Semiconductor protection: overview of the main series of TVS diodes from Littelfuse

The scope of application of diodes is not limited to rectifiers. In fact, this area is very broad. Among other things, diodes are used for protective purposes. For example, to protect electronic devices when they are mistakenly switched on with the wrong polarity, to protect the inputs of various circuits from overload, to prevent breakdowns of semiconductor switches from self-induction EMF pulses that occur when inductive loads are disconnected, etc.

In order to protect the inputs of digital and analog microcircuits from voltage overloads, chains of two diodes are used, which are connected in the opposite direction to the power buses of the microcircuit, and the middle point of the diode chain is connected to the protected input.

If a normal voltage is supplied to the input of the circuit, then the diodes remain in a closed state and have almost no effect on the operation of the microcircuit and the circuit as a whole.

But as soon as the potential of the protected input goes beyond the supply voltage, one of the diodes will go into a conducting state and begin to bypass this input, thus limiting the allowed input potential to the value of the supply voltage plus the direct voltage drop across the diode.

Chains of this kind are sometimes immediately included in an integrated circuit at the stage of designing its crystal, or are put into the circuit later, at the stage of developing a node, block or entire device. Protective two-diode assemblies are also produced in the form of finished microelectronic components in three-terminal transistor packages.

If the protective voltage range needs to be expanded, then instead of connecting to buses with supply potentials, the diodes are connected to points with other potentials that will provide the required permitted range.

On long wire lines, sometimes powerful interference occurs, for example from lightning discharges. To protect against them, more complex circuits may be required, containing not only two diodes, but also resistors, arresters, capacitors and varistors.

As is known, it is the EMF of self-induction that prevents the decrease in current through any inductance, trying to somehow maintain the current through it unchanged. But at the moment when the current source from the coil is turned off, the magnetic field of the inductance must dissipate its energy somewhere, the value of which is equal to

So, as soon as the inductance is turned off, it itself turns into a source of voltage and current, and at that moment a voltage appears on the private key, the value of which can be dangerous for the key. For semiconductor switches, this is fraught with breakdown of the switch itself, because the energy will quickly and with very high power be dissipated on the switch. For mechanical switches, the consequences may be sparking and burning of contacts.

Due to its simplicity, diode protection is very widespread and allows you to protect various switches that interact with an inductive load.

To protect a switch with an inductive load, a diode is connected in parallel with the coil in such a direction that when operating current initially flows through the coil, the diode is blocked. But as soon as the current in the coil is turned off, a self-inductive emf arises, which has a polarity opposite to the voltage previously applied to the inductance.

This self-induction EMF unlocks the diode, and now the current, which at the previous moment was directed through the inductance, moves through the diode, and the energy of the magnetic field is dissipated on the diode or on the snubber circuit in which it is connected. This way the switch will not be damaged by excessive voltage applied to its electrodes.

When the protective circuit includes only one diode, the voltage across the coil will be equal to the forward voltage drop across the diode, that is, in the region of 0.7 to 1.2 volts, depending on the magnitude of the current.

But since the voltage on the diode in this case is low, the current will decrease slowly, and in order to speed up the load shutdown, it may be necessary to use a more complex protective circuit, including not only a diode, but also in series with the diode - a zener diode, or a diode with a resistor or varistor - a full-fledged snubber chain.

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Source

Protective diode (suppressor): operating principle, how to test a TVS diode.

The protection diode is a guest of our review of semiconductors.

The power of interference affecting the voltage level in the device may vary. To counter high-energy pulses, it is possible to use gas dischargers and protective thyristors. To protect yourself from medium and low-power influences, protective diodes and varistors are more suitable.

Protection diode , most often made of silicon, may be called:

Often the suppressor becomes one of the components of the switching power supply unit, since in the event of a malfunction of the unit, the suppressor can protect it from overvoltage. Initially, the protective diode was created as insurance against atmospheric electrical influences on devices.

There are several areas of modern application of limiting zener diodes:

conclusions

The results of the study show that both varistors and suppressors based on avalanche diodes are, from the point of view of performance, elements suitable for use as one of the main means for protecting industrial electronic equipment located in cabinets from the effects of EMP radiation.
Powerful TVS diodes seem to be higher quality and more reliable protection elements than varistors, but their very high cost for mass use forces us to look for an alternative.
An alternative is varistors in combination with ferrite elements installed on the control cable upstream of the varistors.
Additional ferrite elements placed on the control cable make it possible to reduce the steepness of the leading edge and the amplitude of the current flowing through the protective element after it is triggered, and, accordingly, reduce the voltage drop across it, significantly increasing the efficiency of equipment protection with a varistor.

Literature

Protection Technology Comparison Chart. Protek Devices, 2013.
TND335/D. Transient Overvoltage Protection, ON Semiconductor, Semiconductor Components Industries. LLC, 2008
Electronics, surge protection. Section H. 51. Basics of surge protection. - Weidmuller
AN 1826/0104. Transient Protection Solution: Transil diode versus Varistor /Bremond A., Karoui C. - STMicroelectronics.
J. Goldman, Selecting Protection Devices: TVS Diodes vs. MetalOxide Varistors // Power Electronics. 2010. June 1.
Han SM, Huh CS, Choi JS A Validation of Conventional Protection Devices in Protecting EMP Threats // Progress in Electromagnetic Research. 2011. Vol. 119.
Howell T. Comparing Circuit Protection Technologies for 48 V DC in High Surge Environments. Protection Engineers Group Conference, Dallas, March 14–16, 2022.
Gurevich V.I. Ferrite filters // Components and technologies. 2015. No. 10.

Operating principles

The protective diode has a specific VA characteristic characterized by nonlinearity. Provided that the size of the pulse amplitude is greater than permissible, this will entail a so-called “avalanche breakdown”. In other words, the amplitude size will be normalized, and all excess will be removed from the network through a protective diode.

Fig. 1 Protective diode - principle of operation of a semiconductor

The operating principle of a TVS diode assumes that until a danger occurs, the diode fuse in no way affects the device itself or its functional properties. Thus, it should be noted that another name for the protective diode is emerging - an avalanche diode.

