5 Things to Know Before Buying small signal switch diode

I read atleast 3 or 4 topics about diodes but in none of them actually I found something useful.
I just want to have a diode. Common diode
I will be using it sometimes for rectification (max 24V), as a flywheel (for reverse motor shitty things) and for similar things that just require something to prevent for wrong placed "+" and "-" wires. I read about 1N and did a google search plus I viewed its datasheet, but it says that there are "stronger" diodes - 1N to 1N... And I got confused...
So would you please suggest me a proper diode? Thanks in advance.

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The two most important specs are forward current and reverse voltage. I usually buy a higher voltage version (1N) since they don't cost much more and I'm usually buying more than I need so I don't know what I'll be using them for.

As a flyback (or flywheel) application the (peak) current through the diode will be the same as the current through the motor/coil, and the reverse voltage will be the applied voltage.* (So, in most low-voltage applications, voltage isn't an issue and you just have to check the current.)

I will be using it sometimes for rectification (max 24V)

When I'm building a power supply I usually use a [u]bridge rectifier[/u] which is 4 diodes in one package. I may have made a bridge from 4 1N's, but I don't remember. With a single diode, the power is "off" for half of the AC cycle which means you get more ripple (or you have to use a bigger capacitor) and you can only get half the current.

Or, if you have a center-tapped transformer you can get full-wave rectification with two diodes.

The forward voltage across a standard silicon diode is about 0.7V (depending on current) and in some applications where you want a smaller voltage drop, you can use a Schottky diode. Schottky diodes also switch faster than standard silicon diodes so they are sometimes used in high-frequency circuits.

• When you disconnect an inductor/coil you get a high-voltage kick (back EMF). But, since the diode is "backwards", that back EMF becomes the forward voltage across the diode. That "kills" the high-voltage kickback, and your diode never sees high voltage.

It depends what you want to do. Most of the time it is probably not so important. If you have supply voltage 20V or more it is not so important if the diode drops 0.7 or 0.3V. If motor needs 1A you don't care if diode leakage is 1mA or 10uA. If you want something more delicate such as reverse voltage protection difference between normal and Schottky diode may be more important if the battery voltage is close to your intended operating voltage. OTOH if you build some analog circuit "large" leakage current of Schottky may cause problems.

Another important spec - diodes rated for large current are also large - they have thick leads and they are difficult to stick into solderless breadboard. I even got diodes too thick to fit into hole in protoboard.

1. Forward conduction pressure drop

Voltage drop: Voltage drop, or voltage drop for short, is the change in the diode's potential (potential) relative to the same reference point after current flows through the load.

Turn-on voltage drop: When the diode begins to turn on, this voltage is the matching voltage.

Forward characteristics: When a forward voltage is given to the diode, the forward voltage is very low at the start of the forward characteristic, and the forward current is nearly nil because the forward voltage is insufficient to overcome the blocking effect of the electric field in the PN junction. The diode conducts forward when the forward voltage is big enough to overcome the electric field of the PN junction, and the current grows rapidly as the voltage rises.

Reverse characteristics: The current through the diode is a reverse current created by the drifting movement of minority carriers when the applied reverse voltage does not exceed a specified range. The diode is in an off state since the reverse current is so minimal. The diode reverses breakdown after the reverse voltage rises to a particular level.

The link between conduction current and forward conduction voltage drop

The internal electric field area narrows when a forward bias voltage is provided to both ends of the diode, allowing a higher forward diffusion current to pass through the PN junction. The diode can only switch on when the forward voltage exceeds a particular level (known as the "threshold voltage"; the germanium tube is about 0.2V, while the silicon tube is about 0.6V). Is the diode's conduction voltage drop, however, constant? What link does it have with the forward diffusion current? The SM360A diode's conduction current and conduction at room temperature as measured by the test circuit depicted in Figure 1 below. The voltage drop relationship test can yield the curve relationship displayed in Figure 2: The floating voltage difference is 0.2V, and the forward conduction voltage drop is proportional to the conduction current. Although the voltage difference between the light-load conduction current and the rated conduction current is just 0.2V, it affects not only the efficiency but also the temperature rise of the power diode, so try to choose the conduction voltage drop if the price conditions allow. A diode that has a tiny rated operating current that is double the real current.

