SU748748A1 - Method and device for regulating parameters of linear induction pump - Google Patents

Description

 metal in the channel, however, a large number of regulating devices of the temperature condition and the regulator and the control method and device for it. implementation, especially when avtbmaticheskos - ys ryo syme adjustment parameters. p}: to control the same parameters of the pump with the current in only one phase is simpler, but the temperature stability decreases to 30%, which deteriorates the quality of the castings and leads to b1ea1: when using the pump in te erfie of the melt batch when pouring

l Steyne forms, as with malbc

 iff Wjftefiiijasi consumption temperature metal la nd is much lower than the temperature in the furnace.

The aim of the invention is to provide a constant temperature of the liquid Metal in the channel.

This celeb is achieved by increasing the magnetic flux depth in one half of the working zone of the channel located on one side of its longitudinal plane; - Extensible, and at the same time decreasing the other pL Loia, retaining the sunshine value of the work flow; constant. The magnetic flux lines are carried out by local localization 1 a a: tHM of the inductor oirovod in the areas Jtb eHHEix on one side of the continuation of the HCNI axis: symmetry of the channel.

The proposed method can be carried out in flat and cylindrical pumps, characterized by the fact that they additionally contain REMOVAL UNITS placed in closed rods of rods, the magnet of the VDOV magnet on one side of the longitudinal plane of symmetry of the channel.

FIG. 1 shows a flat linear induction pump with a C-shaped cfrd 5m longitudinal

Section 7 1 of FIG. 2 - the same transverse section; in fig. 3, 4 - flat linear induction pump with extension cores, longitudinal and transverse sections.

1 1 The linear induction pump (figs. 1 and 2) contains a traveling electric floor inductor formed by C-shaped ferromagnetic cores 1 with oyiotkami 2 located on their rods 2. A channel is placed in the gap between the core rods. rods x heart “b p n parts yx, located p6 one guard v. ,. the longitudinal section of the bridge: the channel of the Channel, passing through its wide side, is made coaxially closed and 5G in which the 15 and 6 of the magnetic biasing 6 and 7 are placed - Connected to - rGg1tyyrUymbn. niku constant voltage. Each pump can be connected, for example, on the opposite side with a dispensing furnace, and on the other side - with a heated metal pipeline, or heated metal conductors on both sides (in Fig. 1 it is shown with a dotted line).

The flat linear induction pump as shown in FIG. 3 and 4, an inductor of a traveling electromagnetic field, formed by the same and upper and lower cores, in whose open grooves of which the excitation windings 2 of the running floor are laid, will be encased. A channel 3 is located in the air gap between the cores. Each core consists of two packages located opposite sides of the longitudinal symmetry plane of the channel passing through its wide side and installed at some distance from one another. In packages located on one side of the specified. planes, closed grooves 4 and 5 are made, in which bias windings 6 and 7 are located, which are connected to a controlled constant voltage source.

The regulation of the head and the performance of the pump while maintaining the temperature stability of the liquid metal is carried out as follows.

When the windings 2 are connected to a three-phase AC network and there is no current in the bias windings 6 and 7, the pump operates at maximum capacity.

To reduce the head and performance, the bias windings b, 7 pass a constant current, increasing it in the control process to a value that provides deep saturation of the cores 1 in the areas around the slots 4 and 5. As a result of magnetic bias, the magnetic material permeability of the cores decreases in these areas, and consequently, the magnetic flux of the traveling floor in the liquid metal, which is located in the half of the channel, adjacent to the magnetic sections of the cores. At the same time, the magnetic flux in the liquid metal located in the other half of the channel (upper in Fig. 1, 2 and right in Fig. 3, 4) increases by approximately the same value, since at a constant value of the inductor supply voltage, the total value of its Magnetic flow is changed without reference.

Claims (3)

Due to the redistribution of the rforo flux magnet, the force acting on the metal, which is located on one side of the longitudinal axis of symmetry of the channel, decreases by approximately. the same increase on the side. Due to the difference of forces, one half of the channel has a shunting effect on the other, as a result of which the pressure and; Capacity is reduced. By choosing the appropriate length of the slots 4, 5 and the degree of magnetization of the cores, it is possible to achieve zero pump performance. The amount of heat released by the liquid metal of the channel varies slightly during the adjustment process, due to a slight change in the total magnitude of the magnesium flux penetrating the working zone of the channel. This stabilizes the melt perratura in the channel. Stabilization-temperature is also facilitated by the fact that, at low and zero productivity, the metal in the channel, due to the asymmetrical distribution of forces acting on it, moves in a closed loop, moving in opposite directions at opposite edges of the channel (as shown in Fig. 1 is dotted). Such a movement ensures the melt is renewed in the channel with melt from a distributing furnace and a heated metal pipeline, i.e. stabilizes the temperature of the melt.; . Claims 1. Method of adjusting the parameters of a linear induction pump By varying the magnitude of the inductor magnetic pot, characterized in that, in order to ensure po6. 748748, the standing temperature of the liquid metal in the channel, the magnitude of the magnetic flux increases in one half of the working zone of the channel located on one side of its longitudinal plane of symmetry / and simultaneously decreases in the other half, keeping the total value of the working flow constant. 2. The method according to claim 1, characterized in that the asymmetric change in the magnitude of the magnetic flux is accomplished by locally locking the cores of the inductor magnetic core in areas located on one side of the longitudinal plane of symmetry of the channel. 3. Device for implementing the method according to paragraphs. 1 and 2, containing an inductor of a traveling electromagnetic field and a channel located between the rods of the inductor's magnetic cores, which also contains the bias windings placed in the closed grooves of the rods of the magnetic conductors in their sections located on one side of the longitudinal channel symmetry plane. Sources of information taken into account in the examination 1. Verte LA Electromagnetic casting and processing of liquid metal. Metallurgists, 1967, p. 52, 62. 2. USSR author's certificate number 236983, cl. H 02 N 4/20, 1963. 3. Authors certificate of the USSR 275744, cl. H 02 N 4/20, 1966 (prototype).   one | n ||||||| u / rinippts / - tomuimJ Yo 1 111И | ВЙ | f one yyvx v jj yyv jcxyvi  P “G.