There are two types of limiting zener diodes:

Protective diode, bidirectional, suitable for operation in alternating current networks.

Applicable only for networks with direct current, since they have a unidirectional operating mode. The method of connecting an asymmetrical protective diode does not correspond to the standard. Its anode is connected to the negative bus, and its cathode is connected to the positive bus. The position turns out to be conditionally inverted.

The coding of protective diodes classified as symmetrical includes the letters “ C ” or “ CA ”. Single-ended diode fuses have a color-coded stripe on the cathode terminal side.

The housing of each protective diode is also equipped with a marking code that displays all significant parameters in a compressed form.

If the input voltage level of the diode increases, the zener diode will reduce its internal resistance over a very short period of time. The current strength at this moment, on the contrary, will increase, and the fuse will blow. Since the protective diode almost instantly, the integrity of the main circuit is not compromised. In fact, a quick response to excess voltage is the most important advantage of a TVS diode .

TVS diodes TRANSZORB series 1.5KE6.8–1.5KE440CA (1N6267–1N6303A)

Diodes of the 1.5KE6.8–1.5KE440CA series are available in symmetrical and asymmetrical versions. The suffix C or CA is added to the designation of a symmetrical diode. For example, 1.5KE6.8C, 1.5KE440CA. The 1N6267–1N6303A series is available in an asymmetrical version only.


Dimensional drawing	Diode symbols

ppm from td for series of discrete TVS diodes 1.5KE6.8-1.5KE440CA (1N6267-1N6303A) series" title="" width="387″ height="306″>

Rice. 6. Dependence of P ppm on td for a series of discrete TVS diodes of the 1.5KE6.8-1.5KE440CA series (1N6267-1N6303A)

ppm or I pp from T for series of discrete TVS diodes series 1.5KE6.8 - 1.5KE440CA (1N6267 - 1N6303A)" title="" width="350″ height="351″>

Rice. 7. Dependence of P ppm or I pp on T for a series of discrete TVS diodes of the 1.5KE6.8 - 1.5KE440CA (1N6267 - 1N6303A) series

(BR) for series of discrete TVS diodes series 1.5KE6.8 - 1.5KE440CA (1N6267 - 1N6303A)" title="" width="350″ height="268″>

Rice. 8. Dependence of C on V (BR) for a series of discrete TVS diodes of the 1.5KE6.8 - 1.5KE440CA (1N6267 - 1N6303A) series

Significant characteristics of protection diodes

The voltage value at which the diode opens and the potential is transferred to the common wire. An additional synonymous designation is VBR.

Maximum reverse leakage current. It has a small value, measured in microamps, and the functionality of the device practically does not depend on it. Additional designation - IR.

The value is an indicator of constant reverse voltage. V.R.W.M.

The highest value for limiting impulse voltage. VCL, VCmax.

The highest value of the peak pulse current. Otherwise, this is an indicator of the greatest strength of the current pulse that is safe for the protective diode. For the most effective limiting zener diodes, this value can be hundreds of amperes. IPP.

Indicator of the highest value of permissible pulse power. Unfortunately, this parameter is extremely dependent on the pulse duration.

Fig. 2 VA characteristics of the protective diode

The power level of protection diodes is not the same. However, if the suppressor does not have enough initial data on this parameter, it can easily be combined with one or more semiconductors, which will have a positive effect on the overall power level.

A TVS diode can act as a zener diode. But first you need to check its maximum power dissipation and dynamic current at Imax. and Imin.

TVS products Semtech Corporation

Semtech's protective products include both discrete diodes and specialized assemblies designed to work with specific interfaces [3]. This class of devices was designed to protect sensitive components from electrostatic discharge (ESD), electrical fast transients (EFT), and communications surge (CDE). Currently produced devices are available in a variety of housing designs, determined by operating conditions and areas of application, all products are certified to comply with the requirements of IEC, ETSI, Bellcore 1089 and FCC Part 68 safety standards and regulations. Typical applications include portable wearable electronics, equipment Ethernet and other data networks, HD TVs and monitors, laptops, personal and tablet computers.

The range of TVS devices offered by the company contains hundreds of items grouped into separate families; it is not possible to list their parameters in one article. Therefore, further we will consider the most interesting series from the point of view of competitive advantages, which include:

low limiting voltage (from 2.5 V);
high overload capacity;
low intrinsic capacitance (less than 0.5 pF);
the ability to protect against periodically repeating ESD pulses;
minimum dimensions;
low leakage currents.

Rice. 3. Internal structure of protective devices of the EMIClamp series: a) EClamp237xK; b) EClamp2422N; c) EClamp239xP

A series of protective devices that combine TVS diodes and LC/RC filters in single packages is produced by Semtech under the EMIClamp brand.
In addition to limiting spurious ESD pulses, it provides suppression of unwanted electromagnetic (EMI) and radio frequency (RFI) emissions in the frequency ranges determined by the parameters of the built-in low-pass filters. Components in this series protect common interfaces and are successfully used in portable electronics: cell phones, digital photo and video cameras, tablets and laptops, PC peripherals (printers, scanners, etc.) and LCD displays. Currently, 2-, 4-, 6- and 8-channel solutions are available (several dozen items), the internal configurations of which are adapted to specific applications. For example in Fig. Figure 3 shows typical electrical circuits of some popular models (one channel is shown), and Table 2 shows their main parameters. Table 2. Main characteristics of popular devices of the EMIClamp series

