KR200313686Y1 - Solid state relay having a nonheating AC-input part - Google Patents

Abstract

The present invention relates to a contactless electronic relay provided with a heat generating AC control input unit. The contactless electronic relay according to the present invention includes a capacitor connected in series with an AC control input terminal; A rectifier connected to a rear end of the capacitor to convert an AC voltage into a DC; A photocoupler comprising a light emitting element driven by a DC voltage output from the rectifying unit, and a light receiving element electrically insulated from the light emitting element and outputting an electric signal in association with an ON state of the light emitting element; And an output unit driven and driven selectively by an electrical signal output from the photocoupler.

Description

Solid state relay having a nonheating AC-input part

The present invention relates to a contactless electronic relay provided with a non-heating AC control input unit, and more particularly to a contactless electronic relay having a heat generating transformer means for driving a photocoupler included in the contactless electronic relay. will be.

Solid-state electronic relays, commonly referred to as "SSRs," include triac (TRIAC), silicon rectifier (SCR), transistor (TR), field effect transistor (FET), insulated gate bipolar transistor (IGBT), and so on, instead of mechanical contacts. As a switching operation is performed through a semiconductor device, it has low noise, high reliability, small size, and quick response compared to a mechanical relay, and thus has been widely used as a relay for controlling various automation devices.

The functional configuration of this contactless electronic relay is shown schematically in FIG. As shown in the drawing, the contactless electronic relay includes an input circuit 1 for operating a voltage transformer, a rectifier, and the like on an input control signal, a photo coupler 2 driven by the input circuit 1, and a photo port. It consists of an output circuit 3 having a semiconductor switching element which is selectively operated according to an electrical signal generated from the coupler 2.

In the contactless electronic relay, in particular, the photocoupler 2 includes a light emitting element such as an infrared LED, and in order to drive the same, a DC power input having an appropriate level corresponding to 1.2 V-7 mA is required.

Therefore, when a DC voltage of 4 to 32 V is applied to the input terminal, the photocoupler 2 can be driven by transforming it to an appropriate level without any problem. However, a contactless point for setting an AC voltage of 100 to 240 V as an input level is required. In the electronic relay, a very large power loss occurs in the process of transforming a high AC voltage into a low voltage.

Fig. 2 shows a circuit configuration of a conventional general contactless electronic relay which transforms an input AC control signal, falls to an appropriate voltage level, rectifies, and drives the photocoupler 2. As shown in the figure, conventionally, AC (AC) control signals inputted by inserting resistors R ₁ and R ₃ in series with respect to the input terminals are stepped down, and converted into direct current through rectifying section 1a consisting of a bridge rectifying circuit, for example. After that, it was configured to apply to the photocoupler (2). In the figure, resistors R ₂ and LED 1 serve as an additional voltage drop means.

Conventional solid-state electronic relay this is because with a series resistor to the variable pressure the AC control signal of the high voltage occupies a very small volume compared to the variable pressure means, such as a transformer, but this transformer efficiency is excellent advantages of a lower voltage series resistor R _1, and R Due to the conduction current flowing through ₃ , the Joule heat loss and the resulting heating problem are seriously vulnerable.

The present invention was devised to solve this problem, and an object thereof is to provide a contactless electronic relay having an AC control input stage that does not involve heat generation.

The following drawings attached to this specification are illustrative of the preferred embodiments of the present invention, and together with the detailed description of the present invention to serve to further understand the technical spirit of the present invention, the present invention is a matter described in such drawings It should not be construed as limited to.

1 is a block diagram schematically showing a functional configuration of a general solid state relay (SSR).

Fig. 2 is a circuit diagram showing the configuration of an AC control input contactless electronic relay according to the prior art.

Figure 3 is a circuit diagram showing the configuration of the AC control input contactless electronic relay according to an embodiment of the present invention.

Figure 4 is a circuit diagram showing the configuration of the AC control input contactless electronic relay according to another embodiment of the present invention.

<Description of main reference numerals in the drawings>

1a ... rectifier 2 photocoupler 3 ... output circuit

In order to achieve the above object, a contactless electronic relay according to the present invention includes a capacitor connected in series with an AC control input terminal; A rectifier connected to a rear end of the capacitor to convert an AC voltage into a DC; A photocoupler comprising a light emitting element driven by a DC voltage output from the rectifying unit, and a light receiving element electrically insulated from the light emitting element and outputting an electric signal in association with an ON state of the light emitting element; And an output unit driven and driven selectively by an electrical signal output from the photocoupler.

