Crescend Technologies 7VB916-0140 800VC015-0R2RF User Manual
Crescend Technologies LLC 800VC015-0R2RF Users Manual
Users Manual
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| Document ID | 60536 |
| Application ID | ZAXttDUUco8EnJriOhISjg== |
| Document Description | Users Manual |
| Short Term Confidential | No |
| Permanent Confidential | No |
| Supercede | No |
| Document Type | User Manual |
| Display Format | Adobe Acrobat PDF - pdf |
| Filesize | 1.98kB (24718 bits) |
| Date Submitted | 1999-09-24 00:00:00 |
| Date Available | 2000-02-16 00:00:00 |
| Creation Date | 2001-05-25 17:03:39 |
| Producing Software | Acrobat Distiller 4.0 for Windows |
| Document Lastmod | 2001-05-25 17:03:40 |
| Document Title | Users Manual |
VOCOM Products RF Amplifiers Instruction Manual For Model 800VC28-015-XXR RF Power Amplifiers THE FOLLOWING INSTRUCTIONS ARE FOR USE BY QUALIFIED RF SERVICE PERSONNEL ONLY. SERVICE PERFORMED ON VOCOM’S AMPLIFIERS MAY VOID THE MANUFACTURER’S WARRANTY VOCOM Products Company, L.L.C. 2255 Lois Drive Suite 1 Rolling Meadows, IL 60008 Quality since 1979 TABLE OF CONTENTS 800VC28-015-XXR RF POWER AMPLIFIER SECTION 1.0 OPERATING INSTRUCTIONS SECTION 2.0 SPECIFICATIONS SECTION 3.0 TEST SECTION 4.0 PROPER AMPLIFIER SETUP SECTION 5.0 APPLICATION NOTE SECTION 1: OPERATING INSTRUCTIONS GENERAL: To effectively use the 800VC28-015-XXR RF power amplifier, the operation capabilities of the unit must be known. This section describes input/output connections and environmental operating conditions. Understand the operating of limitations of the amplifier before installation is attempted. OPERATING VOLTAGES: Warning: This unit is designed for operation from 28 volts DC negative ground systems. The chassis must be kept at earth potential. The negative (black) DC power lead is connected directly to the chassis. Operation in positive ground systems may cause injury. All power measurements and specifications are met at 28 volts DC as measured at the DC input terminals. For best performance, a regulated power supply is recommended. Operating voltage range is from 24-28 volts. Power will be reduced slightly at DC voltages below 28 volts. Operation a 28 volts or higher is to be avoided as this will significantly reduce transistor life. POWER CORD IDENTIFICATION: Two cables extend from the amplifier. The RED lead is to be connected to the POSITIVE power supply terminal. The BLACK lead is to be connected to the NEGATIVE power supply terminal and earth ground. Use caution not to reverse the DC polarity and do not connect to an AC power line. OPERATING TEMPERATURE: The amplifier may be operated when the ambient air is between O and 50 degrees centigrade. If operated in a closed cabinet, verify that the air temperature flowing over the heat sink is in this range. The amplifier/power supply combination may generate over 1500 watts of heat. The amplifier is cooled by convection flow across the heat sink fins of the unit. Maintain a minimum of 4 inches clearance. A thermal shut-off circuit is provided that will interrupt the DC power input to the first RF stage should the heat sink rise above 60 degrees C. Operation in confined areas may cause the unit to shut-off thermally. Installations where thermal cut-off occurs frequently should be avoided. The unit may be stored in temperatures between -20 and + 70 degrees centigrade. Keep the fan intakes free of dust. TROUBLE SHOOTING: LOW POWER OUTPUT: The most common amplifier problem is low power output. If the installation test shown in Section 3 is run the power input/output specification on the nameplate should be met, especially when working into a dummy load, since this is essentially the test run at the factory. If working with BIRD wattmeters, remember that the power output reading is specified at +/-5% of full scale. In other words, a wattmeter with a 100w element gives readings of +/-5 watts when the wattmeter is reading full scale. Mid-scale readings have much lower accuracy. Always use an element closest to full scale for maximum accuracy. Treat your element with extreme care. Dirty or dropped elements always read low. Make sure that your power supply is adjusted to 28 volts. The input/output powers specified on the nameplate were taken at 28 volts. Measure the voltage at the amplifier terminals to be sure all the DC connections are tight and that the amplifier is seeing 28 volts during operation. Check the manufacturer's ratings to be sure the CONTINUOUS rating of the power supply is sufficient to power the amplifier. If the power supply is slumping, the amplifier output will go down with the voltage. Look at the drive power while the amplifier is operating. Many exciters will put out different powers into even slightly different loads. Low drive power will produce low output power. Do not assume that your exciter output power with the exciter running into a dummy load will be the same as when the exciter is running the amplifier. A strong RF field can sometimes cause an exciters to increase or decrease power as well as go spurious. In-band spurious signals maybe amplified. The change in signal level will show up on the input wattmeter. RF fields can also cause linear power supplies to fall out of regulation. This should be seen on a voltmeter (CAUTION: RF can