RU31177U1 - DC disconnect device with a non-polarized high-current contact device - Google Patents

Description

2003107735

“MRIIRRISHCH IPC burden 33/62

DC disconnect device with a non-polarized high-current contact device.

The utility model relates to electrical engineering, namely to switching devices, in particular, to high-current devices and is designed to turn off both large and low currents, for example, for switches protecting the electrical equipment of urban electric vehicles.

DC disconnect devices are known from the following sources.

In the source of O.B. Bron, “Electric arc in control devices. State Energy Publishing House, 1954, pp. 214-222, two devices are described. The first contains a pole having a breakable contact, an arcing chamber and a coil, through which the current of the switched circuit flows. The second device is characterized in that instead of the coil through which the current of the switched circuit flows, it contains a coil connected to the full voltage of the circuit. The first device can be used to turn off current in circuits where the direction of current flow changes, but it is not effective enough when low currents are turned off. The second device is more effective when disconnecting low currents, but is applicable only in circuits where the direction of current flow does not change.

The closest analogue to the patented device can be considered a DC disconnect device with a non-polarized high-current contact device by source A.A. Chunikhin “Electric devices. General course. Textbook for high schools. - 3rd ed., Revised. and add. - M .: Energoatomizdat, 1988., pp. 313 - 317. This device contains one pair of series-connected poles, each of which has an openable

contact, the arcing chamber and the coil through which the current of the switched circuit flows, creating a magnetic field designed to move the arc into the arcing chamber.

The disadvantage of this device is the long arc extinction when disconnecting low currents. Moreover, with certain parameters of the circuit, stable burning of the arc between the contacts is possible. This is explained by the fact that, at a low value of the current of the switched circuit, the magnetic field acting on the arc to move it into the arcing chamber also has a small value.

The utility model is aimed at solving the problem of increasing the reliability of disconnecting direct current with an unpolarized high-current contact device.

The technical result that is achieved by the patented device is that it turns off both large and low currents with an unpolarized high-current contact device.

This is ensured by the fact that the device additionally contains one or more coils or one or more permanent magnets to create an additional magnetic field, the direction of which in one of the poles coincides with the direction of the magnetic field created by the current of the switched circuit, and in the other pole is directed counter to the magnetic field, created by the current of the switched circuit.

The presence of an additional coil or several coils or permanent magnets in one of the poles creates an increase in the magnetic field acting on the arc to move it into the arcing chamber, when current flows in any direction.

A high-current contact device contains one pair of series-connected poles. The first pole has a breakable contact 1, an arcing chamber (not shown in Fig.), A coil 2 through which the current of the switched circuit flows, and a coil 3. The second pole has a breakable contact 4, an arcing chamber (not shown in Fig.), A coil 5 along which the current of the switched circuit flows, and coil 6. Coils 3 and 6 are connected to the power source so that the magnetic field created by them in one pole coincides with the magnetic field created by the current of the switched circuit, and in the other pole is directed opposite to the magnetic field , from Switched current circuits zdaval. Coils 3 and 6 can be connected to the same power source as the switched circuit, or to an independent power source, as shown in FIG. Instead of two coils 3 and 6, one coil can be used that creates an additional magnetic field, the direction of which at one of the poles coincides with the direction of the magnetic field created by the current of the switched circuit, and in the other pole it is directed counter to the magnetic field created by the current of the switched circuit.

Instead of coils, one or more permanent magnets can be used to create an additional magnetic field.

The device serves to disconnect the variable load 7.

When direct current flows in any direction, coils 2 and 5 create a magnetic field designed to move the arcs into the arcing chambers. Coils 3 and 6 create an additional magnetic field, which in one of the poles, for example, in the first, coincides with the magnetic field created by the current of the switched circuit. In this case, when the contacts of both poles are opened in the first pole, a stronger effect will be created on the formed arc to move it into the arcing chamber. Therefore, the arc moves into the arcing chamber of this pole even at low currents. At low currents, shutdown is ensured by the rapid quenching of the arc in the arcing chamber of one pole. At high currents, the magnitude of the additional magnetic field is small compared to the magnetic field generated by the current of the switched circuit, therefore, the large current is switched off by mixing the arcs formed in the arcing chambers of both poles with the magnetic field created by the current of the switched circuit.

When the direction of flow of the direct current changes, the additional magnetic field coincides in direction with the magnetic field created by the current of the switched circuit in the second pole, where these fields were met at a different polarity. When the contacts of both poles are opened in the second pole, a stronger effect will be created on the formed arc to mix it into the arcing chamber, which ensures disconnection of low currents due to the rapid quenching of the arc in the arcing chamber of the second pole. Disconnection of large currents occurs similarly to the above.

From the dry land of the utility model it is clear that for the implementation of the device not one but several pairs of poles can be used.

Thus, due to the additional magnetic blast, reliable shutdown of both large and small currents by one device is ensured when currents flow in any direction.

Claims (1)

A DC disconnect device with a non-polarized high-current contact device, containing at least one pair of series-connected poles, each of which has a breakable contact, an arcing chamber and a coil through which a switched circuit current flows, creating a magnetic field designed to move the arc into the arrester camera, characterized in that it further comprises one or more coils or one or more permanent magnets to create additional magnetically field, the direction of which in one of the poles coincides with the direction of the magnetic field created by the current of the switched circuit, and in the other pole is directed counter to the magnetic field created by the current of the switched circuit.