DE4244133A1 - - Google Patents

Abstract

The surge absorber has a PNPN-structure semiconductor element 21 and PN-structure semiconductor element 22. A terminal 23 connected to an external P-section 21a of element 21 and a terminal 24 connected to an external N-section 21d of element 21 are used as connection terminals. An N-section 22a of PN element 22 is connected to the external P-section 21a of PNPN element 21 and a P-section 22b of element 22 is connected to an internal P-section 21c serving as a gate terminal of element 21. The communication-network surge absorber makes it possible to obtain a large surge-current resistant capacity at a low breakover voltage. The PNPN element 21 may be a triac, (Fig 3), or SCR, Fig 2, and the PN element 22 may be a Zener diode. <IMAGE>

Description

The present invention relates to a surge arrester, which is suitable for electronic devices of transmission systems, telephone equipment, facsimile equipment, telephone exchanges and modems lock in. In particular, it refers to a surge arrester for a transmission network for the protection of electronic components elements before mains overvoltage, which is applied to this.

A surge arrester that is connected to a pair of conductors of an electroni rule device of transmission systems is connected in parallel, so that it is at a voltage higher than the operating voltage of the elec tronic device works is known. The surge arrester serves as a resistor with a high resistance at one Voltage less than the initial discharge voltage. However, if the applied voltage is higher than the initial discharge voltage, the Arrester as a resistor with a low resistance value of a few tens of ohms or less. If an overvoltage z. Legs Mains overvoltage instantly attached to an electronic component is placed, the surge arrester discharges and conducts the over voltage to protect the electronic component.  

A semiconductor element, e.g. B. a zener diode, a thyristor or TRIAC, has a satisfactory surge arrester characteristic because it has no response delay for overvoltage.

The use of one of these semiconductor elements as a surge arrester however, does not solve the problems. For example, the zener diode the disadvantage of a breakdown and short circuit if one Low current overvoltage is applied because it has a low over voltage current tolerance. In addition, the thyristor and The TRIAC cannot be configured to provide protection against large excesses to provide voltage currents at low breakdown voltages.

It is an object of the present invention a surge to provide arresters for a transmission network to obtain a large surge current-resistant capacity at a low Breakdown voltage.

This object can be achieved by the present invention provides a surge arrester with a diode that acts as a first layer of a semiconductor material of a first type connected to a second layer of semiconductor material of a second type is structured. The diode is connected to a thyristor. The Thyristor is with an end layer of the second semiconductor material type and an inner layer of the same type. The diode is with electrically connected to the thyristor so that the first layer of the diode with the end layer of the thyristor and the second layer of the diode with the inner layer of the thyristor is connected.

The inventive surge arrester shows a high resistance, when the voltage applied between the input lines is lower  than the breakdown voltage of the pn element. If the created Voltage exceeds the breakdown voltage of the pn element flows Current in the inner p-area (gate) of the pnpn element, which most overcurrent is caused by the pnpn element flows.

As soon as the overcurrent subsides, the current flowing through the pnpn Element flows, equal to or less than the holding current of the pnpn-Ele ment what the surge arrester in its high resistance state leads back.

Further advantages, features and possible uses of the present the invention result from the following description of Embodiments in connection with the drawing. In the drawing shows

Fig. 1 is a block diagram of an embodiment of a surge arrester according to the present invention;

Fig. 2 is a circuit diagram of a surge arrester circuit using the surge arrester of Fig. 1;

Fig. 3 is a circuit diagram of the surge arrester of Fig. 1;

Fig. 4 are diagrams of an initial VI characteristic of a surge arrester of the present invention and two known surge arresters; and

Fig. 5 surge arrester waveforms of a surge arrester of the present invention and two known surge arresters.

Referring to Fig. 1 is a surge arrester 13 of the front lying invention for a transmission network with a pnpn-constructive-structured semiconductor element 21 and a pn-structured semiconductor element 22, and uses a terminal connected to an outer p region 21 a of the semiconductor element 21 is connected and a connection which is connected to an outer n-region 21 d of the semiconductor element 21 , in each case as connection connections 23 and 24 .

As shown, an n-region 22 a of the semiconductor element 22 is electrically connected to an outer p-region 21 a of the semiconductor element 21 , and a p-region 22 b of the semiconductor element 22 is electrically connected to an inner p-region 21 c, which as a Gate connection of the semiconductor element 21 is used.

In the inventive surge arrester circuit of FIG. 2, connection terminals 23 and 24 of the surge arrester 13 are connected between a pair of input lines 11 and 12 of the electronic device 10 for transmission systems and in parallel with the device 10 .

A thyristor, TRIAC and the like can be used as the semiconductor element 21 of the present invention. A zener diode or the like can be used as the semiconductor element 22 .

For this surge arrester for a transmission network, semiconductor elements 21 and 22 serve as a resistor with a high resistance value if the voltage applied between the terminals 23 and 24 is less than the breakdown voltage of semiconductor element 22 . When the applied voltage exceeds the breakdown voltage of the semiconductor element 22 , a tripping current flows through an inner p-region 21 c, which serves as a gate terminal of the semiconductor element 21 . As a result, the semiconductor element 21 is turned on and most of the overvoltage current flows through the semiconductor element 21 .

