KR900001448Y1 - Automatic starting circuit for facsimile - Google Patents

Abstract

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Description

Facsimile Auto Start Circuit

1 is a conventional circuit diagram.

2 is a circuit diagram of the present invention.

* Explanation of symbols for main parts of the drawings

RL ₁ -RL ₃ , RL ₅ -RL ₆ : Relay R ₁ -R ₂ : Resistance

C ₁ -C ₆ : Condenser BD ₁ -BD ₄ : Bridge Diode

T ₁ , T ₂ : Power transformer

RL ₁₁ , RL ₂₁ , RL ₃₁ , RL ₄₁ , RL ₅₁ , RL ₅₂ , RL ₆₁ , RL ₆₂ : Relay switch

The present invention relates to a facsimile auto start circuit, and more particularly, to a facsimile auto start circuit that prevents the facsimile from malfunctioning and similarly reduces power consumption in a standby state.

The conventional facsimile automatic start circuit is configured as shown in FIG. 1 and the relay switches RL ₁₁ , RL ₂₁ , and RL ₃₂ are respectively shorted when the relays RL ₁ , RL ₂ , and RL ₃ are driven. RL ₃₁ is connected to one fixed terminal a ₃₁ of the relay RL ₃ when the relay RL ₃ is driven, and the relay switch RL ₄₁ is short-circuited when a communication end signal is input.

Referring to the operation of the conventional circuit, when a call signal is input through the connection terminal RT of the telephone line, the rectified power through the bridge diode BD ₁ is applied to the relay RL ₁ to drive the relay. The switch RL ₁₁ is short-circuited so that the power of the power supply terminal AC is applied to the primary side T ₁₁ of the power supply transformer T ₁ through the relay switch RL ₁₁ .

Accordingly, the power held on the secondary side T ₁₂ of the power supply transformer T ₁ is rectified through the bridge diode BD ₂ , and then applied to the relay RL ₂ through the relay switch RL ₃₁ and driven. Accordingly, the relay switch RL ₂₁ is connected, so that power from the power supply terminal AC is applied to the power supply transformer T ₁ through the relay switch RL ₁₁ (RL ₂₁ ).

In this state, if the standby state without a signal continues, the relay RL ₁ is not driven, and thus the relay switch RL ₁₁ is opened.

However, since the power is being applied through the relay switch RL ₂₁ , the relay RL ₂ is in a driving state. Accordingly, the relay switch RL ₂₁ is short-circuited and thus the power is continuously supplied.

After the communication type signal is input and the relay switch RL ₁₁ is short-circuited, the power induced in the secondary side T ₁₃ of the power transformer T ₁ is rectified through the bridge diode BD ₃ and then the diode D _1. ) relay (applied to the RL _3), Accordingly, the relay switch (RL ₃₂₎ is short-circuited, and the relay (RL ₂₎ is kept running even immediately after the end of communication signal is lost also relay switch (RL ₃₁ in accordance with its drive) through Is connected to one side of the fixed terminal a ₃₁ so that the charge of the capacitor C ₂ is discharged through the resistor R ₁ and the relay RL ₂ is not driven. Accordingly, the relay switch RL ₂₁ is turned off, so that power from the power terminal AC is cut off.

However, in such a conventional operation, the facsimile is operated even with a short pseudo call signal due to noise applied through the telephone line connection terminal (RT) or a misconnection of a line. Since it consumes a lot of power has a disadvantage.

The present invention allows the facsimile to operate when the call signal is repeatedly applied in consideration of such a conventional disadvantage, and to reduce the power consumption by using standby power when waiting after the call signal. When this is described in detail as follows.

Telephone line connection terminal (RT) is a bridge diode (BD ₁₎ and a capacitor (C ₁₎ of the relay (RL ₁₎ junction box as well as a capacitor (C ₅₎ and a relay (RL ₆ through a relay switch (RL ₅₂₎ to over ), And the power supply terminal AC is connected to the primary side T ₂₁ of the power supply transformer T ₂ through the relay switch RL ₁₁ (RL ₅₁ ), and the relay switch RL ₆₁ (RL ₂₁ ). ), the power transformer (connected to the primary side (T ₁₁₎ of the T _1), second side (T ₂₂₎ of the power transformer (T ₂₎ via the relay via a bridge diode (BD ₄₎ and capacitor (C ₆₎ (RL ₅ ) and resistor (R ₂ ), connected to relay (RL ₅ ) and resistor (R ₂ ), and relay (RL ₅ ) and resistor (R ₂ ) of relay switch (RL ₆₂ ). It is connected to one side and the other fixed terminal (a ₆₂ ) (b ₆₂ ), respectively.

The secondary side T ₁₂ of the power transformer T ₁ is connected to the relay switch RL ₃₁ through the bridge diode BD ₂ and the capacitor C ₂ and fixed to one side and the other side of the switch RL ₃₁ . The terminals a ₆₁ and b _{61 are} connected to the resistor R ₁ and the relay RL ₂ , respectively, and the secondary side T ₁₃ of the power supply transformer T ₁ is a bridge diode BD ₃ and a capacitor ( Through C ₃ ), relay switch (RL ₁₁ ) (RL ₂₁ ) (RL ₃₂ ) (RL ₅₁ ) (RL ₆₁ ) is shorted when relay ((RL ₁ -RL ₃ ) (RL ₅ -RL ₆ ) The relay switches RL ₃₁ and RL ₆₂ are configured to be connected to their fixed terminals a ₆₁ and b ₆₂ respectively when the old relays RL ₃ and RL ₆ are driven, and the relay switches RL ₄₁ terminate the communication. The signal was shorted at the input.

