

 The supply of working gas to the vacuum chamber 1 is made through the means 9 into the cavity of the installation section 7 of the pipe. The heater is powered by a power supply consisting of a direct current power source 10, an adjusting power source 11, a diode 12. The vacuum-arc discharge current is stabilized by a power source 13, the open circuit voltage of which is about 2-2.5 times higher than the voltage at the electrodes discharge.

 The drawing also shows a positive column 14 of a metal-gas plasma and a column 15 of a gas plasma. The vacuum chamber is pumped out through the pipe 16.

 A device for processing products in a vacuum as follows.

 The vacuum chamber 1 is pumped out by a pumping system through the pipe 16 and then, using the means 9, the working gas is supplied to the cavity of the pipe and the vacuum chamber 1. A vacuum-arc discharge is ignited between the cathode 3 and the vacuum chamber 1. The volume of the vacuum chamber enclosed between the cathode 3 and the means 5, impervious to metal ions, filled with metal-gas plasma.

 Then the stabilizing source 13 is turned on. In this case, a discharge is excited inside the tube between the cathode 3 and the anode 8. The discharge current from the source 13 is small and does not exceed 2-3A. Since the tool 5 is impervious to metal ions propagating along straight trajectories from the surface of the cathode, under the influence of the electric field of the anode, gas inside the tube is ionized, and the inner space of the tube is filled only with gas plasma.

 When the power supply 11 is turned on, the main discharge current passes through the pipe, the value of which can reach several hundred amperes at a voltage of 100-380 V. Sources 11 and 13 of the power supply can be adjustable rectifiers (you can use an adjustable three-phase thyristor rectifier). The presence of a stabilizing source 13 allows for deep adjustment of the discharge current.

 Consider the energy balance in the heater. The electric energy supplied to the heater is distributed between the I and II stages of a two-stage vacuum-arc discharge.

The energy loss P ₁ in the first stage of the discharge is constant in absolute value and equal to P ₁ = I _p ˙ U _{1 st} . U _1st is a constant value determined by the cathode material. As a rule, U _1st = 20 V.

 In the second (gas) stage of the discharge, the energy is distributed as follows. Part of the energy spent on ionizing the gas inside the means 5, impermeable to metal ions, another part is spent at the surface of the anode and transferred to it in the so-called anode potential drop. The value of the anode potential drop in the positive plasma column is determined by the area of the anode.

 To reduce the anode potential drop, the anode area should be larger than the cross-sectional area of the pipe. Therefore, the cross-sectional area of the installation section of the pipe, as well as the area of the anode are selected larger than the cross-sectional area of the pipe.

 Determination of the operability of the heating device was carried out on the model. A quartz tube with a diameter of 40 mm and a length of 1 m was installed in the vacuum chamber. The installation diameter of the pipe was 100 mm, and the diameter of the cooled anode was 80 mm. The voltage at the heater electrodes was 240 V, the heater current was 100 A. The stabilizing source had a voltage of 450 V, and the current strength was 1 A. The current was regulated by a thyristor current regulator in the range of 30-100 A. Calorimetry determined the useful power of the heater. She was 65-70%

Claims (1)

 DEVICE FOR PROCESSING PRODUCTS IN VACUUM, containing a vacuum chamber and a heater located inside the chamber with power supply, characterized in that it is equipped with a working gas supply means, the heater comprises an integrated cold cathode of a vacuum arc discharge, an anode mounted on the chamber the end located on the anode side of the pipe from a heat-resistant electrical insulation material with working and installation sections and a means not permeable to metal ions, located Noe between the cathode and the loose end of the tube, an anode is placed in the cavity of the mounting portion of the pipe disposed on the part of the fixed end of the latter, wherein the cross sectional area of the mounting portion of the pipe, and a working surface area of the anode over the cross sectional area of the working portion of the pipe.