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12 1-800-735-6200
VI-HAM
Harmonic Attenuator Modules
Features
s Unity Power Factor s Safety Agency Approvals: UL, CSA, TUV, BABT s Meets IEC 6100-3-2 for Line Current Harmonic Content s Reduces Peak and RMS Line Currents s Universal Input: 85-264Vac: 50/60 Hz s Up to 600W of Power s Power Density Up to100W/in3 s Adaptive Output Voltage Control s Short-Circuit Protection s Input Surge Current Limiting s Converter Enable s Power OK Output s Size: 4.6" x 2.4" x 0.5" (116,8mm x 61,0mm x 12,7mm) s Efficiency: 90-94% Typical s CE Marked
Unity Power Factor
Conventional capacitive-input front ends draw energy from the AC line in short bursts of current at the peaks of the line voltage waveform. These current bursts are characterized by high peak currents and high harmonic content. The effect of the distorted line current can be appreciated by measuring the rms line current drawn by a conventional front end: the product of the measured rms current and the rms line voltage -- the "apparent power" being delivered by the line -- will be significantly greater (typically 1.6X) than the DC power delivered by the front end. The "extra" rms current at the input is circulating harmonic currents which deliver no power to the load but which flow in the delivery system and contribute to losses. Only the fundamental component of the line current contributes to "real" power flow. Power factor -- the ratio of "real" to "apparent" power -- is a measure of the effectiveness with which an AC load can extract usable power from an AC source. The VI-HAM (see Fig. 2) consists of a full-wave rectifier, a proprietary high-frequency zerocurrent switching (ZCS) boost regulator (patents applied for), active inrush, short-circuit protection, control and housekeeping circuitry. The incoming AC line is rectified and fed to the ZCS boost converter. The control circuitry varies the operating frequency of the ZCS boost converter so as to simultaneously maintain the output voltage of the HAM at a DC voltage value above the peak of the incoming line, while forcing the input current to the ZCS converter to follow the waveshape of the rectified line. By this means, the AC input current follows the AC voltage waveform and a power factor better than 0.99 is achieved. Operating efficiency of the ZCS boost converter is optimized at any incoming line voltage by a patented adaptive output voltage control scheme. The HAM also includes active circuitry which controls inrush currents when power is applied and active short circuit protection circuitry -- features not normally found in conventional power factor correctors. Housekeeping circuitry provides two signals of use to the system designer (see Fig. 2): Module Enable and Power OK. Referencing the timing diagram (see Fig. 3), the Module Enable signal, which is connected to the Gate In inputs of the Vicor DCDC converters powered by the HAM, will come high and enable the DC-DC converters when the HAM output voltage exceeds 240Vdc. The DC-DC converter voltage outputs will be up approximately 10 ms after Module Enable goes high. Typically, 20 ms after Module Enable goes high the HAM Power OK signal, which can be used by the system designer to enable circuitry powered by the DC-DC converter modules, goes low. On loss of power or brownout, the Power OK signal will go high when the HAM DC output voltage drops below 230V, signaling an impending loss of input power to the converter modules. When the DC output dips below 195V, the Module Enable signal will toggle low, disabling the converter modules and unloading the HAM. The HAM will provide at least 16 ms of ride-through or holdup time, and at least 5 ms of AC fail warning time with a 1000 F output capacitor.
Figure 1a.
AC Line
Rectifier
ZCS Boost Converter
Current Sense
Inrush & Short Circuit Protection
+ DC Out - Note: Non-Isolate Output
Voltage Waveform
High Frequency Control Output Voltage Control Module Enable & Housekeeping Power OK Circuitry Aux. Supply
Figure 1b. Above: Oscilloscope photos showing input voltage and current without power factor correction (A) and with power factor correction as provided by the VI-HAM (B).
Gate In Gate Out NOTE: No input to output isolation.
