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Synchronous rectifier

First, the designer should choose the type of rectification technology that is most appropriate for the application. The choice is whether to use passive rectification in which semiconductor rectifiers are used or synchronous recification in which power MOSFE B are placed in parallel with a smaller passive rectifier. Synchronous rectifiers are typically used in battery operated portable products where the added efficiency, usually an added two to eight percent, is important to extend the operating life of the battery or in applications where heat is important. In today s switching power supplies, passive rectifiers can dissipate 40 to 60 percent of the total losses within the power supply. Synchronous rectifiers affect only the conduction loss, which can be reduced by as much as 90 percent. [Pg.57]

The silicon-controlled rectifier with a dc motor has become predominant in adjustable-speed drives for almost all commonly used conveyors when speed adjustment to process conditions is necessary. The low cost of this control device has influenced its use when speed synchronization among conveyors is required. This can also be done, of course, by changing sheave or sprocket ratios. [Pg.1913]

Another concept is brushless excitation, in which an ac generator (exciter) is direc tfy coupled to or mounted on the motor shaft. The ac exciter has a stator field and an ac rotor armature which is directly connected to a static controllable rectifier on the motor rotor (or a shaft-mounted drum). Static control elements (to sense synchronizing speed, phase angle, etc.) are also rotor-mounted, as is the field discharge resistor. Changing the exciter field adjusts the motor field current without the necessity of brushes or slip rings. Brushless excitation is suitable for use in hazardous atmospheres, where conventional brush-type motors must have protective brush and slip-ring enclosures. [Pg.2485]

Fig. 15-8 Synchronous current, voltage and potential recording with stray current interference from dc railways (a) Without protective measures, (b) direct stray current drainage to the rails, (c) rectified stray current drainage to the rails, (d) forced stray current drainage with uncontrolled protection rectifier, (e) forced stray current drainage with galvanostatically controlled protection rectifier (constant current), (f) forced stray current drainage with potentiostatically controlled protection rectifier (constant potential), (g) forced stray current drainage with potentiostatically controlled protection rectifier and superimposed constant current. Fig. 15-8 Synchronous current, voltage and potential recording with stray current interference from dc railways (a) Without protective measures, (b) direct stray current drainage to the rails, (c) rectified stray current drainage to the rails, (d) forced stray current drainage with uncontrolled protection rectifier, (e) forced stray current drainage with galvanostatically controlled protection rectifier (constant current), (f) forced stray current drainage with potentiostatically controlled protection rectifier (constant potential), (g) forced stray current drainage with potentiostatically controlled protection rectifier and superimposed constant current.
For those applications where high efficiency is important, synchronous rectification may be used on the higher current (power) outputs. Synchronous rectifier circuits are much more complicated than the passive 2-leaded rectifier circuits. These are power MOSFE B, which are utilized in the reverse conduction direction where the anti-parallel intrinsic diode conducts. The MOSFET is turned on whenever the rectifier is required to conduct, thus reducing the forward voltage drop to less than O.f V. Synchronous rectifiers can be used only when the diode current flows in the forward direction, that is in continuousmode forward converters. [Pg.60]

Figure 3-30 shows the common ways synchronous rectifiers are employed within switching power supplies. [Pg.60]

Figure 3-30 Common synchronous rectifier circuits (a) nonisolated (b) self-driven (c) transformer-coupled. Figure 3-30 Common synchronous rectifier circuits (a) nonisolated (b) self-driven (c) transformer-coupled.
As seen in Section 4.1, the major types of losses are the conduction and switching losses. Conduction losses are addressed by selecting a better power switch or rectifier with a lower conduction voltage. The synchronous rectifier can be used to reduce the conduction loss of a rectifier, but it can only be used for forward-mode topologies, and excludes the discontinuous boost-mode converters. The synchronous rectifier will improve the efficiency of a power supply about one to six percent depending upon the average operating duty cycle of the supply. For further improvements, other techniques must be pursued. [Pg.144]

Selection of the power switch and synchronous rectifier MOSFETs... [Pg.164]

Some control over the delay between the power switch and the synchronous rectifier MOSFE B. [Pg.166]

Direa connected exciters were once common for general purpose and large, high-speed synchronous motors. At low speeds (514 rpm and below), the direct-connected exciter is large and expensive. Motor gener ator sets and static (rectifier) exciters have been widely used for km speed synchronous motors and when a number of motors are supplict from a single excitation bus. [Pg.266]

Electric power is almost always transmitted as three-phase AC current. In domestic use, current is often distributed from a substation at 13,200, 6,600, or 2,300 V, which is stepped down by a transformer close to the point of use to 600, 480, and 240 V for three-phase current for commercial power and 240 and 120 V for single-phase, three-wire current for household power and lights. If DC current is required, synchronous converters or rectifiers are used to convert the AC supply to DC. [Pg.294]

Inverter-AC Motor Drives. An adjustable-frequency control of AC motors provide efficient operation with the use of brushless, high-performance induction, and synchronous motors. A typical system is shown in Figure. 3-14. Such a system consists of a rectifier (which provides DC power from the AC line) and an inverter (which converts the DC power to acljustable-frequency AC power for the motor). Inverter cost per kilowatt is about twice that of controller rectifiers thus the power convertor for an AC drive can approach three times the cost of a DC drive. [Pg.417]

Figure 3-14. Typical invester AC motor drive consisting of rectifier-DC link, adjustable-frequency inverter, and induction of synchronous motor [10]. Figure 3-14. Typical invester AC motor drive consisting of rectifier-DC link, adjustable-frequency inverter, and induction of synchronous motor [10].
When investigating filling records, one occasionally stumbles across values that seem to be way out of line. Does such a value represent normal operation, or has some other mechanism taken over, such as the blocking of a filling nozzle, poor synchronization in a cutting operation, or delivery of improper material In order to rectify the situation and avoid it in the future, it is important that the probable cause can be assigned. [Pg.242]

Power Supply Electrical precipitators are generally energized by rectified alternating current of commercial frequency. The voltage is stepped up to the required value by means of a transformer and then rectified. The rectifying equipment has undergone an evolution which began with the synchronous mechanical rectifier in 1904 and was... [Pg.62]

In row F calculate the synchronously rectified signal as the product of the terms in columns C and E. [Pg.317]

In cell D2 compute the average of the synchronously rectified signal as = SUM(F6 F406)/400. [Pg.317]


See other pages where Synchronous rectifier is mentioned: [Pg.301]    [Pg.48]    [Pg.301]    [Pg.48]    [Pg.1616]    [Pg.2485]    [Pg.113]    [Pg.233]    [Pg.60]    [Pg.135]    [Pg.25]    [Pg.178]    [Pg.155]    [Pg.74]    [Pg.335]    [Pg.339]    [Pg.192]    [Pg.192]    [Pg.193]    [Pg.1438]    [Pg.2240]    [Pg.371]   
See also in sourсe #XX -- [ Pg.60 ]




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