JPH0376714B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Technical Field of the Invention The present invention relates to a transformer polarity determining device that easily and quickly determines the polarity of a transformer.

Prior Art and Problems In pulse transformers, switching power supply transformers, etc., it is necessary to determine the polarity of the transformer before making connections. The polarity of a transformer corresponds to the winding direction, but the polarity of a transformer that has already been manufactured must be determined by some means. Therefore, as a conventional means for determining the polarity of a transformer, for example, as shown in FIG. Connect to the phenomenon oscilloscope 2 and check the transformer T to be measured.
By connecting terminals c and d of the secondary side of the transformer to the two-phenomenon oscilloscope 2 and displaying the waveforms of the primary and secondary sides of the transformer under test on the two-phenomenon oscilloscope 2 simultaneously, the positive polarity can be determined. It is possible to determine whether the polarity is the opposite polarity. However, the polarity determination means using the oscilloscope 2 in this way is
There are cases where the phase of the primary side waveform and the secondary side waveform is significantly different, and in such cases, accurate polarity determination cannot be made by observing the displayed waveform. However, the disadvantage was that it took a long time to determine the polarity.

In addition, as shown in Fig. 2 a, the transformer to be measured T
Connect the primary side terminal b and the secondary side terminal d,
The inductance L ₁ between terminals A and B when primary side terminal a is connected to terminal A and secondary side terminal c is connected to terminal B is as shown in Figure 2 b. When terminal b is connected to terminal c on the secondary side, terminal a on the primary side is connected to terminal C, and terminal d on the secondary side is connected to terminal D, the inductance L ₂ between terminals C and D is By comparing the magnitudes of , the polarity of the transformer T to be measured can be determined. That is, what is the inductance L ₁ between terminals A and B when connected as shown in Figure 2 a, and the inductance L ₂ between terminals C and D when connected as shown in Figure 2 b? , L ₁ <L ₂ , the polarity of the transformer T to be measured can be determined by inductance measurement. However, it has the disadvantage that it takes a lot of time to switch connections between terminals and measure inductance.

In addition, a voltage is applied to the primary winding, the polarity of the voltage induced in the secondary winding is discriminated by a discrimination circuit consisting of a diode, and the discrimination output is added to a monostable multivibrator and held, and the output is used to generate a lamp, etc. A polarity discriminating device is known that discriminates the polarity by lighting up (see, for example, Japanese Utility Model Publication No. 49-5015). However, if the winding ratio as well as the polarity of the secondary winding are unknown, the induced voltage in the secondary winding may be too high and damage the discrimination circuit, etc.; may be so low that the monostable multivibrator cannot operate. In either case, there was a drawback that polarity could not be determined.

OBJECT OF THE INVENTION An object of the present invention is to easily and quickly determine the polarity of a transformer even when the winding ratio is unknown.

Configuration of the Invention The transformer polarity determining device of the present invention includes a pulse generator for applying a pulse to the primary side of the transformer;
A series circuit consisting of a resistor that applies a pulse voltage generated on the secondary side of this transformer and a bidirectional Zener diode, an operational amplifier that amplifies the voltage across the bidirectional Zener diode, and the positive and negative polarity of the output signal of this operational amplifier. It is equipped with a polarity discrimination circuit that discriminates the polarity discrimination circuit, and a latch circuit that latches the discrimination output signal of the polarity discrimination circuit, making it possible to discriminate the polarity of the transformer even with a single pulse. Examples will be described in detail below.

Embodiment of the invention FIG. 3 is a block diagram of an embodiment of the invention.
10 is a pulse generator, 11 is a polarity discrimination circuit for determining the positive or negative polarity of the pulse voltage induced on the secondary side of the transformer T to be measured, 12 is a latch circuit, and 13 is an output terminal. The pulse generator 10 outputs a pulse of a predetermined polarity, applies the output pulse to the primary side of the transformer T to be measured, and the pulse voltage induced on the secondary side is discriminated by the polarity discrimination circuit 11, and the discrimination result is latched. The latch is latched in the circuit 12, and the latch output is outputted from the output terminal 13 as a polarity determination output signal. For example, if it is determined that a positive pulse voltage is induced on the secondary side when a positive pulse is applied to the primary side of the transformer under test T, then the It is assumed that the connection state with the secondary side is of positive polarity, and when it is determined that a pulse voltage of negative polarity is induced on the secondary side, it is determined that the connection state is negative polarity.

FIG. 4 shows an example of a specific configuration of the polarity discrimination circuit 11 and the latch circuit 12 in FIG. , CMP2 and comparison reference voltages Vr1, Vr2 and bidirectional Zener diode
The latch circuit 12 consists of flip-flops FF1 and FF2, a resistor R6, and a reset switch SW. Further, 13A and 13B are output terminals for determining polarity, and +V _CC is a power supply voltage.