Figure 2 * VI-HAM Block Diagram
12 1-800-735-6200
AC Mains 120V RMS 230 Vdc DC Output of HAM Boost Voltage 240 Vdc Rectified Line 195 Vdc
Module Enable
Off at 195 Vdc
25 ms Power OK Off at 230 Vdc
Vicor varies the output voltage of the HAM as a function of incoming AC line voltage (see Fig. 4, patent applied for). On a nominal 120Vac line the output voltage of the HAM is 260Vdc -- well within the input operating voltage range of standard Vicor converters. As input line increases, so does the HAM output voltage; at 220Vac the delivered voltage will be about 350V. For any given input line voltage, the HAM maintains enough headroom between the output voltage and peak input voltage to ensure high quality active power factor correction without unnecessarily sacrificing operating efficiency.
VI-HAM Protection Features
Overtemperature Shutdown The HAM incorporates overtemperature shut-down, and is designed to shut down when the temperature of the baseplate exceeds 90-100C. It is not safe to run the HAM for extended periods above its maximum operating temperature of 85C. Short Circuit Protection The HAM contains a short circuit shutdown function. Operation of this function does not clear the input fuse and the output will resume normal operation after removal of the short. A small period of time may be required to allow for cooling of an internal PTC. Overcurrent protection is provided by the Vicor DC-DC converters. Output Overvoltage Protection The HAM contains output overvoltage protection. In the event the output voltage exceeds approximately 420Vdc, the boost will decrease to maintain 420Vdc on the output. When the peak of the AC line exceeds 420V (approximately 293Vac) the boost will have been reduced to zero. Beyond this the protection circuit will be enabled and the output voltage will decrease.
Outputs VI-200 DC-DC Converter(s)
10 ms
400 Vdc 350 Vdc 300 Vdc 250 Vdc 200 Vdc 80 Vac 260 Vdc 152 Vac 85 Vac
250 Vac
46V Boost
Output Voltage as a Function of Input Voltage
Figure 3 * Functional Timing Diagram Active power factor correctors incorporate a boost regulator which must operate over a range of incoming AC line voltages. Conventionally, the output voltage of the boost regulator is set to a value greater than the maximum anticipated peak value of the incoming AC line.
150 Vdc 100 Vdc 50 Vdc Vin x 2 Operating Region 75 50 100 125 150 Vac 264 Vac
25
175 200
225 250
275 300 296
Figure 4 * Input Voltage vs. Output Voltage
Pin Function Description
* L1 and L2/N (VI-HAM): These pins are to be connected to the AC mains output of a suitable EMI/RFI filter (Vicor P/N 07818 or equivalent). Do not connect an X capacitor across these pins as power factor correction will be slightly degraded. * +IN, -IN (VI-HAMD, VI-BAMD): These pins are connected to the output of the external bridge rectifier. * Gate Input (VI-HAM): This pin disables the boost converter only. Rectified line current may still be present on the output. This pin does not provide the same function as the gate input pin of VI-200/VI-J00 modules. The user should not make any connection to this pin. * Gate Input (VI-HAMD): This pin serves as a rectified AC following pin for power factor correction synchronization to line. This connection must be made through the synchronization diodes between the line filter and bridge rectifier (see Fig. 10, page 84). * Gate Input (VI-BAMD): The Gate Input pin is an interface pin to the Gate Out pin of a VI-HAM, VI-HAMD or VI-BAMD depending on configuration. The user should not make any other connection to this pin. * Gate Output: The Gate Output pin is an interface pin to BAMDs; the user should not make any other connection to this pin. * +Output and -Output and Holdup Capacitor: These outputs should be connected to the respective inputs of Vicor DC/DC converters. In addition, an external holdup capacitor of 1000 F with a minimum voltage rating of 450Vdc, is required across the output for 16 ms ride through time at 600W (500 F for 300W, etc). Do not exceed 3000 F of total output capacitance. Lower values of capacitance may be used for reduced holdup requirements, but not less than 330 F. Lower capacitance values may degrade power factor specifications. * Auxiliary Supply (A/S): The VI-HAM and VI-BAMD contain an internal low voltage output (A/S) that may be used to power primary side logic. This output is 19-23Vdc, referenced to -OUT, at 3 mA max. Do not overload or short this output as the HAM will fail. A typical use for A/S is to power an optical coupler that isolates the Power OK signal. This provides sufficient time for the converters to turn on and their outputs to stabilize prior to P/OK being asserted. When the AC mains is removed and the output of the HAM drops below 230V, P/OK goes to an open circuit state. When the output voltage drops below 195V the converters are disabled via Module Enable. P/OK will provide power fail warning at least 1 ms prior to converter shutdown.