Name	Number of channels	VR, V (max)	VBR, V (min)	C, pF	R, Ohm	L, nH	IR, µA (max)	Case dimensions, mm
EClamp2357NQ	6	5	6	10	100	–	0,5	3×3×1 (QFN-16)
EClamp237xK*	4; 6; 8	5	6	10	100	–	0,5	1.7×1.3×0.5 (SLP-8) 2.5×1.3×0.5 (SLP-12) 3.3×1.3×0.5 (SLP-16)
EClamp238xK*	4; 6; 8	5	6	12	200	–	0,5
EClamp239xP*	4; 6; 8	5	6	12	–	19	0,1	2.1×1.6×0.5 (SLP-8) 3×1.6×0.5 (SLP-12) 4×1.6×0.5 (SLP-16)
EClamp255xP*	4; 6; 8	5	6	12	–	28	0,1	2.1×1.6×0.5 (SLP-8) 3×1.6×0.5 (SLP-12) 4×1.6×0.5 (SLP-16)
EClamp2374KQ	4	5	6	20	100	–	0,5	1.7×1.3×0.5 (SLP-8)
EClamp2422N	2	5	6	100	–	2	0,1	1.5×1×0.5 (SLP-6)
EClamp2455K	4	5	6	20	100 47	–	0,5	1.7×1.3×0.5 (SLP-8) 2.1×1.6×0.5 (SLP-12)
EClamp2465T	4	5	6	10	100 47	–	0,5	1.7×1.3×0.5 (SLP-8)
EClamp2522P	2	5,5	6	20	22	–	1	1.6×1.6×0.5 (SLP-6)

Note. x - corresponds to the number of channels

The six-channel IC EClamp2357NQ (Fig. 4), designed to protect logical lines of SD (Secure Digital) memory cards and touch displays, works with 5‑V data buses [4].

Rice. 4. Typical connection diagram for the EClamp2357NQ IC

Integrated P-type filters, each consisting of a 100-ohm resistor and two 10 pF capacitors, provide 20 dB of signal attenuation in the 1-3 GHz frequency range. TVS diodes provide ESD suppression to IEC 61000-4-2 Level 4 and are AEC-Q100 certified for automotive applications. Structurally, the devices are made in 16-pin low-profile QFN form factor packages with dimensions of 3x3x1 mm and a pin pitch of 0.5 mm.

Small-sized multi-channel protection devices EClamp237xP and EClamp238xP save space on the printed circuit board. The new families, containing 4-, 6- and 8-channel devices, are designed to protect and filter signals from high-speed parallel interfaces operating at speeds greater than 60 Mbps. Security ICs are available in planar SLP packages, which have a minimal form factor, increased reliability and integrate up to 32 discrete components. The characteristic features of all devices within the families are unified width (1.3 mm) and height (0.5 mm), length, depending on the number of channels, varies between 1.7–3.3 mm.

The EClamp239xP and EClamp255xP families with built-in LC filters are used to protect high-quality color LCD interfaces in 3G GSM and CDMA phones. They feature a sharp roll-off frequency response, providing a minimum of 30 dB of attenuation in the 800 MHz - 2.7 GHz range. The housing design and number of channels are similar to the EClamp237xP and EClamp238xP families. The pass-through design of protection devices makes it easy to trace signals for faster and more convenient PCB layout. Large ground pad sizes minimize parasitic inductance for improved filter performance.

The EClamp2422N dual-channel voltage limiter is positioned to protect audio interfaces [5]. In addition to symmetrical TVS diodes, it contains chains of CLC filters consisting of 2 nH inductors and 100 pF capacitors. Available in a 6-lead SLP package with dimensions of 1.5 x 1 x 0.5 mm and 0.5 mm pin pitch. An example of its application is shown in Fig. 5.

Rice. 5. Speaker protection with EClamp2422N

Suppressors of the TransClamp and LC series (Table 3) are designed to protect circuits from the effects of increased power.
Small-sized devices, produced in housings for planar mounting and capable of absorbing surges up to 2500 W, are favorably characterized by a minimal difference between the operating voltage and the limiting voltage and have a low intrinsic leakage current (from 0.1 μA). Devices designed to operate in circuits with operating voltages of 2.5 and 3.3 V are made using proprietary EPD (Enhanced Punch-Through) technology. Table 3. Main characteristics of popular devices of the TransClamp and LC series

Name	Number of channels	VR, V (max)	VBR, V (min)	C, pF	P, W (8/20 µs)	IPP, A (max)	IR, µA (max)	Case dimensions, mm
TClamp0602N	2	6	6,8	12	2500	95	5	2.6×2.6×0.6 (SLP-10)
TClamp2502N		2,5	–				0,5
TClamp3302N		3,3	–				1
TClamp1202P		12	13,3	12	300	100	0,1	2×2×0.6 (SLP-5)
TClamp1272S		12	13,5	5	600	20	0,1	2.9×1.6×1.2 (SOT-23-6L)
TClamp2512N		2,5	2,7	8	2300	120	0,1	2.6×2.6×0.6 (SLP-10)
TClamp3312N		3,3	3,5	8	2300	120	0,1	2.6×2.6×0.6 (SLP-10)
TClamp2482S		24	27	2	150	20	0,1	2.9×1.6×1.2 (SOT-23-6L)
LC01-6	2	6	8	50	1500	100	25	10.2×7.5×2.3 (SO-16W)
LC03-3.3		3,3	–	12	1800	100	1	4.9×3.9×1.5 (SO-8)
LC03-6		6	6,8	12	2000	100	25	4.9×3.9×1.5 (SO-8)
LC04-6	4			15	1000	200	15	9.9×3.9×1.5 (SO-16)
LC05-6					2000	100	15
LC04-12		12	13,3		600	100	2

Dual-channel TransClamp devices are used for surge protection of high-speed data interfaces, the main areas of application include: equipment for T1/E1, T3/E3, 10/100 Ethernet, ISDN, WAN and xDSL networks. They are manufactured primarily on the basis of a bridge configuration, which allows optimal operation of differential communication lines. In Fig. Figure 6 shows an example of connecting the TClamp3302N IC [6].

Rice. 6. Option for protecting logical lines of the Ethernet interface using the TClamp3302N IC

The operating principle is simple. A surge-correcting diode bridge composed of compensation diodes directs the incoming current through the TVS diode. Using this approach allows you to protect the circuit from both common-mode interference and differential-mode interference. Built-in suppressors handle 20-120 A pulse currents and 8/20 µs rise/fall times, ensuring compliance with IEC standards.

The LC series security microcircuits are positioned for similar purposes and applications. In addition to the bridge configuration, the option shown in Fig. 1 is used in their manufacture. 7. Available devices have high current carrying capacity and consist of 2-4 pairs of TVS + rectifier elements connected in series. The two back-to-back pairs ensure that the compensation diode does not go into reverse bias during transient conditions.