Additionally, the present invention may further include a discharge resistor connected in parallel with the capacitor.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

First, Figure 3 is a circuit diagram showing the configuration of a contactless electronic relay according to an embodiment of the present invention. As shown in the figure, the present invention includes a condenser C ₂ connected in series with the AC control input terminal, a rectifying unit 1a for rectifying operation, a photocoupler 2 and an output circuit 3.

A and have the capacity reactance X _C which corresponds to, a capacitor (C ₂₎ is inserted a capacitor (C ₂₎ is, as is well known 1 / 2πfC (capacitance π: pi, f:: frequency, C) according to a exchange The current I corresponding to V / X _C (V: input control voltage) flows in the line 90 degrees above the voltage.

Therefore, the AC control input voltage drops through the capacitor C ₂ , and the current I does not accompany Joule heat generation, and thus no heating problem occurs.

As the capacitor C ₂ , a metal film capacitor having excellent pressure resistance and capable of increasing capacitance can be preferably used, and other types of capacitors may be employed.

In addition, the capacitor (C ₂ ) is a driving power supply of the photocoupler (2) of about 1.2V-7mA corresponding to the specification of the contactless electronic relay for a conventional AC control input, and AC control corresponding to about 100 to 240V and 60Hz. Considering the input, it is desirable to have a capacitance of 0.1 kV to 250 V and a breakdown voltage for the transformation to an appropriate voltage for driving the photocoupler 2. Here, the capacitance of the capacitor C ₂ is not necessarily limited to 0.1 kW, and there may be various modifications such as 0.12 kW or 0.15 kW, or 0.2 kW or 0.22 kW depending on the specification of the photocoupler 2, of course. to be.

The rectifier 1a converts the AC control input voltage dropped by the capacitor C ₂ into direct current. To this end, the rectifying unit 1a may be preferably a bridge rectifying circuit including a bridge diode and a smoothing capacitor C ₁ , and other rectifying means may be employed.

The photocoupler 2 is coupled to the rear end of the rectifying unit 1a to transmit a signal to the final output circuit 3 according to a control signal input while maintaining an electrical insulation state.

The photocoupler 2 is formed so as to face the light emitting device driven by the DC control voltage output from the rectifying unit 1a in an electrically insulated state from the light emitting device as is known, so that the light emitting device is in an ON state. It consists of a light receiving element for outputting an electrical signal in conjunction with. In this case, an infrared LED may be preferably used as the light emitting device, and a photo transistor may be used as the light receiving device.

The output circuit 3 corresponding to the output portion of the contactless electronic relay according to the present invention is a circuit which is selectively opened and closed by being driven by an electrical signal output from the photocoupler 2, and is a semiconductor switching element (not shown). It is made to include. In this case, for example, a triac (TRIAC), a silicon rectifier (SCR), a transistor (TR), a field effect transistor (FET), an insulated gate bipolar transistor (IGBT), or the like may be used as the switching element. The output circuit 3 may employ the same well-known technical configuration, and there may be various modifications, and thus the detailed description thereof will be omitted.

On the other hand, according to another embodiment of the present invention, as shown in Figure 4, the capacitor C ₂ is connected in series with the AC control input terminal for the AC voltage drop, the discharge resistance in parallel with the capacitor (C ₂ ) A contactless electronic relay provided with (R _d ) is provided.

In the present embodiment, the discharge resistor (R _d ) is to prevent the electric shock that may occur when the user handles the contactless electronic relay of the present invention in the state of blocking the input control voltage, the capacitor (C ₂ ) And the discharge current flows through the closed circuit consisting of the discharge resistance R _d and discharge of the charge charged in the capacitor C ₂ .

The discharge resistor R _d preferably has a resistance value of 470 kΩ or more, and more preferably, has a resistance value of 1 MΩ or more to prevent heat generation from occurring due to the discharge current. The resistance value corresponds to the drive voltage of the photocoupler 2 corresponding to about 1.2V-7mA corresponding to the specification of the contactless electronic relay for a normal AC control input, and the AC control input corresponding to about 100 to 240V and 60Hz. In consideration of this, the capacitor C ₂ corresponds to an optimum value set in consideration of the case where the capacitance is around 0.1 mW. Therefore, the resistance value of the discharge resistance (R _d ) can be variously modified according to the specifications of the photocoupler 2, the capacitor (C ₂ ) and the like included in the contactless electronic relay of the present invention.