D LOGIC G S
P/OK
-OUT
Figure 6 * Power OK (P/OK)
+ 19 - 23V - A/S 3mA -OUT
"Power OK" Status Low = OK + OUT P/OK E/O A/S - OUT 18 k, 1/4W
Figure 5 * Auxiliary Supply (A/S)
* Power OK (P/OK) P/OK is a monitor signal that indicates the status of the AC mains and the DC output voltage of the HAM. P/OK, during normal operation, is an active low (see Fig. 6). In the event AC mains or DC output fails, this pin goes to an open circuit state. P/OK is asserted when the output bus voltage is within normal operating range and 20-25 ms after DC-DC converters are enabled by the Module Enable output of the HAM.
* Module Enable (E/O) The Module Enable output is used to disable the DC-DC converters until there is sufficient energy in the holdup capacitor (240V) to support normal operation, while limiting inrush current. Module Enable must be connected to the Gate Input of all driver DC-DC converters. It is not necessary to connect this pin to boosters as they are controlled by their respective driver. If the AC mains fail, Module Enable goes low when the DC output of the HAM drops below 195V. Failure to connect Module Enable may result in the output of the HAM latching low during turn-on.
E/O D LOGIC G S
-OUT
Figure 7 * Enable/Output (E/O)
12 1-800-735-6200
VI-HAM Protection Features
(continued)
Inrush Current Limit
Filter Requirements for the VI-HAM
The VI-HAM requires an external filter to meet international standards for conducted EMI/RFI emissions. P/N 07818 (for use up to 600W) incorporates transient protection for compliance with IEC 61000-4-5 Level 3 and meets conducted emissions standards EN55022 and FCC Part 15 Level A (minimum loading of 150W required).
The HAM contains inrush current protection in the form of a PTC and a shunt device. The same PTC is used for overcurrent protection on the output.
Input Transient Overvoltage Surge Protection
This function is included in all HAM compatible filters. If any other filter is used this function must be provided externally, typically by a transient suppressor. * Safety Note * All VI-HAM configurations must be preceded by an appropriately rated fast-blow 3AG fuse ahead of the line filter. This fuse would be a 10A for a single VI-HAM connected to line. For fusing information on other VI-HAM configurations, please contact Vicor's Application Engineering Department.
VI-HAM Configurations
VI-HAM-CM Driver HAM: Fully configured power factor correcting front end.
VI-HAMD-CM Driver HAM: No internal bridge rectifier or synchronization diodes. VI-BAMD-CM Booster HAM: Companion module to VI-HAMD-CM used for additional output power. No internal bridge rectifier.
Compatible Modules
Over the full range of input voltages (85 to 264 Vac), the output varies from 260 to 415Vdc. Therefore the modules used with the HAM are from the VI-260 and VI-J60 families. When ordering add the prefix VI- to the part number below; i.e., VI-260-CU. VI-200 Family 5V 12V 15V 24V 48V Output
Use the VI-HAM-CM for applications requiring up to 600W from the front end. For applications in excess of 600W, it is not possible to simply parallel two driver HAMs due to conflicting control loops. Gate Out to Gate In connections on respective driver/boosters are used to ensure that the power train of the HAMs current-share. However, this does not ensure that the diodes in the lower half of the bridge rectifier will current-share. A solution for this situation is illustrated (see Fig. 8).