Rice. 7. Internal structure and circuit variant of the protective IC LC04-6

In high-speed applications, it is necessary to consider the stray capacitance introduced by the diodes, which affects the transmitted signal by causing signal attenuation, delay, reflection, or edge rounding that impedes data reception. To maintain signal quality in such systems, it is necessary to use protective devices with extremely low capacitance and low leakage currents. Semtech offers RailClamp series devices for these purposes - the most extensive in the number of components and designed for almost any telecommunications application. Its main difference is a high degree of protection against electrostatic discharges with an extremely low level of intrinsic capacitance, not exceeding 0.15 pF for some devices. This allows RailClamp devices to be connected to circuits with operating frequencies up to 3 GHz and successfully protect USB (versions 2.0, 3.0 and 3.1), MHL/MDDI, LVDS, HDMI 1.3/1.4, DVI, 1000BASE-T, 100BASE-T, xDSL and others common technologies, as well as multimedia display ports, antennas and memory cards. The RailClamp series includes both single TVS diodes (bidirectional) and assemblies based on them. For clarity, in Fig. Figure 8 shows typical internal connection diagrams of some RailClamp protection devices.

Rice. 8. Internal structure of individual protective devices of the RailClamp series: a) RClamp0502BA; b) RClamp3346P; c) RClamp0552T

The operating voltage and number of channels of the product can be easily determined from the name - to do this, you need to pay attention to the first two and last digits, respectively. For example, the RClamp3346P is designed for use in 3.3 V circuits and can provide protection for up to six logical communication lines. Despite the variety of models, the available range of operating voltages is limited to the following values: 2.5; 3.3; 3.5; 5; 6.5; 8; 12; 15 and 24 V. The letter Q at the end of the component name indicates compliance with the AEC-Q100 standard and can be used in automotive applications. The package design is determined by the maximum absorbed power; all devices are produced in surface-mount packages - both in standard SOT‑23, SC‑70, S0-8 and others, as well as in patented leadless SLP (Fig. 9).

Rice. 9. Appearance of typical housings used in the production of RailClamp series devices

As one application example, consider the use of the RClamp0524PA IC, recommended for protecting DisplayPort differential lines, the communication interface with LCD displays. In Fig. Figure 10 shows a typical connection diagram for RClamp0524PA devices [7].

Rice. 10. Application of the RClamp0524PA IC for ESD protection of the DisplayPort interface

To certify any device under development that contains this interface, both the source and receiver of the digital signal must be tested according to the methods outlined in the DisplayPort CTS (Compliance Test Specification). One of the main tests is to measure the reflected signal using a time domain reflectometer. In accordance with the requirements for the magnitude of the reflected signal, the nominal value of the differential resistance of the signal lines for the receiving device must be at the level of 100 Ohms ±15% with a rise time of the test signal of no more than 200 ps. To meet these requirements, the connected ESD device must have the smallest possible capacitance value (no more than 0.5 pF). The RClamp0524PA voltage limiter meets these requirements with a maximum capacitance of only 0.3 pF, a supply voltage of 5 V, and a miniature 10-pin package that does not introduce additional parasitic inductance. In Fig. Figure 11 shows the results of measurements of differential line signals with a connected RClamp0524PA transient limiter. The figure shows that the requirements for differential line resistance (100 Ohm ±15%) for the HDMI receiver device are met in this case.

Rice. 11. Dynamic reflectometer measurement results

It is worth noting the through pin topology, which allows you to add protection devices to the data line break and simplifies the design of the printed circuit board. All data lines enter the chassis from one side and pass through without requiring bending or routing of conductors, which can cause line impedance changes and reduce signal quality.

The MicroClamp series, as the name suggests, contains miniature protection devices used in portable devices that are critical to the size of electronic components. It consists primarily of single symmetrical and asymmetrical TVS diodes, as well as sets of suppressors connected in a circuit with a common anode and providing protection for up to eight lines. These products meet industry standards for ESD protection (IEC 61000-4-2) of ±15 kV air gap and ±8 kV direct contact. The case sizes are the smallest possible, from 1×0.6×0.5 mm, the main areas of application are protecting keyboards and memory cards (Fig. 12). Among the new products in the series, it is necessary to note the unidirectional devices uClampxx61P, characterized by an increased peak power of up to 1500 W, an operating voltage in the range of 5–40 V and a leakage current of no more than 0.2 μA.

Rice. 12. Use of uClamp0511T suppressors for ESD keyboard protection

Checking the integrity of the protective diode

Checking the integrity of the protective, as well as the rectifying (including power) diode, is carried out with a multimeter (as an option, you can use an ohmmeter). The device can be used for this purpose only in dialing mode.

Fig 3 Checking the protective diode

When the multimeter is ready, you need to connect it with probes to the suppressor terminals (positive-red with the anode, negative-black with the cathode). When this is done, the display of the testing device will display a number indicating the threshold voltage of the diode fuse being tested. When changing the polarity of the connection, an infinite resistance value should be displayed. If everything turned out this way, then the element is working.

If a leak is detected during a pole change, we can talk about the dysfunction of the element and the need to replace it. Similarly, you can check the protective diode of a car generator.

Selecting security chain parameters

8.1 Diode selection

Protective circuit diodes are selected based on the following conditions:

E < 0.7*Uadd. (5)

Considering that E = 220 V, we choose a diode of type D229B, which has Uadd = 400 V.

8.2 Selection of resistors

The resistor resistance values are determined using the curves in Fig. 4 and correspond to the intersection point of the curve Uм=f(Rp) with the straight line 0.7*Uadd.-E=0.7*400-220=60V, parallel to the Rр axis.

In the circuits presented in Fig. P-1b, P-2b, P-3b, the resistance of the protective circuit resistor is determined from the curves for relays RP-251, RPU-2 and are respectively equal to R = 2.4 kOhm, R5 = 4.2 kOhm , R7=4.2 kOhm.