　Diode conduction voltage drop test circuit

The relationship between on-voltage drop and on-current

The influence of high and low-temperature conditions on electronic components is the main hurdle to stable product functioning in our product development process. The diode is no exception to the fact that ambient temperature has a significant impact on most electrical components. The relationship curve of the measured data sheet 1 of SM360A and Figure 3 can be known in high and low temperature environments: the diode's conduction voltage drop. The ambient temperature has an inverse relationship with it. Although the conduction voltage drop is greatest at -45°C, it has no effect on the diode's stability; nonetheless, when the ambient temperature is 75°C and the case temperature exceeds the 125°C mentioned in the data sheet, the diode must be derated for operation at 75°C. One of the reasons why the switching power supply must be derated for operation at a given high temperature point is because of this.

Test data of conduction voltage drop and conduction current

The relationship between the conduction pressure drop and the ambient temperature

2. Rated current, maximum forward current IF

The average current value estimated based on the operational temperature rise during the long-term operation of the diode is referred to as the rated current IF. The present maximum power rectifier diode's IF value can reach A.

Its value is connected to the PN junction area and external heat dissipation circumstances, and it relates to the highest forward average current value that the diode is allowed to pass through for a long period continuously. Because the current traveling through the tube heats up the die, which raises the temperature. The die will overheat and be damaged if the temperature exceeds the permitted limit (approximately 141 for silicon tubes and about 90 for germanium tubes). As a result, during usage, do not exceed the diode's maximum rectified current value under the specified heat dissipation circumstances. The ubiquitous IN- germanium diodes, for example, have a rated forward operating current of 1A.

3. Maximum average rectified current Io

Maximum average rectified current IO: The maximum value of the average rectified current flowing through the load resistance in a half-wave rectifier circuit. When converting the design, this is a critical value.

4. Maximum surge current IFSM

The operation is experiencing an excessive amount of forwarding current. It is an instantaneous current, not a regular current. This is a significant amount of money.

5. Maximum reverse peak voltage VRM

Even if there is no reverse current, the diode will be broken sooner or later if the reverse voltage is repeatedly increased. The reverse voltage that can be applied is a series of forwarding and reverse voltages that are applied repeatedly. The maximum value of the AC voltage is a defined critical factor since it is applied to the rectifier. The maximum reverse peak voltage, or VRM, is the highest reverse voltage that can be applied without causing a breakdown. The maximum VRM value currently available is several thousand volts.

6. Maximum reverse voltage VR

The highest reverse peak voltage indicated above is the peak voltage that is repeatedly applied, and VR is the amount of continuous DC voltage application. The maximum DC reverse voltage is critical in defining the allowed value and upper limit for DC current.

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7. Maximum operating frequency fM

When the working frequency of a PN junction surpasses a specific value, its unidirectional conductivity deteriorates due to the presence of the junction capacitance. The fM of a point contact diode is higher, exceeding 100MHz; the fM of a rectifier diode is lower, typically not exceeding a few thousand Hz.

8. Reverse recovery time Trr

The optimal circumstance for the diode to work is for the current to be turned off instantly when the forward voltage shifts from forward to reverse voltage. In fact, there is usually some lag time. The reverse recovery time is the quantity that determines the current cut-off delay.

9. Maximum power P

The diode absorbs heat and raises its temperature as current travels through it. The maximum power P is the highest power value. Specifically, the current flowing multiplies the voltage across the loading diode. For Zener diodes and variable resistance diodes, this limit parameter is especially essential.