Before starting the polarity determination, the reset switch SW is turned on and a signal of "1" is applied to the reset terminals R of the flip-flops FF1 and FF2 to reset the flip-flops FF1 and FF2. That is, the latch circuit 12 is reset. Next, a pulse is applied from the pulse generator 10 to the primary side terminals a and b so that the primary side terminal a of the transformer to be measured T has, for example, positive polarity. In the illustrated connection state, a pulse is induced in the terminals c and d on the secondary side, with the terminal c having a positive polarity. This induced pulse voltage on the secondary side is generated by resistor R1 and bidirectional Zener diode.
BZ is added to the series circuit, and the terminal voltage of the bidirectional Zener diode BZ is applied to the operational amplifier OPA through the resistor R2.
added via .

Bidirectional Zener diode BZ is for protection,
This is to prevent the operational amplifier OPA from being damaged even if a large secondary side induced voltage occurs because the turns ratio between the primary side and the secondary side of the transformer T to be measured is unknown. Further, the operational amplifier OPA is used to amplify the voltage so that polarity can be determined even when the induced voltage on the secondary side is low. Therefore, the transformer under test T
If the winding ratio etc. of the winding ratio are known in advance and the polarity of the ratio measuring transformer T having the same winding ratio is always determined, it is possible to omit the bidirectional Zener diode BZ and the operational amplifier OPA.

The output signal of the operational amplifier OPA is sent to the comparator CMP
1, added to CMP2, comparison reference voltage Vr1, Vr
It is compared with 2. When a positive pulse voltage is induced, the output of comparator CMP2 becomes "1",
Flip-flop FF2 via AND circuit A2
The flip-flop FF2 is set and its terminal Q becomes "1". Also, since flip-flop FF1 is not set, its terminal Q remains at "0". Therefore, since the output terminal 13A becomes "0" and the output terminal 13B becomes "1", it is determined that the transformer T to be measured is in a positive polarity connection state.

Also, when flip-flop FF2 is set,
Since that terminal becomes "0", AND circuit A1
The output signal of comparator CMP1 is “1”
Even if it becomes, it remains at "0" and flip-flop FF1 is never set. That is, once the polarity is determined using the first pulse voltage, the AND circuits A1 and A2 regulate the setting operations of flip-flops FF1 and FF2 so that they do not malfunction even if a pulse voltage such as noise is applied. .

As mentioned above, it is possible to determine the polarity of the transformer under test T with a single pulse, but by applying multiple pulses of the same polarity to the primary side of the transformer under test T, a pulse induced on the secondary side of the transformer under test T can be applied. It is also possible to configure the polarity determination circuit 11 and the latch circuit 12 to determine the polarity of the voltage multiple times and output the polarity determination result if all the determination results are the same or by a majority vote of the determination results. be. Even when polarity determination is performed by applying a plurality of pulses in this manner, the pulse period can be shortened, so polarity determination can be performed in a short time.

Effects of the Invention As explained above, the present invention provides a pulse generator 10 for applying pulses to the primary side of the transformer T.
, a resistor R1 that applies the pulse voltage generated on the secondary side of the transformer T, and a bidirectional Zener diode BZ.
This bidirectional Zener diode in series circuit with
an operational amplifier OPA that amplifies the voltage across BZ;
It is equipped with a polarity discrimination circuit 11 and a latch circuit 12, and since the polarity of the transformer T can be discriminated with a single pulse from the pulse generator 10, the polarity discrimination can be executed in a short time. Furthermore, polarity can be easily determined without being affected by the phase relationship of the induced voltage on the secondary side.

Also, if the induced voltage on the secondary side is too high because the turns ratio of the transformer T is unknown, it is reduced by a series circuit of resistor R1 and bidirectional Zener diode BZ to protect the operational amplifier OPA. be able to. Furthermore, if the induced voltage on the secondary side is too low, it can be amplified by the operational amplifier OPA, which has the advantage that the polarity discrimination circuit 11 can reliably discriminate between positive and negative polarities.

[Brief explanation of drawings]

Figures 1 and 2 a and b are explanatory diagrams of conventional transformer polarity determination, Figure 3 is a block diagram of an embodiment of the present invention, and Figure 4 is a detailed circuit diagram of an embodiment of the present invention. . T is the transformer to be measured, a and b are the primary side terminals,
c, d are secondary side terminals, 10 is a pulse generator, 11
12 is a latch circuit, 13 is an output terminal, OPA is an operational amplifier, CMP1 and CMP2 are comparators, SW is a reset switch, and FF1 and FF2 are flip-flops.

Claims (1)

[Claims] 1. A pulse generator for applying pulses to the primary side of the transformer, a series circuit of a resistor and a bidirectional Zener diode for applying the pulse voltage generated to the secondary side of the transformer, and both ends of the bidirectional Zener diode. A transformer comprising: an operational amplifier that amplifies a voltage; a polarity discrimination circuit that discriminates between positive and negative polarity of an output signal of the operational amplifier; and a latch circuit that latches a discrimination output signal of the polarity discrimination circuit. Polarity discrimination device.