According to the present invention configured as described above, as shown in Table 1 below, it can be seen that the power consumption and the amount of heat generated at the front end of the photocoupler 2 are significantly smaller than those of the conventional contactless electronic relay.

division A B Control input voltage 220V / 60Hz 220V / 60Hz Operating current (mA) 7 7 Power Consumption (W) 1.53 0.1 Device temperature (℃) 26 1.1

In Table 1, Division A represents a case where R ₁ = R ₃ = 15 kΩ and R ₂ = 470 Ω in the conventional solid state electronic relay shown in FIG. 2, and the division B represents the solid state electron of the present invention shown in FIG. In the relay, Rd = 1MΩ, R ₂ = 330Ω and C ₂ is 0.1㎌-250V.

In the above table, the power consumption of Category A is P _A1 = (I _A ) ² x (R ₁ + R ₃ ) = (7mA) ² x 30 kΩ ≒ 1.47 W, which corresponds to Joule heat loss by R ₁ and R ₃ , P _A2 = 4 x (I _A xV _D ) = 4 x (7mA x 0.6V) ≒ 0.016W, loss at rectifier 1a, and Joule heat loss at resistor R ₂ P _A3 = (I _A ) ² x (R ₂ ) = (7 mA) ² x 470 Ω ≒ 0.023 W and P _A4 = I _A x V _L = 7 mA x 2 V = 0.014 W and P at loss of photocoupler 2 _A5 = I _A x V _P = 7mA x 1.2V = 0.0084W

On the other hand, the power consumption in the segment B is _B1 = P loss of the discharge resistor ^{_{R d (V d 2 / R}} d) = (214V) 2 / 1MΩ ≒ 0.046W and a loss in the holding portion (1a) P _B2 = 4 x (I _B x V _D ) = 4 x (7 mA x 0.6 V) ≒ 0.016 W and Joule heat loss due to resistance R ₂ P _B3 = (I _B ) ² x (R ₂ ) = (7 mA) ² x 330 Ω ≒ 0.016 W, P _B4 = I _B x V _L = 7 mA x 2 V = 0.014 W, loss at LED 1, and P _B5 = I _B x V _P = 7 mA x, loss at photocoupler (2) As the total of 1.2V = 0.0084W is added, it is understood that the power consumption is much smaller than that of Category A, and the temperature of the entire apparatus is also significantly lower.

Then, the operation of the present invention as described above will be described.

According to the present invention, for example, a capacitor C ₂ is coupled in series to the input terminal to step down an AC control input corresponding to 100 to 240V. Therefore, the drop of the AC voltage by the capacitive reactance of the capacitor (C ₂₎ and be fulfilled, in which the capacitor (C ₂₎ has a displacement current rather than a conductive current (displacement current) is therefore flowing heating caused by Joule heat loss This does not happen.

In another embodiment of the present design the capacitor (C ₂₎ and the discharge resistance (R _d) coupled in parallel, so as to form a closed circuit wherein the capacitor discharge resistor (R _d) an electric charge charged in the (C ₂₎ By discharging through the electric shock to prevent the accident.

In the above, preferred embodiments of the present invention have been described with reference to the accompanying drawings. Here, the terms or words used in the present specification and claims should not be construed as being limited to ordinary or dictionary meanings, but should be construed as meanings and concepts corresponding to the technical spirit of the present invention. Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical ideas of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

The contactless electronic relay according to the present invention has the advantage of being able to be manufactured in a very small size because it transforms an AC control input signal using a capacitor, and thus has an effect of providing heat-free characteristics.

In addition, the present invention may be coupled to the discharge resistor in parallel with the capacitor for the transformer, in this case there is an effect that can prevent an electric shock accident during handling.

Claims (2)

A capacitor connected in series with the AC control input terminal; A rectifier connected to a rear end of the capacitor to convert an AC voltage into a DC; A photocoupler comprising a light emitting element driven by a DC voltage output from the rectifying unit, and a light receiving element electrically insulated from the light emitting element and outputting an electric signal in association with an ON state of the light emitting element; And A contactless electronic relay provided with a non-heating AC control input including a; output unit is driven by the electrical signal output from the photocoupler to selectively open and close. The method of claim 1, And a non-heating AC control input unit further comprising: a discharge resistor connected in parallel with the capacitor.