VI-HAMD
260-CU 261-CU 262-CU 263-CU 264-CU 200W 260-CV 261-CV 262-CV 263-CV 264-CV 150W 260-CW 261-CW 262-CW 263-CW 264-CW 100W 260-CX 261-CX 262-CX 263-CX 264-CX 75W 260-CY 261-CY 262-CY 263-CY 264-CY 50W Framed area available as boosters. Change VI-2XX-XX to VI-BXX-XX.
Vac Line Filter
VI-BAMD
VI-BAMD
Figure 8 * VI-HAMD with Booster HAMs (BAMDs) -- No Internal Bridge Rectifier 48V Output
VI-J00 Family 5V 12V 15V 24V
J60-CW J61-CW J62-CW J63-CW J64-CW 100W J60-CX J61-CX J62-CX J63-CX J64-CX 75W J60-CY J61-CY J62-CY J63-CY J64-CY 50W J60-CZ J61-CZ J62-CZ J63-CZ J64-CZ 25W
A solution to bridge rectifier current sharing issues is to remove the bridge rectifier from each HAM and use one diode bridge sized to handle the entire load. Approximately 25% of the heat is removed from the HAM in this approach; use a VI-HAMD-CM with one or more VI-BAMD-CMs. Note: Synchronization diodes are required when using this approach (see Fig. 10, page 84).
Prod. Grade
E C I M
Baseplate Temp.
-10C to +85C -25C to +85C -40C to +85C -55C to +85C
Storage Temp.
-20C to +100C -40C to +100C -55C to +100C
Model
VI-HAM-EM VI-HAM-CM VI-HAM-IM
-65C to +100C VI-HAM-MM
12 1-800-735-6200
Specifications
VI-HAM and VI-HAMD With External Bridge and Synchronization Diodes, 1000 F Output Capacitor and Vicor Line Filter P/N 07818. VI-BAMD When Operated with VI-HAM and VI-HAMD, Respectively.
(Unless otherwise indicated, specifications apply over operating input voltage and temperature range)
Parameter Line Input 47-63 Hz Output Power VI-HAM 85V to 264V (Volts AC) Up to 600W VI-HAMD 85V to 264V (Rectified AC) Up to 600W 90-91% (With ext. rectifier loss) 93-94% (With ext. rectifier loss) 0.99 <7.5% <8.5% 7V p-p 5V p-p <13A peak <20A peak 500-3000 F 16 ms Included in the external filter VI-BAMD 85V to 264V (Rectified AC) Up to 600W 90-91% (With ext. rectifier loss) 93-94% (With ext. rectifier loss) 0.99 <7.5% <8.5% 7V p-p 5V p-p <13A peak <20A peak 500-3000 F 16 ms Included in the external filter Isolation provided by DC-DC converters Note: Not short circuit protected Remarks Unit will operate from 400 Hz, but may not meet PF or THD specs Derate from 110Vac to 85 Vac @ 8W/Volt 120Vac, full load 240Vac, full load 120/240Vac, 50-100% of full load Sinusoidal, 120Vac, full load Sinusoidal, 240Vac, full load 120Vac, full load 240Vac, full load 120Vac, full load 240Vac, full load External to HAM (for 600W load) (1000 F Nom.) 600W output with a 1000 F holdup capacitor (300W = 500 F, etc.)
Efficiency 90-91% Efficiency 93-94% Power Factor 0.99 Total Har. Distortion (line current)* <7.5% Total Har. Distortion (line current)* <8.5% Output Ripple 7V p-p Output Ripple 5V p-p Inrush Current <13A peak Inrush Current <20A peak Output Capacitance 500-3000 F Ride Through/Holdup Time Transient Surge Withstand, Normal Mode Isolation Voltage Input to Output Input to Baseplate Output to Baseplate Auxiliary Output Thermal Shutdown Baseplate Temperature Storage Temperature Short Circuit Protection MTBF (GB, 25C) Size Weight
* ITHD = HAMTHD - VTHD
Line current total harmonic distortion = input voltage distortion plus 8.5% max.
