JPS63151004A - Electromagnet device - Google Patents

Abstract

PURPOSE:To make the making current of a contact point of a change-over switch nearly equal to zero, and prevent contact point transfer of the change- over switch, by connecting in series the change-over switch, a second resistor, and the light emitting diode of a photocoupler, between the DC output terminals of a full-wave rectifier, and connecting the phototriac of a photocoupler in parallel with a first condenser and a first resistor. CONSTITUTION:A change-over switch 8, which acts linking to the operation of a moving-iron core 10, opens just before the moving-iron core in attracted to the fixed-iron core, and cuts off a current flowing toward a light emitting diode 13. Then the change-over switch 8 opens, the current flowing through the change-over switch 8 is limited to a very small value by a second resistor 11. The current flowing through the change-over switch 8 is limited by the resistor 11, and the contact cut-off current at the time of opening instance of the change-over switch 9 is very small. The change-over switch 8 closes after the energy of a electromagnetic coil 2 is discharged by a flywheel circuit composed of a full-wave rectifier 1 and a transistor 3, so that the current becomes nearly equal to zero, and contact point transfer of the change-over switch can be prevented.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to an electromagnetic device used for example in an electromagnetic contactor, and in particular to an improvement in the performance of an electromagnetic device.

[Conventional technology]

FIG. 4 shows the conventional ! It is a circuit diagram showing a magnet device, and in the figure (1
) is a full-wave rectifier that converts AC voltage input from an AC power source (not shown) into DC voltage, (2) is a 1i magnetic coil whose one end is connected to one of the DC output terminals of the full-wave rectifier (1), and (3
) is a transistor in which the electromagnetic coil (2), collector, and emitter are connected in series, and (4) has one end connected to the base of the transistor (3), and the other end connected to the 1i magnetic coil (2) and a full-wave rectifier ( 1) Bias resistor connected to the connection end of (
5) is a capacitor connected between the base and collector of the transistor (3).

(6) is the first capacitor connected in series to the AC side of the full-wave rectifier (1) to limit the current flowing to the electromagnetic coil (2), and (7) is the first capacitor connected in series with the first capacitor (6). The connected first resistor (8) is a delay-operated changeover switch connected in parallel to the series-connected first capacitor (6) and first resistor (7).

When an AC voltage is applied to the electromagnetic device configured as above, a bias voltage is applied to the base of the transistor (3) from the bias resistor (4) via the changeover switch (8) and the full-wave rectifier (1). It will be done. This bias voltage causes a base current to flow through the transistor (3), causing conduction between the collector and emitter of the transistor (3)! Direct current is passed through the magnetic coil (2), and the fixed iron core (9) is installed through the magnetic coil (2) as shown in Figure 5.
is excited, and the movable iron core (10) is attracted to the fixed iron core (9).

The changeover switch (8) is interlocked with the movable core (lO), and the contact is opened just before the movable core (10) is attracted to the fixed core (9), and after the contact of this changeover switch (5) is opened, w A voltage reduced by a capacitor (3) is applied to the magnetic coil (2), and a limited holding current flows therethrough.

Note that even when the changeover switch (8) is held after the contact is opened, the base current (2) of the transistor (3) flows as shown in FIG. 6(E), and current flows between the collector and emitter. Figure 6 shows the collector-emitter voltage, collector current, voltage and current of the capacitor (5), base current, and current flowing through the bias resistor (4) until the movable iron core (10) is attracted, passes through the holding state, and is released. FIG. 4 is a characteristic diagram showing changes over time.

By the above operation, when the movable iron core (!0) is attracted, a large current is passed through the electromagnetic coil (2) to obtain an attractive force, and the movable iron core (!0) is attracted.
When holding 1O), the current flowing through the electromagnetic coil (2) is restricted to reduce power consumption during holding.

Next, when the external switch (not shown) is turned off and opened, the capacitor (5) begins to be charged by the energy of the electromagnetic coil (2), and the transistor (3), full-wave rectifier (1), and electromagnetic coil (2) Current attenuation begins due to the flywheel effect, and the movable core (10) is released from the fixed core (9) by the reaction force of a trip spring (not shown).

By releasing this movable iron core (10), the changeover switch (8)
contacts are closed. This contact is closed with residual charge remaining in the first capacitor (6), and a large discharge current (ii) flows, but the first resistor (7) suppresses this discharge current (12).