After most of the overvoltage current is over, the current flowing between the terminals 23 and 24 becomes less than or equal to the holding current of the semiconductor element 21 . Then the semiconductor elements 21 and 22 again serve as a resistor with a high resistance value.

As shown in FIG. 3, the surge arrester 13 is provided with a TRIAC 21 and a Zener diode 22 . Connections T ₂ and T _{1 of} the TRIAC 21 are used as connection connections 23 and 24 , respectively. As shown in Fig. 1, an n-region 22 a of the Zener diode 22 is electrically connected to the connection terminal 22 of the TRIAC 21 and a p-Be region 22 b of the Zener diode is electrically connected to the gate terminal of the TRIAC 21 .

In the present connection, the following areas for the Characteristics of semiconductor elements used:

10 V Vz 400 V
500 VV _GT 1000 V
15 mA V _GT 600 mA
10 mA I _H 500 mA
600 VV _BD 1000 V

where Vz is the Zener voltage, V _{GT is} the gate trigger voltage, I _{GT is} the gate trigger current, I _{H is} the hold current and V _{BD is} the breakdown voltage.

The characteristic value of the Zener diode 22 in this embodiment is nominally 62 V as a Zener voltage and the nominal power is 1 W. The characteristic values of the TRIAC 21 are 800 V for the gate trigger voltage, 15 mA for the gate trigger current, 10 mA for the holding current and 800 V for the breakover voltage.

Test Example 1 is now described.

Fig. 4 (a) shows the initial VI characteristic of the surge arrester 13 of the above embodiment. In comparison, FIG. 4 (b) shows the initial VI characteristic of the surge arrester from only one Zener diode 22 , which is a component of the surge arrester 13 , and FIG. 4 (c) shows the initial VI characteristic of the surge arrester from only one TRIAC 21 , which is a component of the surge arrester 13 .

As shown in FIG. 4 (b), current begins to flow at 60 V in the surge arrester with only one Zener diode 22 . As shown in Fig. 4 (c), at a voltage of 800 V, current begins to flow in the surge arrester with only one TRIAC 21 , and the voltage drops when the terminals 23 and 24 are connected together. In contrast; As shown in Fig. 4 (a), the surge arrester 13 of the TRIAC 21 is turned on, and the voltage has dropped to a voltage where the zener diode 22 breaks down.

Surge characteristics are created by creating a dummy surge voltage with a current or. Voltage waveform of (1.2 × 50) µsec-2kV applied to the three surge arresters tested in test example 1 will.  

The voltage response of the surge arrester with only one Zener diode 22 is 110 V and shows the surge arrester waveform of Fig. 5 (b). The voltage response of the surge arrester with only one TRIAC 21 is 1000 V, which is shown in the surge arrester waveform of Fig. 5 (a). In contrast, in the inventive surge arrester 13, the response occurs at 120 V, as shown in Fig. 5 (a). This is close to the voltage response of the surge arrester with only one Zener diode 22 .

The surge current-resistant capacity is created by applying a Apparent overvoltage, which is a current or. Voltage waveform of (8 × 20) µsec has examined to the three surge arresters, which in Test example 1 can be tested.

The surge arrester with only one Zener diode 22 breaks down and closes briefly at an overvoltage current of 100 A. The surge arrester with only one TRIAC 21 and the surge arrester 13 of the invention do not break through, even with an overvoltage current of 600 A.

As described above, the present invention is advantageous in that it provides a surge arrester that operates at a low Breakdown voltage of a pn-structured semiconductor element works and which has a high surge current tolerance due to com bin a pnpn structured semiconductor element, e.g. B. a thyristor or TRIACs, with a pn-structured semiconductor element, e.g. B. one Zener diode.

Claims (12)

1. Surge arrester, which has:

• (a) a diode which has:
  • (i) a first layer of a first semiconductor type;
  • (ii) a second layer of a second semiconductor type connected to the first layer;
• (b) a thyristor; which has:
  • (i) an end layer of the second semiconductor type; and
  • (ii) an inner layer of the second semiconductor type,

the first layer being electrically connected to the end layer and the second layer is electrically connected to the inner layer is. 2. Surge arrester according to claim 1, wherein the thyristor Is TRIAC. 3. Surge arrester according to claim 1, wherein the second element is a zener diode. 4. Surge arrester according to claim 3, wherein the zener diode has a Zener voltage in the range of 10 volts to 400 volts. 5. Surge arrester according to claim 1, wherein the thyristor Gate trip voltage, a gate trip current, a hold current and has a breakdown voltage.   6. Surge arrester according to claim 5, wherein the gate tripping voltage is in the range of 500 volts to 1000 volts. 7. Surge arrester according to claim 5, wherein the gate trip current is in the range of 15 milliamps to 600 milliamps. 8. surge arrester according to claim 5, wherein the holding current in Is from 10 milliamperes to 500 milliamperes. 9. surge arrester according to claim 5, wherein the breakover voltage is in the range of 600 volts to 1000 volts. 10. Surge arrester according to claim 1, wherein the first half lead is p type and the second semiconductor type is n. 11. Surge arrester according to claim 1, wherein the first half lead is type n and the second semiconductor type is p.