16 ms Included in the external filter
None None None 1,500 VRMS 1,500 VRMS 1,500 VRMS 1,500 VRMS 1,500 VRMS 1,500 VRMS 19-23Vdc 19-23Vdc 19-23Vdc @ 3 mA @ 3 mA @ 10 mA 90C-100C baseplate 90C-100C baseplate N/A -10C to +85C (E Grade) -25C to +85C (C Grade) -40C to +85C (I-Grade) -55C to +85C (M-Grade) -40C to +100C (C Grade) -55C to +100C (I-Grade) -65C to +100C (M-Grade) Yes Yes Yes >420,000 hours >424,000 hours >818,000 hours 4.6" x 2.4" x 0.5" 4.6" x 2.4" x 0.5" 4.6" x 2.4" x 0.5" (116,8 x 61,0 x 12,7) (116,8 x 61,0 x 12,7) (116,8 x 61,0 x 12,7) 6 Ounces (170 Grams) 6 Ounces (170 Grams) 6 Ounces (170 Grams)
Application of the VI-HAM
The HAM must be used in conjunction with a suitable line filter, such as Vicor's P/N 07818**, output holdup capacitor and Vicor DC-DC converters (see Fig. 9). Connect single phase AC mains to the input of the line filter via a standard 10A AC fuse. Connect the output of the filter to L1 and L2/N of the HAM. Do not put an X capacitor across the input of the HAM or use a line filter with an X capacitor on its output as power factor correction may be impacted. Connect the +Output of the HAM to the +Input of the converters via a 3A PC Tron DC fuse. Connect the -Output of the HAM to the -Input of the converters. Connect a 1000 F electrolytic capacitor rated at a minimum of 450Vdc across the + and -Output of the HAM (or 500 F for 300W, etc). This capacitor must be in close proximity to the HAM. Connect the Enable Output of the HAM to the Gate Input of each driver converter to disable the converters until the output of the HAM is within normal operating range. Please refer to Vicor's Applications Manual for information on the proper connection of the DC-DC converters. The aforementioned connections are the minimum required. In addition, there are other features available. * The Auxiliary Supply output is approximately 21V at 3 mA max. This output is usually used in conjunction with the Power OK signal. Power OK provides an indication of the status of the DC output and the AC mains. * The Enable Output of the HAM must be connected to the Gate Input of all driver modules. The HAM will then disable the module output until the input exceeds 85Vac and the output has been boosted to 260Vdc. If an external load is connected directly to the output of the HAM, do not apply the load until the output of the HAM is in boost mode. * Although the efficiency of the HAM is quite high, it still dissipates significantly more power than a VI-200 DC-DC converter. Care should be taken to cool it. Thermal compound should be used between the heatsink and baseplate of the VI-HAM, VI-HAMD and VI-BAMD. * When making any connections to the VI-HAM for measurement purposes, remember that it is not isolated from the line -- either input or output. A line isolation transformer must be used when making scope measurements. * The input voltage range of the VI-HAM is 85 to 264Vac; however it may not start boosting until the AC mains has exceeded 87Vac. Once the VI-HAM has started, it will operate down to 85Vac. The VI-HAM contains 2.5 to 6V of input hysteresis, therefore if the AC line impedance is high, i.e., when using a variable autotransformer, the VI-HAM may start, but the AC line may then fall enough to drop below undervoltage lockout. When this happens the AC line will go up, the HAM starts and the cycle repeats. Therefore avoid soft AC lines at or near low line.