(Problems to be solved by the invention) In the conventional electromagnet device as described above, the movable iron core (
10) When the changeover switch (8) is opened during suction, the first capacitor (6) and the first resistor (7) form an arcless circuit for the contacts of the changeover switch (8). In order to further improve the effect, if the resistance value of the first resistor (7) is made small, the discharge from the first capacitor (6) when the changeover switch (8) is opened when releasing the movable core (10) is reduced. The current (i-) increases, and transition of the contacts of the changeover switch (8) becomes more likely. Therefore, if the electromagnet device is operated repeatedly, the changeover switch (
When the wear of the contacts of 8) becomes large and exceeds the contact wear limit, the contacts of the changeover switch (8) will become welded.As a result, a large current will continuously flow through the electromagnetic coil (2) during attraction! There is a problem that the magnetic coil (2) may be burnt out.

In addition, if a tritic is used as an external switch to attract and release an electromagnetic device, if the gate signal of the tritic is turned off to release the electromagnetic device, the tritic will always be cut off at the zero point of the AC voltage (E). be done. However, since the impedance of the first capacitor (6) is large, the first capacitor (6) and the first resistor (7)
) The voltage and current of the circuit have a phase difference of about 90 degrees, and each time the external switch tritic is cut off, the selector switch (8) changes the peak current I□-rE as shown in Figure 7. The circuit is closed at /R. For this reason, contact transition of the changeover switch (8) is likely to occur, causing contact welding as described above and making it impossible to open mechanically, which may lead to burnout of the electromagnetic coil (2).

This invention was made to solve these problems! The purpose of the present invention is to prevent welding of changeover switch contacts of a magnet device and to obtain an electromagnet device with a long life and high performance.

[Means for solving problems]

The electromagnetic device according to the present invention connects an electromagnetic coil, a collector, and an emitter of a transistor in series on the DC output side of an aftereffect rectifier, and uses a delay-type changeover switch to change the current and holding current when the movable core is attracted, and when releasing the electromagnetic core. In an AC-operated DC-excited electromagnet device configured to cut off DC from a coil by a transistor, a delay-type changeover switch, a second Connect the resistor and photocoupler light emitting diode in series,
It is characterized in that a phototriac of a photocoupler is connected in parallel with a first capacitor and a first resistor that are connected in series to the alternating current side of a full-wave rectifier.

[For production]

In this invention, the current flowing through the changeover switch is
The contact breaking current when the changeover switch is opened is suppressed by the resistance of It becomes almost zero and prevents contact transfer of the changeover switch.

〔Example〕

FIG. 1 is a circuit diagram showing an embodiment of the present invention, and in the figure, (1) to (7) are completely the same as the conventional example shown in FIG. 4 above. (8) is a delay operation type changeover switch, (11) is a second resistor, (12) is a photocoupler, (13) is a light emitting diode of the photocoupler (12),
(14) is a phototriac of a photocoupler (12), and a changeover switch (8), a second resistor (11), and a light emitting diode (13) are connected between the DC output terminals of the full-wave rectifier (1). connected in series. Photo coupler (12
) is connected in parallel with a first capacitor (6) and a first resistor (4) connected in series to the AC side of the full-wave rectifier (1). In addition, (15
) is a protective triac.

In the electromagnet device configured as described above, when an external switch (not shown) is closed, an alternating current flows from the alternating current power supply through the first capacitor (6) and the first resistor (4) to the alternating current side of the full-wave rectifier (1). When a voltage is applied, a base current flows from the DC output side of the full-wave rectifier (1) to the base of the transistor (3) via the bias resistor (4).
The light-emitting diode (13) conducts current between the collector and emitter of the photocoupler (12) through the second resistor (11) and the changeover switch (8). emits an optical signal, and sends the optical signal to the phototriac (14). When the phototritic receives an optical signal, it becomes conductive and short-circuits the first capacitor (6) and the first resistor (7).

Therefore, the full voltage is applied to the full-wave rectifier (1) via the phototriac (14), and a large attraction current flows through the electromagnetic coil (2), causing the fixed iron core (9) shown in FIG.
is excited and attracts the movable iron core (10). A changeover switch (8) that operates in conjunction with the operation of this movable iron core (10)
The current flowing through the changeover switch (8) where the movable iron core (10) is attracted to the fixed iron core (9) is a minute current that is limited by the second resistor (11).

