RU2052905C1 - Switching-and-pressing gear for direct graphitization furnaces - Google Patents

Abstract

FIELD: electrical engineering. SUBSTANCE: switching-and-pressing gear for direct graphitization furnaces has mobile contacts, current lead, main drive. One of mobile contacts is manufactured from two parts: conductive and electrically insulated. Conductive part of mobile contact is coupled to second mobile contact with the aid of mentioned current lead and electrically insulated part is fitted with additional drive which is integrated with main one. It leads to maintenance of longitudinal pressure of graphite rod (current lead) after completion of heating process and during cooling which is kept thanks to immobility of electrically insulated contact with gear being disconnected from network. EFFECT: reduced graphitization time and enhanced productivity of furnace. 2 cl, 2 dwg

Description

 The invention relates to electrical equipment, and in particular to devices of direct and alternating current, mainly multi-ampere.

 Known switching-clamping units, which are widely used for closing and opening various conductors, which is carried out using one or more conductive bodies of one form or another, for example in the form of flat plates, driven by various mechanisms: hydraulic, mechanical, etc. for contact pressure and pressure on the current collector, for example on a granite rod (candle) of a direct graphitization furnace.

 The closest in technical essence to the claimed one is a switching-clamping unit for direct graphitization furnaces (a proposal for two multi-ampere input carts for installing graphite electrodes in columns according to the Castner method, containing movable contacts in the form of flat plates, driven by a hydraulic actuator, and a current conductor connecting movable plates between themselves, and the hydraulic actuator moves the contacts of the plates to turn on the graphitization furnace in the network, disconnects from the network, creates contact pressure for increasing the conductivity in the contacts and creating a variable force on the graphite rod (candle) of the furnace.

 The drive of the unit moves the contact plates compressing the graphite rod between the network contacts, at the same time an electric circuit is formed: network contact contacts and current leads of the units graphite rod (current collector) network contact. A high amperage current is passed through the circuit to heat the graphite rod. At the end of heating, the high-ampere current is turned off and the graphite rod located under it and connected to the network is cooled.

 This design of the unit and contacts does not provide disconnection of the graphitization furnace from the network while maintaining pressure on the graphite rod of the furnace after disconnecting the high-ampere current and cooling the graphite rod.

 The aim of the invention is the provision of disconnection of the graphite rod from the network while maintaining longitudinal pressure on the rod from the unit.

 The goal is achieved in that in an assembly containing movable contacts connecting their current lead and a drive interacting with each of the movable contacts, one of the movable contacts is made of two parts: electrically conductive and electrically insulating, while using the current lead to the second movable contact, an electrically conductive part of the contact, and the insulating part is equipped with an additional drive. In addition, an additional drive is combined with the main one.

 Figure 1 shows the unit in the off position; in Fig.2 the same as in Fig.1, when the graphite rod and unit are disconnected from the network and the pressure applied to the graphite rod (current collector).

 The unit contains an electrically conductive part 1, an electrical insulating part 2 connected to an additional drive 3, which is integrated in the drive 4. A flat contact 5 is connected to the electric drive contact 1 by means of a flexible electrical connection. The conductive contact 1 when turned on, contacts the network contact 6 through a graphite rod 7.

 The unit operates as follows.

 When a fluid creates pressure in the drive cavity A (cylinder and piston), contact 5 moves to the right, and the cylinder with the contact along the guides moves to the left, while contact 2 and the piston of the additional drive 3 move together with the cylinder, there is no pressure in the cavity B. Contacts 5 and 1 are displaced into the graphite rod 7 and network contact 6. They increase the pressure in the cavity A and create a longitudinal force on the graphite rod and contact pressing.

 On the high voltage side, the current through the mains contact, the conductive parts of the unit, the graphite rod and the mains contact equal to 100 kA at a voltage of 180 V are switched on to the step-down transformer. The graphite rod heats up, lengthens, moving contact 5 with the piston 4 to the left, increasing the pressure in cavity A To maintain a given longitudinal pressure and contact pressure, part of the liquid from cavity A is discarded.

 After turning off the current in the cavity B of the additional drive (cylinder and piston 3), create a pressure by supplying liquid, while reducing the pressure in the cavity A, the insulating contact 2 is pressed against the network contact 6, and the cylinder with the conductive contact 1 moves to the right until it stops in the piston 4, creating visible gap between the conductive contact 1 and the network contact 6, i.e. disconnected from the network (figure 2), while the contact 5 remains pressed against the graphite rod, since the reduced pressure in the cavity A remains, creating, together with the pressure in the cavity B, a longitudinal force on the graphite rod.

 When cooling for 4 hours, the rod is shortened, but the longitudinal force on it is supported by a constant supply of fluid into cavity A and movement of contact 6 by piston 4.

 Thus, the electrical insulating contact 2 with an additional drive, illuminated with the main one, allows you to disconnect the unit with the furnace from the network while maintaining longitudinal pressure on the graphite rod and at the same time include other graphitization furnaces in the same network, ensuring continuous production.

 In addition, combining the additional drive with the main one allows you to reduce the number of high-pressure hydraulic cylinders and hydraulic equipment to a minimum, which simplifies control and reduces the cost of the unit, and their coaxial arrangement eliminates the appearance of overturning moments in the event of failures in the hydraulic system, inaccuracies in manufacturing and installation, and no additional mechanisms for fastening are required unit when creating a longitudinal force on a graphite rod.

Claims (2)

 1. COMMUTATION AND PRESSING MACHINE FOR DIRECT GRAVITY FURNACES, containing movable contacts, connecting their conductors and a drive interacting with each of the movable contacts, characterized in that one of the movable contacts is made of two parts: electrically conductive and electrical insulating, using The conductive part of the contact is connected to the current lead with a second movable contact, and the electrical insulating part is equipped with an additional drive.  2. The unit according to claim 1, characterized in that the additional drive is combined with the main drive.

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