In addition, the value of the condenser C ₆ is set such that the relay RL ₅ is driven by a predetermined time when the power is applied to the power supply T ₂ .

Referring to the operation and effects of the present invention configured as described above are as follows.

When a call signal is input through the telephone line connection terminal RT, the rectified power through the bridge diode BD ₁ is applied to the relay RL ₁ to drive the relay switch RL ₁₁ . Power from the terminal AC is applied to the primary side T ₂₁ of the power supply transformer T ₂ through the relay switch RL ₁₁ .

Subsequently, the power induced in the secondary side T ₂₂ of the power supply transformer T ₂ is rectified through the bridge diode BD ₄ and applied to the relay RL ₅ to drive the relay switch RL _51. ) Is short-circuited so that power from the power supply terminal AC is applied to the power supply transformer T ₂ through the relay switch RL ₁₁ (RL ₅₁ ), and the relay switch RL ₅₂ is short-circuited.

In this state, if the standby state without a signal continues, the relay RL ₁ is not driven, and thus the relay switch RL ₁₁ is opened.

However, since power is applied through the relay switch RL ₅₁ , the relay RL ₅ is continuously shorted, and thus the power is continuously supplied.

At this time, since the power is supplied using the standby power transformer T ₂ to consume only low power for the standby state, only low power consumption is maintained.

However, if the signal input through the telephone line input terminal (RT) is a noise or a short pseudo-call signal due to a misconnection of the line, the relay (RL ₅ ) will be deactivated even if the power is applied to the power transformer (T ₂ ). Since the relay switch RL ₅₂ is kept in the open state, and the short similar call signal is interrupted, the relay RL ₁ is stopped and its relay switch RL ₁₁ is opened, so that the power is cut off and the facsimile is stopped. Will not start.

On the other hand, when the _second call signal is input through the telephone line connection terminal RT in the standby state of the fax as described above, the power rectified through the bridge diode BD ₁ is relayed through the relay switch RL ₅₂ . ₆ ) is driven so that the relay switch RL ₆₁ is connected accordingly so that the power from the power supply terminal AC is supplied via the relay switch RL ₆₁ to the primary side T ₁₁ of the power transformer T ₁ . Therefore, the power induced in the secondary side T ₁₂ of the power transformer T ₁ is rectified through the bridge diode BD ₂ and applied to the relay RL ₂ through the relay switch RL ₅₁ . Since it is driven and thus the relay switch RL ₂₁ is connected, power from the power supply terminal AC is applied to the power supply transformer T ₁ through the relay switch RL ₆₁ (RL ₂₁ ).

In addition, the relay switch RL ₆₂ is connected to one fixed terminal a _{62 of} the relay switch RL ₅ so that the driving of the relay RL ₅ is stopped, and thus the relay switch RL ₅₁ RL ₅₂ is opened, thereby relaying the switch RL. ₅₁ ) The power applied to the power supply transformer T ₂ is interrupted. As the relay switch RL ₅₂ is opened, the relay RL ₂ is in a driving state, and the relay switch RL ₂₁ is shorted. Is continuously applied to the power supply transformer T ₁ through the relay switch RL ₂₁ so that the facsimile can perform its operation normally.

Then, when the relay switch RL ₄₁ is short-circuited as the communication type signal is input, the power induced in the secondary coil T ₁₃ of the power transformer T ₅₁ is rectified through the bridge diode BD ₃ to relay the relay RL. ₃ ) the relay switch RL ₅₂ is connected so that the driving of the relay RL ₃ is held, and thus the relay switch RL ₃₁ is connected to one side fixed terminal a _{31 of} the relay switch RL ₅₂ . Since the driving of RL ₂ is stopped, the relay switch RL ₂₁ is opened accordingly to stop the supply of power.

As described above, the present invention prevents the facsimile from operating normally for short pseudo-call signals due to noise or incorrect connection of the line. On the other hand, the standby power after the call signal reduces power consumption. It will work.

Claims (1)

The telephone line connection terminal RT is connected to the relay RL ₁ through the bridge diode BD ₁ and the condenser C ₁ , and the power supply terminal AC is powered through the relay switch RL ₁₁ and RL ₂₁ . It is connected to the primary side T ₁₁ of the transformer T ₁ , and its secondary side T ₂₂ is connected to the relay switch RL ₃₁ via the bridge diode BD ₄ and the condenser C ₂ , and one side thereof. And the other fixed terminal a ₆₁ (b ₆₁ ) to the resistor R ₁ relay RL ₂ , and the secondary coil T ₁₃ of the power supply transformer T ₁ is a bridge diode BD ₃ and In the case where the relay RL ₃ is commonly connected to the relay switches RL ₃₂ and RL ₄₁ through the condenser C ₃ and the relay RL ₃ is connected, the bridge diode BD ₁ is the condenser C. ₅ ) and the relay RL ₆ via a relay switch RL ₅₂ , and the power supply terminal AC is connected to the primary side T ₂₁ of the power transformer T ₂ via a relay switch RL ₁₁ (RL ₅₁ ). ) And his secondary (T ₂₂₎ is a bridge diode (BD ₄₎ and a condenser relay (RL ₅₎ and a connection to the resistor (R _2), the relay (RL ₅₎ and a resistor (R ₂₎ relay switch via the (C ₆₎ ( A facsimile automatic starting circuit characterized in that it is connected to one side and the other fixed terminal (a ₆₂ ) (b ₆₂ ) of the RL ₆₂ .