The design case for the circuit in Fig. P-5c is the case of disconnection by contacts K3 of three parallel-connected relay windings K6, K7, K8 with the contacts K1 in the closed position. Moreover, if there is no protective circuit in the circuit in Fig. P-5c, then diodes VD1, VD2 are exposed to switching overvoltage. The resistance of the protective circuit resistor is defined as equivalent to three equal resistances connected in parallel, one of which (Rр) is determined from the curve in Fig. 4 for the RP-23 relay:

R2=Rр/3=2.2/3=0.773 kOhm

In the diagram shown in Fig. P-5c, it is worthy of attention to consider the possibility of relay K8 operating when contacts K2 are opened. The answer to this question in the case under consideration can be obtained by comparing the maximum value of the current passing through the winding of relay K8 in the transient mode with the minimum operating current of this relay. The current I passing in the winding of relay K8 when the contacts K2 is opened is the sum of current I1, which represents part of the sum of the currents in the windings of relays K4, K5 and current I2 - part of the sum of the currents in the windings of relays K6, K7. The maximum values of currents I1, I2, I are determined as follows:

Here: Ik4, Ik5, Ik6, Ik7 are the currents passing respectively in the relay windings K4, K5, K6, K7.

Where:

220 – power supply voltage (V);
9300, 9250 – direct current resistance, respectively, of the RP-23 relay winding and the RP-223 relay winding connected in series with the additional resistor (Ohm).

Minimum operating current of relay K8 (RP-23):

Thus, the amount of current passing in the winding of relay K8 when contacts K2 opens is insufficient to trigger the relay (If Im > Iav.k8, then relay K8 will operate when the condition tb > tav is met, where:

tav – time during which Im > Iav.k8;
tb – response time of relay K8.

Basic qualities of TVS diodes

But, as a result, it is necessary to recognize that the fulfillment of one condition often entails a violation of another.

In addition, the TVS diode, in principle, cannot be considered an ideal protective limiter. For example, suppressor protective diodes in the “off” position can be characterized by fairly large reverse currents. Further, abruptness when changing modes is disapproved. The biggest problem is that in the limiting mode the voltage level is directly dependent on the current strength.

It must be remembered that all diode characteristics given by the manufacturer are valid only under specific temperature conditions. At higher temperatures, the permissible peak power and currents will decrease.

However, even despite such shortcomings, diode fuses still turn out to be better than instruments, devices and elements with a similar purpose.

TVS diodes TRANSZORB from General Semiconductor

TRANSZORB TVS diodes from General Semiconductor are available in various designs, taking into account operating conditions and areas of application. Discrete diodes in a plastic case with flexible leads designed for installation in through holes are available with maximum permissible pulse power values of 400 W, 500 W, 600 W, 1.5 kW and 5 kW. Diodes with the highest values of the maximum permissible pulse power are usually used for installation in power circuits. At lower power levels, high-density applications use diodes and diode assemblies that are available in both DIP and surface mount packages. They are available with maximum permissible pulse power values of 400 W, 500 W, 600 W, 1.5 kW and 5 kW. Diode assemblies are commonly used on data lines to protect I/O ports from ESD. In addition, specialized low-capacitance TVS diodes are produced, used in circuits with high data rates to prevent attenuation of useful signals. TRANSZORB TVS diodes are available for operation in circuits with operating voltages from 5 to 376 V. Due to the wide range of possible operating voltages and permissible power ratings (as well as overvoltages), TRANSZORB TVS diodes are used in a variety of electronic circuits and applications.

Designation, parameters and application of protective diodes

Among the variety of semiconductor devices, diodes are probably the largest family. Schottky diodes, Gunn diodes, zener diodes, LEDs, photodiodes, tunnel diodes and many more different types and applications.

One of the classes of semiconductor diodes in our literature is called SOL (semiconductor voltage limiter) or suppressor. In foreign technical literature the name TVS diode ( Transient Voltage Suppressor is . Very often, TVS diodes are named by manufacturer brands: TRANSIL, INSEL.

In the technical literature and among radio amateurs, a suppressor can be called differently: protective diode, limiting zener diode, TVS diode, transil, voltage limiter, limiting diode. Suppressors can often be found in switching power supplies - there they serve as protection against overvoltage of the powered circuit in the event of faults in the switching power supply.

Let's consider what a TVS diode is, its principle of operation, in what circuits and for what purposes it is used.

TVS diodes were created in 1968 in the USA to protect industrial equipment from atmospheric electricity discharges. In the operating conditions of electronic devices for both industrial and household purposes, great importance is attached to protecting these devices from natural electrical impulses.

Voltage surges also often occur at power transformer substations. In such cases, hundreds of household appliances break down. Because industrial enterprises have comprehensive protection, but residential buildings are not protected at all in this case.

To protect equipment from the effects of electrical overvoltages, a class of semiconductor devices called TVS diodes or “suppressors” was developed. Sometimes in a conversation you can hear: diode fuse.

Designation on the diagram.

Operating principle of a suppressor (protective diode).

TVS diodes have a pronounced nonlinear current-voltage characteristic. If the amplitude of the electrical pulse exceeds the rated voltage for a particular type of diode, it will go into avalanche breakdown mode. That is, the TVS diode will limit the voltage pulse to a normal value, and the “excess” goes to the case (ground) through the diode. The process looks more clearly in the figure.

As long as there is no threat of failure of the electronic device, the TVS diode does not have any effect on the operation of the equipment. This semiconductor device is faster than previous limiters.

Safety diodes are available both asymmetrical (unidirectional) and symmetrical (bidirectional). Symmetrical ones can operate in circuits with bipolar voltages, and asymmetrical ones only with voltages of one polarity. Another typical connection diagram (for a bidirectional diode).

For a unidirectional suppressor, the circuit looks a little different.

If the input voltage increases, the device reduces its resistance in a very short time. The current in the circuit increases sharply and the fuse blows. Since the suppressor operates very quickly, there is no harm to the equipment. A distinctive feature of TVS diodes is their very short response time to overvoltage. This is one of the “features” of protective diodes.

Basic electrical parameters of suppressors.

U samples (V) – breakdown voltage value. In foreign technical documentation, this parameter is designated as VBR ( Breakdown Voltage ). This is the voltage value at which the diode suddenly opens and diverts a dangerous current pulse to the common wire (“to ground”).