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Connection Diagram, VI-HAM/DC-DC Converters
10A
MOV P/N 03040
260-400 Vdc Up to 600W
PC-Tron 3A
Vicor 26X or J6X Family Converters +IN GATE IN GATE OUT -IN Driver +OUT +S T -S -OUT
L1 GND L2/N
LINE
L1 Vicor Line Filter P/N 07818 6.3A L2/N
LOAD
L1 GATE IN GATE OUT L2/N
VI-HAM
+ OUT P/OK E/O A/S - OUT
1000 F
+
PC-Tron 0.5A
Module Output Voltage
24V Zener (1N4709)
Y-Capacitor +IN
PC-Tron 3A
Holdup Box (HUB) available as accessory product through Vicor Express 270F HUB270-P 470F HUB470-P 870F HUB870-P 1100F HUB1100-P 150W max 300W 450W 600W
+OUT
GATE IN
Booster (n) GATE OUT -IN -OUT
Figure 9 * VI-HAM Connection Diagram
Y-Capacitor
Connection Diagram, VI-HAMD/VI-BAMD
10A
+IN GATE IN
20A
+OUT P/OK E/O A/S -OUT
1000 F @ + 450 Vdc
Input L1 L1
1N4006
Bridge Rectifier
+ -
10A
GATE OUT -IN
HAMD
MOV P/N 03040
GND L2/N
Line Filter 12.6A*
1N4006
L2/N 410V Transorb 1.5 KE 130CA 1.5 KE 130CA 1.5 KE 150CA
+IN GATE IN BAMD GATE OUT -IN
+OUT N/C N/C A/S -OUT
1000 F @ + 450 Vdc
* Please consult Vicor's Application Engineering Department for specific VI-HAMD/VI-BAMD filtering information.
Figure 10 * VI-HAMD/BAMD Connection Diagram
VI-HAM / HAMD / BAMD Mechanical Diagram
.50 (12,7)
.30 (7,6) .015 (0,38)
4.60 (116,8) 3.60 (91,4) 1.80 (45,7)
.080 (2,0) Dia. (2) places Solder plate over copper alloy 9
4 2.10 (53,3) 3
Pin # HAM HAMD 1 L1 +IN 2 Gate In Gate In 3 Gate Out Gate Out 4 L2/N -IN 5 +Out +Out 6 P/OK P/OK 7 E/O E/O 8 A/S A/S 9 -Out -Out
BAMD +IN Gate In Gate Out -IN +Out N/C N/C A/S -Out
2.40 (61,0) .30 (7,6) Min 1.75 (44,5)
VI-HAM
2 1
8 7 6 5
1.40 1.00 (35,6) .70 (25,4) .40 (17,8) (10,2) .35 (8,9) .015 (0,38)
Aluminum Base
4.20 (106,7) .22 (5,6) MIN
.15 (3,8)
FULL R .15 (3,8) Product ID this surface
.040 (1,0) Dia (7) places Solder plate over copper alloy .12 (3,0)
.50 (12,7)
+.030 (0,76) -.000
.01
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Typical HAM Filter Applications
Operating voltage = 85 to 250Vac Operating current = 6.3A Operating frequency = 50/60 Hz Operating temperature = 20 to 50C Diel. withstanding (line - case) = 1500Vac Diel. withstanding (line - line) = 1500Vac Leakage current = 1.0 ma at 220Vac, 50 Hz Max residual voltage after 1 sec. = 34V Agency approvals = UL, CSA, TUV
LINE
MOV P/N 03040
R
Cx
LD
D2 D3
Cy
HAM Filter P/N 07818 Cx = 1.5uF(x2)SH Cy = .01uF SH LC = 6.9mH LD = .72mH R = 235K OHM D1,2 = 1.5KE130CA D3 = 1.5KE150CA
RATED CURRENT VS AMBIENT TEMPERATURE OPERATING TEMP (DEG C) 90 INSERTION LOSS (db) 80 70 60 50 40 1.0 2.0 3.0 4.0 5.0 6.0 7.0
90 80 70
DM
60 50 40 30 20 10 0 .01 .02 .04 .1 .4 1 4 10 .07 .2 .7 2 7 20 FREQUENCY (MEGAHERTZ) 40 70 100
CM
CURRENT (AMPS)
HAM Filter Mechanical Diagram
4-40 INSERT .25 DP 4 PL 4.60 .02 2.50 1.200
o.080 PIN 6 PLACES
.060
SEE NOTE 1
2.40 .02 2.00 .100
LOAD
LINE
FACE MAY BE BOWED .04 MAX 1.800 .900 .30 .02 .13 .02
VICOR LABEL SEE NOTE 2
.500
.500
1.45
2.800
1.00 MAX '0'
LOAD
LC
Cy
D1

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