When the current flowing through the light emitting diode (13) is cut off, the phototriac (14) also becomes an open circuit state, and the voltage reduced by the first capacitor (6) is applied to the full-wave rectifier (1), and the iam Let the current flowing through the coil (2) be a small holding current.

Next, when the external switch is turned off and released, the capacitor (
5) starts to be charged, the base current of the transistor (3) decreases, the collector-emitter voltage increases, the collector current also decreases, and the movable iron core (10 ) in a short time (9)
Free from. When the moving iron core (lO) begins to be released,
The changeover switch (8) becomes closed. At this time, since the current flowing through the changeover switch (8) is almost zero, occurrence of contact transition of the changeover switch (8) is prevented.

In the above embodiment, the case where the phototritic (13) of the photocoupler (12) was directly connected to the AC side of the full-wave rectifier (1) was explained, but as shown in FIG. 6) and the first resistor (7), connect the output triac (16) in parallel with the output dry tick (
A large suction force is required by controlling the gate of 16) with a phototriac (14)! Magnetic coil (2
) can pass the required attraction current. In FIG. 2, (17) is a resistor for applying a gate signal to the output gate and the gate of the reactor (16).

Furthermore, in each of the above embodiments, phototritic (14)
Although we have explained the case where a photocoupler with a photocoupler having a A similar effect can be achieved.

[Effects of the Invention] As explained above, the present invention suppresses the current flowing when the changeover switch is opened by the second resistor to make it a minute current, and the changeover switch converts the self-energy of the electromagnetic coil into a full-wave rectifier. Since single-point transfer of the flywheel is prevented, the changeover switch contacts will not weld even after repeated operations.
This has the effect of increasing the single-chain nature of the electromagnet device.

In addition, the photocoupler and capacitor controlled by the changeover switch apply full voltage to the electromagnetic coil when attracting, and apply a reduced voltage when holding, so a small changeover switch with small contact capacity can be used to am coil can be operated.

Furthermore, since the electromagnetic coil is cut off by the operation of the transistor, there is an effect that the release time of the movable core can be shortened.

[Brief explanation of the drawing]

Figure 1 is a circuit diagram showing an embodiment of this invention, Figures 2 and 3 are
The figures are circuit diagrams showing other embodiments, Fig. 4 is a circuit diagram showing a conventional example, Fig. 5 is a schematic configuration diagram of an electromagnet device, and Fig. 6 is a diagram of operating characteristics of a transistor used in the electromagnet device. ,
FIG. 7 is a discharge current characteristic diagram of a conventional example. (1)・・・・・・Full wave rectifier, (2)・・・・・・
...Ir! 1 magnetic coil, (3)...
・Transistor, (4)...Bias resistor, (5)...Capacitor, (6)...
......First capacitor, (7)...
...First resistor, (8)...... Selector switch, (11)... Second resistor, (12
)......Photocoupler, (13)...
...Light-emitting diode, (14) ...
・Phototritic, (16)...Output triac, (18)...Photothyristor, (19)...Diode. Note that the same reference numerals in each figure indicate the same or corresponding parts. Agent Patent Attorney Muneharu Sasaki Figure 1 Figure 2 Figure 3 Figure 6

Claims (2)

[Claims] (1) An electromagnetic coil connected to the DC output side of a full-wave rectifier, a transistor connected between the collector and emitter in series with the electromagnetic coil, one end connected to the base of the transistor, and the other end connected to the electromagnetic coil. a bias resistor connected to the connecting end of the full-wave rectifier, a capacitor connected between the base and collector of the transistor, a fixed iron core provided through the electromagnetic coil, and a movable iron core attracted to the fixed iron core. and a changeover switch that is opened after the movable iron core starts suction operation and closed after it starts release operation, and is connected in series to the alternating current side of the full-wave rectifier, and when the changeover switch is opened, the electromagnetic coil is connected. In an AC-operated DC-excited electromagnet device comprising a first capacitor and a first resistor that limit the current flowing, the changeover switch, the second resistor, and a photocoupler are connected between the DC output terminals of the full-wave rectifier. An electromagnet device characterized in that light emitting diodes are connected in series, and a phototriax of the photocoupler is connected in parallel to the first capacitor and the first resistor. (2) The electromagnet device according to claim 1, wherein the photocoupler includes a photothyristor.