I arr. (µA) – value of constant reverse current. This is the value of the maximum reverse leakage current that all diodes have. It is very small and has virtually no effect on the operation of the circuit. Another designation is IR ( Max. Reverse Leakage Current ). May also be referred to as IRM.

U arr. (V) – constant reverse voltage. Corresponds to the English abbreviation VRWM ( Working Peak Reverse Voltage ). May be referred to as VRM.

U limit imp. (V) – maximum impulse limiting voltage. In datasheets it is designated as VCL or VC – Max. Clamping Voltage or simply Clamping Voltage .

I ogr. max. (A) – maximum peak pulse current. In English it is designated as IPP ( Max. Peak Pulse Current ). This value shows the maximum value of the current pulse the suppressor can withstand without destruction. For powerful suppressors, this value can reach several hundred amperes!

P imp. (Watt) – maximum permissible pulse power. This parameter shows how much power the suppressor can suppress. Let us recall that the word suppressor comes from the English word Suppressor , which means “suppressor”. Foreign name for the parameter Peak Pulse Power ( PPP ).

The value of the maximum pulse power can be found by multiplying the values of U limit. imp. ( VCL ) and I limit. max. ( IPP ).

The current-voltage characteristics of a symmetrical and asymmetrical TVS diode are as follows.

CVC of a unidirectional protective diode (suppressor) CVC of a bidirectional suppressor

The big disadvantage of these diodes is the large dependence of the maximum pulse power on the pulse duration. Typically, the operation of a TVS diode is considered when a pulse is applied to it with a minimum rise time of about 10 microseconds and a short duration.

For example, with a pulse duration of 50 microseconds, an SMBJ 12A diode can withstand a pulse current that is almost four times the rated one.

Small-sized diodes TRANSZORB TM series 1.5KE6.8 - 1.5KE440 (C)A . They are available in both symmetrical and asymmetrical versions. For a symmetrical diode, the letter C or CA is added to the designation. This series has a wide range of operating voltages from 5.0 to 376 volts, a short response time of 1 * 10-9 sec, and the ability to suppress high-power pulses up to 1500 W. They have proven themselves excellent in protection schemes for television, digital and other modern equipment.

Diodes are available in DO-201 package.

Dimensions are indicated in inches and millimeters (in parentheses). Asymmetrical suppressors have a colored marking ring on the body, which is located closer to the cathode terminal.

The body contains the marking of the protective diode, which encodes its main parameters.

Bidirectional diodes TRANSIL TM 1.5KE440CA are successfully used to protect household electronic equipment in 220 volt networks. Their use is most effective for protecting objects that are connected to overhead lines. In this case, there will be protection both from atmospheric electrical impulses and from impulse overvoltages along power circuits.

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How to choose the right suppressor

In order not to make a mistake in choosing this device, you should follow simple recommendations:

set the rated voltage level on the line;
determine exactly how the element will be installed;
determine the type of voltage, and also establish that the reverse voltage exceeds the rated voltage of the circuit;
identify acceptable operating temperature limits;
decide what type of diode is required (symmetrical or asymmetrical);
decide on the most suitable series and product option.

In addition, before purchasing, it is recommended to additionally make sure that the dimensions and parameters of the radio element comply with the requirements and installation nuances.

The use of modern protective diodes in circuits is highly effective in protecting any electrical equipment connected to overhead lines.

Topic: Are protection diodes needed?

Theme Options

In some PA circuits there are diodes between the output and the power buses (of course, in reverse connection), protecting the output transistors from reverse polarity voltage. They are used, for example, in the following amplifiers: “Brig”, Kletsov (83), Zuev (84), Gumelya (85). Most schemes, especially modern ones, do not have them. Meanwhile, I am not aware of cases of failure of transistors in PAs without these diodes. So are they needed? More precisely, is it necessary to protect modern high-power high-voltage transistors with them?

Diodes may be needed if the amplifier protection operates on the principle of sharp current cutoff. Then, when it is triggered, a situation is possible when a large current in the inductive load is applied to the output of the amplifier.

Power field-effect transistors have this diode in the transistor structure itself. They should be installed with bioplar ones if the circuit has a limitation of the output signal from the repeater. If the driver limits and the residual voltage on the transistor is more than 5 V, then this diode will not protect anything and the protection must be done differently.

In a state of avalanche breakdown, there will usually be 7-8 V at the emitter junction. How dangerous this is for the transistor depends on the current. Based on the fact that the area of the emitter junction is smaller than the collector junction, and the dissipation of high power on it will cause local heating of the crystal, up to 2-3 A is safe, 5-6 is critical and more than 8 is fatal, if we talk about powerful modern transistors with a permissible collector current 15A. The base current has no effect here, since nothing will flow through the base electrode.

Source

Examples of choosing diode protection against switching overvoltages

Figures P-1a - P-5a show the practically used circuit diagrams of direct current relay protection circuits with separating diodes. In some of these circuits, the decoupling diodes may be subject to switching overvoltages.

1. Fig. A-1a When contacts K1 are closed and contacts K2 are open, almost all the current in the winding of relay K4 is turned off. In this case, a switching overvoltage occurs between the terminals of the winding of relay K4 (in winding K4 the reverse saturation current of the diode VD, amounting to several microamps, continues to flow), and the potential of the positive terminal of the winding becomes much lower than the potential of the negative pole of the power source. The diode VD is exposed to a reverse voltage that exceeds the maximum permissible voltage of the D229B diode.

Fig.P-1a - K3, K4 - relay windings, respectively RP255/220, RP251/220; VD, VD1 - diodes D229B; VD1,R - safety chain

2. Fig. P-2a. Diodes VD1, VD2 are exposed to switching overvoltage when contacts K1 are closed and contacts K2 are open, since almost all the current in the relay winding K6 is turned off, and the potential of its positive terminal is much lower than the potential of the negative pole.