10. Reverse saturation leakage current IR

When a reverse voltage is applied across a diode, the current flowing through it is called reverse current. The current is proportional to the temperature and semiconductor material. The IR of the silicon tube is nA (10-9A) at ambient temperature, while the IR of the germanium tube is mA. (10-6A).

11. Derating (junction temperature derating)

Derating can help extend the life of a product and increase its reliability. The lowest derating junction temperature data for tubes with different rated junction temperatures are listed below, based on the idea that the temperature is dropped by 10°C and the service life doubles.

                                                                                                  Table 1 Diode DeratingRated valueTjM125℃150℃175℃200℃TjM that can be used after derating110℃135℃160℃185℃

12. Safety regulations

The power device should be the key consideration during the selection stage, as well as if the device has passed the safety certification. UL (North America), CSA (Canada), TUV (Germany), VDE, and other types of safety certification are generally recognized by many countries.

13. Reliability design

Correctly pick the device and the circuit design, mechanical design, and thermal design that surrounds it to manage the device's operating conditions throughout the entire machine, avoid various inappropriate stresses or operations from destroying the device, and maximize the device's inherent reliability.

14. Tolerance design

The permissible range of device characteristics (including manufacturing tolerance, temperature drift, and time drift) should be relaxed when designing a single board to ensure that the single board can function normally when the device parameters shift within a given range.

15. Prohibition of optional packaging

The use of an axially inserted diode package is prohibited, as is the use of an open-junction diode.

OPEN JUNCTION's wafer diffusion method is known as O/J. The wafer is then split into crystal grains once it has been diffused. The crystal grains' edges are jagged, and the electrical characteristics are insecure. The edges must be washed with a mixed acid (the primary component is hydrofluoric acid), then wrapped in silica gel and encapsulated molding; however, the reliability is poor.

Glassivation passivation parts, or GPP for short, is the generic word for glass passivation devices. This product is based on existing standard silicon rectifier diffuser diffusers that burn a layer of glass around the P/N junction of the divided die. Glass and monocrystalline silicon have strong bonding properties, allowing the P/N junction to be optimally insulated from the external environment, improving the device's stability and dependability.

The heat dissipation of O/J is not as good as that of GPP, and the two have fundamentally different basic structures: Pickled O/J chips must be soldered with copper sheets and wrapped in silica gel. GPP chip rectifier bridge has a greater internal structure than GPP. It is directly welded to the copper connecting piece of the rectifier bridge, eliminating the stages of pickling and applying silica gel. The internal structure of the chip is much smaller than that of O/J chips. It leads to intuitive and habitual misperceptions.

A comprehensive evaluation of GPP chip and OJ chip:

1. The GPP chip completes glass passivation at the wafer stage and can do VR probe testing, whereas the OJ chip can only test VR after the product has been assembled.

2. VRM is a V GPP chip that is grooved and passivated from the P+ surface, and the mesa has a negative bevel structure (the surface electric field strength is higher than that in the body), whereas the OJ chip's cutting has no bevel.

3. Unlike the GPRC chip, which applies glass passivation to the entire section, the GPP chip distributes glass passivation in the pn junction area, whilst the OJ chip applies silicone rubber protection to the entire section.

4. Mechanical cutting leaves a cutting damage layer on the GPP chip, whereas chemical etching may erase the cutting damage layer on the OJ chip.

5. The GPP chip is passivated with a unique high-temperature molten inorganic glass layer, which improves Tjm and HTIR stability over silicone-protected OJ products.

6. Miniaturization, thinness, and LLP packaging are ideal for GPP chips, whereas lead-out packaging is ideal for OJ chips.

The difference in the production process:

(1) The soldering, pickling, passivation, whitening, curing, and baking processes are all required for the OJ chip, and its electrical qualities (reverse voltage) are intimately related to the packing and pickling processes. Plug-in packaging is the most common type of packaging.

(2) In addition, the chip manufacturing process at GPP includes pickling and passivation. The chip determines its electrical properties directly, and the patch type is the most frequent sealing form.

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