Fig.P-2 - K3, K4, K5 - relay windings RP252-U4/220; K6 - relay winding RPU-2/220; VD1-VD6 - diodes D229B; VD5,R4 - spark arresting circuit; VD6,R5 - protective chain

3. Fig. P-3a. When the current in the winding of relay K7 is switched off by contacts K2, when contacts K1 are in the closed position, the transient process occurs similarly to that discussed above. Switching overvoltage affects diodes VD1, VD2.

Fig.P-3 - K3 - indicating relay winding; K4, K5, K6 relay windings RP252-U4/220, K7 - relay winding RPU-2/220; VD1-VD6 - diodes D229B; R1, R2 - resistors, respectively, 3000 and 2000 Ohms; VD5,R6 - spark arresting circuit; VD6,R7 - protective chain; SX - overlay

4. Fig. P-4. In this circuit, the separating diodes are not exposed to switching overvoltages.

Fig.P-4 - K3, K4 - windings of indicating relays; K5 - series winding of the intermediate relay; K6, K7 relay windings RP222-U4/220; VD1, VD2 - diodes D229B; R - 1000 Ohm resistor;

5. Fig. P-5a. Diode-resistor chains connected in parallel to the relay windings (see also Fig. P-2a, P-3a) and designed to reduce sparking at the contacts, to some extent limit the switching overvoltage on the separating diodes. The use in these chains of two, instead of one, series-connected diodes with resistors connected in parallel to them (serving to uniformly distribute the reverse voltage across the diodes) was undertaken in order to prevent breakdown of the diodes of these chains from the effects of overvoltages.

However, the possibility of the influence of switching overvoltage on the diodes-resistor chains in the circuit of Fig. P-5a (as well as in circuits P-2a, P-3a) is excluded (It is assumed that overvoltages cannot also enter the circuit of Fig. P-5a from the source side nutrition). Therefore, it is advisable to replace all these relatively complex chains with diode-resistor chains (Fig. P-2b, P-3b, P-5b). Moreover, if the probability of a break in the circuit of separating diodes is insignificant, it is possible to use instead of three one common diode-resistor circuit, connecting it in parallel with the winding of relay K8 (Fig. P-5c).

The common diode-resistor protective circuit, along with a reduction in the level of switching overvoltages affecting the separating diodes VD1-VD4, helps reduce sparking at the contacts.

Fig.P-5 - K4, K5 - relay windings RP223/220; K6, K7, K8 - relay windings RP23/220; VD1-VD14 - diodes D229B; R1 - 1000 Ohm resistor;

Protective diodes operating principle

The protection diode is a guest of our review of semiconductors.

Protection diode , most often made of silicon, may be called:

There are several areas of modern application of limiting zener diodes:

Application areas of diodes

Such radioelements are actively used in various directions:

communications and telecommunications;
digital interfaces;
various power electronics;
household electrical appliances;
various control schemes.

Avalanche diodes are widely used to protect on-board electronics of vehicles. For example, the ignition system of any car is one of the most powerful sources of electrical impulses. Domestic protective diodes (Kremniy, SZTP, Foton, STC SIT, Saransk, TOR, Russia and others) are not inferior in quality, efficiency and availability to foreign analogues.

Operating principles

Fig. 1 Protective diode - principle of operation of a semiconductor

There are two types of limiting zener diodes:

Protective diode, bidirectional, suitable for operation in alternating current networks.

The coding of protective diodes classified as symmetrical includes the letters “ C ” or “ CA ”. Single-ended diode fuses have a color-coded stripe on the cathode terminal side.

The housing of each protective diode is also equipped with a marking code that displays all significant parameters in a compressed form.

Introduction

To protect electronic equipment from surge voltages, various types of elements with a nonlinear current-voltage characteristic have been widely used, reducing their resistance under the influence of an applied voltage pulse.
The most widespread are three types of such elements: gas arresters, varistors and so-called suppressors (Transient Voltage Suppressor - TVS), made on the basis of avalanche diodes and therefore often called “TVS-diodes”. Gas arresters have a relatively long response time to an applied voltage pulse, and, in addition, their breakdown voltage increases very strongly with increasing rate of rise of the leading edge of the pulse. Therefore, their use is very limited. Zinc oxide varistors and TVS diodes, which are free from these disadvantages of gas dischargers, are much more often used. The advantage of varistors and TVS diodes becomes especially relevant when it is necessary to provide protection against powerful overvoltage pulses in the nanosecond range. Such a pulse occurs at the inputs and outputs of electronic equipment under the influence of a high-altitude nuclear explosion. An electromagnetic pulse from a high-altitude nuclear explosion (EMP) with parameters of 2/25 ns creates an electric field strength at the surface of the earth reaching up to 50 kV/m, and numerous cables connected to electronic equipment for industrial use absorb electromagnetic energy from a large area and deliver it directly to the inputs of sensitive electronic equipment. The amplitude of the pulse occurring at the inputs of this equipment significantly exceeds the amplitude of ordinary switching and atmospheric overvoltages, protection against which is provided in the equipment. That is why, to ensure reliable protection against nuclear radiation EMP, additional external means of protection are required, which can be varistors and TVS diodes. However, powerful TVS diodes are not cheap elements. Their cost reaches $100–150 or more per piece, while varistors of the same power are approximately 80–100 times cheaper. When it comes to the inclusion of additional protective elements in parallel with each input and output of electronic equipment with dozens of inputs and outputs, for example, such as microprocessor protection relays in the electric power industry, the relevance of the issue raised in the title of the article becomes clear. If cheap varistors cope with the problem no worse than much more expensive TVS diodes, it is clear that the advantage should be given to them. The only question is, do they really cope with the problem no worse than TVS diodes?

Significant characteristics of protection diodes

The voltage value at which the diode opens and the potential is transferred to the common wire. An additional synonymous designation is VBR.

Maximum reverse leakage current. It has a small value, measured in microamps, and the functionality of the device practically does not depend on it. Additional designation - IR.

The value is an indicator of constant reverse voltage. V.R.W.M.

The highest value for limiting impulse voltage. VCL, VCmax.

Indicator of the highest value of permissible pulse power. Unfortunately, this parameter is extremely dependent on the pulse duration.

Fig. 2 VA characteristics of the protective diode

A TVS diode can act as a zener diode. But first you need to check its maximum power dissipation and dynamic current at Imax. and Imin.

The influence of protective circuits on increasing the current load on switched contacts

The protective circuits under consideration practically do not increase the current load on the switching contacts: if there is a semiconductor diode in the protective circuit, the current load increases by the amount of the reverse current of the diode, which, having a value of up to several tens of microamperes, is very small compared to the current in the relay winding. The additional load on the switching contacts in the case of using a protective RC circuit is determined by the active leakage current of the capacitor, which is also very small and can not be taken into account. It should be noted that protective chains, by reducing the magnitude of switching overvoltages, facilitate the operating conditions of switching contacts.

Checking the integrity of the protective diode

Fig 3 Checking the protective diode

If a leak is detected during a pole change, we can talk about the dysfunction of the element and the need to replace it. Similarly, you can check the protective diode of a car generator.

Basic qualities of TVS diodes

But, as a result, it is necessary to recognize that the fulfillment of one condition often entails a violation of another.

Content

1. General part
2. Determination of parameters of protective chains
2.1 Zener diode
2.2 Diode resistor
2.3 Protection diode
2.4 Selection of protective RC chain
2.5 Selection of protective circuit diodes
3. The influence of protective circuits on increasing the current load on switched contacts
4. Safety chains recommended for use
5. Method for reducing switching overvoltages when using a transistor as a switching element
6. Examples of choosing diode protection against switching overvoltages
7. Selecting a security chain
8. Selection of security chain parameters
8.1 Diode selection
8.2 Selection of resistors
9. References

Designation, parameters and application of protective diodes

Let's consider what a TVS diode is, its principle of operation, in what circuits and for what purposes it is used.

Designation on the diagram.

On circuit diagrams, the suppressor (aka protective diode) is designated as follows (VD1, VD2 - symmetrical; VD3 - unidirectional).

Operating principle of a suppressor (protective diode).

For a unidirectional suppressor, the circuit looks a little different.

Basic electrical parameters of suppressors.

U arr. (V) – constant reverse voltage. Corresponds to the English abbreviation VRWM ( Working Peak Reverse Voltage ). May be referred to as VRM.

U limit imp. (V) – maximum impulse limiting voltage. In datasheets it is designated as VCL or VC – Max. Clamping Voltage or simply Clamping Voltage .

The value of the maximum pulse power can be found by multiplying the values of U limit. imp. ( VCL ) and I limit. max. ( IPP ).

The current-voltage characteristics of a symmetrical and asymmetrical TVS diode are as follows.

CVC of a unidirectional protective diode (suppressor) CVC of a bidirectional suppressor

For example, with a pulse duration of 50 microseconds, an SMBJ 12A diode can withstand a pulse current that is almost four times the rated one.

Diodes are available in DO-201 package.

Dimensions are indicated in inches and millimeters (in parentheses). Asymmetrical suppressors have a colored marking ring on the body, which is located closer to the cathode terminal.

The body contains the marking of the protective diode, which encodes its main parameters.

Types and designation

There are two main types of TVS protection diodes:

symmetrical (bidirectional) - actively used in circuits with bipolar voltage, which allows their use in alternating current networks;
asymmetrical (unidirectional) - effectively protect circuits with voltage of the same polarity, which allows their use in DC networks.

In the diagrams, suppressors are designated as VD1, VD2 (bidirectional) and VD3 (asymmetrical). The rated voltage of such diode fuses varies from 6.8 to 440 volts. And the operating temperature ranges from -65 to +175 degrees Celsius. High response speed reliably protects equipment from overvoltage. The diode fuse housing is equipped with a marking code that displays all the important parameters of the product.

The marking of protective diodes allows you to select the most suitable radio element for DC or AC networks. Asymmetrical products have a colored marking ring on the body. Numbers and letters usually indicate power, breakdown voltage, and permissible voltage deviation.

Operating principle of a suppressor (TVS diode)

This protective semiconductor has an interesting nonlinear current-voltage characteristic. If the pulse amplitude exceeds the reference data, it will go into avalanche breakdown mode. That is, the suppressor will limit the electrical impulse to the nominal value, and the excess will flow to the ground through it.

A TVS diode can be asymmetrical or symmetrical. The former are used to operate only in DC networks, because in operating condition they allow current to flow in only one direction. Symmetrical suppressors allow current to flow in both directions and are therefore capable of operating in AC networks. An asymmetrical protective limiter is included in the circuit in the opposite direction when installing conventional diodes, that is, the anode is connected to the negative bus, and the cathode to the positive.

If the input level increases, the protective semiconductor sharply reduces its internal resistance in a very short time. The current in the circuit increases sharply and the fuse blows. Since the suppressor operates almost instantly, the main circuit does not have time to burn out. A distinctive feature of TVS diodes is their very low response time to exceeding the voltage level.

Basic electrical parameters of suppressors

A huge disadvantage of suppressors can be considered the strong dependence of the maximum pulse power on the pulse duration. TVS diodes are available in various power levels. However, if these ratings are not enough, then the power can be increased by connecting several semiconductors in series. So, when two are connected, their total power doubles.

Limiting diodes can also be used as zener diodes. But in order to include TVS diodes in a circuit in this way, it is necessary to check reference data on the values of maximum power dissipation, as well as dynamic resistance under conditions of maximum and minimum possible currents.

Suppressors are characterized by a high rate of performance. Their response time is so short that the “bad” current pulses do not have time to cause damage to the equipment.

Source

Operating principle and device

Protection diodes consist of two plates made of germanium or silicon, which have different electrical conductivities. The wire leads of the electrodes are usually soldered to metal layers deposited on the outer surfaces of the plates. The design is enclosed in a plastic, metal-glass or ceramic case.

The operating principle of the protective diode is based on the use of reversible breakdown. As long as the voltage does not exceed the nominal value, the limiter does not have any significant effect on the operation of the circuit, but the device will go into avalanche breakdown mode as soon as the electric pulse amplitude exceeds the base voltage. Thus, the amplitude size is normalized, and all excess voltage goes to the ground through the limiter itself.