effect digital voltmeters, too.) Low (or high) output powers can be the result of a high output SWR. Carefully check your loads and connecting cables. NO OUTPUT POWER: After checking the above items, be aware that there is protection circuitry. Check with the factory if you suspect that the internal protection has or is operating. As a rule, if the front panel light and fan are operating and output is zero, the SWR circuit has operated (usually with an audible click upon key-up.) If the SWR protection were operating, you would notice the output wattmeter "jump" briefly upon key up and then return to zero. If the front panel light does not light, either the input drive isn't high enough to trigger the amplifier on or the amplifier has disconnected itself from DC power. The amplifier will reset itself when it cools down. (Some power supplies will "spring up" in voltage when a heavy load is released and settle down to normal after 100-200 milliseconds. This can damage an amplifier.) If all else fails, give us a call. We'll be glad to help! SECTION 2: SPECIFICATIONS WARNING: Do not exceed 15 watts output. Do not exceed nameplate drive power by more than 5%. Do not exceed 28.0 volts while operating. FREQUENCY: 840-960 MHz range. Factory set to specific frequency on ID label. FREQUENCY RANGE: May be operated within + or - 10 MHz of the factory set frequency without tuning. INPUT DRIVE POWER: As specified on amplifier ID nameplate. This is the power measured during final inspection that was required to reach 15 watts output. MAXIMUM INPUT DRIVE POWER: Nameplate input drive power +5% MAXIMUM TEST OUTPUT POWER: 18 watts (Pulsed output period not to exceed 100 mS) MAXIMUM RATED OUTPUT POWER: Not to exceed 15 watts. MAXIMUM RATED LOAD VSWR FOR CONTINUOUS DUTY OPERATION 1.2:1 (<5% reflected power) MAXIMUM VSWR RATING WITHOUT DAMAGE Infinite, all phase angles. (1 hour test time at 12V, no degradation in output power upon return to normal load and temperature). VSWR or thermal protection may operate above 1.5:1 VSWR. OUTPUT VSWR PROTECTION Inherent. THERMAL PROTECTION 60 degrees C + /- 7 degrees C heat sink temperature. Shut off; reset upon return to normal temperature. INPUT/OUTPUT CONNECTORS Type N FEMALE. SPURIOUS OUTPUTS < -75 dBc. HARMONICS - 65 dBc or below. COOLING DC fan cooled controlled by amplifier. Section 3.0 1. TEST PROCEDURE 28 VOLT AMPLIFIER BLOCK DIAGRAM: TRANSMITTER (EXCITER) WATT METER AMPLIFIER BEING TESTED WATT METER DUMMY LOAD 28 VOLT POWER SUPPLY. 24 VOLT FOR INITIAL TEST. EQUIPMENT NEEDED: 1. 2. 3. 4. 5. 6. 7. 3. Exciter Watt meters (2) with slugs for full scale readings Power Supply (28 VOLT) Dummy Load Short coaxial cables (RG-8 or better) with appropriate connectors or adapters. DC ammeter DC voltmeter INSTRUCTIONS: 1. Mount equipment in permanent location. Operate the amplifier at 24 volts into a dummy load for initial tests. 2. The amplifier is of fixed gain design. In order to obtain a given output power (e.g., exactly 100 watts) the input or drive power must be adjusted. The factory test input / output powers are shown on the serial number plate for your particular amplifier. 3. You must measure input power, output power, DC voltage, and DC current draw and verify that all are within specifications. If you do not measure one of these parameters, you have not done a proper installation. 4. After proper operation into the dummy load is assured, connect the amplifier to the installation load (antenna, combiner, etc.) The output power and DC current draw should not change significantly. If it does, a load SWR problem exists and must be corrected. Remember the specification output power is obtained only at 28 volts. Initial tests at 24 volts will result in lower output powers than at 28 volts. A reduction in drive power from the value set at 24 volts will be required when the voltage is increased. Otherwise, higher than rated output power will result. Section 4: Proper Amplifier Set-Up The life of an amplifier is dependent on many factors, but probably the most important is initial set-up. Let's look at some typical cases demonstrating amplifier life. These examples are based on the VOCOM‘s 800 MHz 140 watt amplifier. Case 1: Run it "wide open." Power Input: 200 mWatts Power Output: 185 watts Current Draw: 62A at 13.8 volts Power consumed 62 X 13.8 = Power output = Power dissipated as heat 855.6 185.0 670.6 watts Assuming a junction to case thermal resistance of 1.16 degree C per watt, and 7 transistors in this design: 1.16 X 670.6/7 + 60 = 171.1 degree C junction temperature. The 60 in the above equation is an assumed heat sink temperature. Motorola has published data on MTBF (see for example, AN-790) For the MRF 847 used in this amplifier this equates to an MTBF of a little over 10 years. Converting MTBF to % failures per year this equates to a 10% Failure rate per year PER DEVICE. In an amplifier with seven devices, Motorola predicts a 70% failure rate per year if the amplifier is operated at this point. Case 2: Recommended operating point Power Input: 200 mWatts Power Output: 140 watts Current Draw: 40 A at 13.8 volts Power consumed: 40 X 13.8 = Power output = Heat dissipated = 552 150 402 watts Following a similar calculation, the MTBF per device is 2000 years. In an amplifier with 7 devices the 5 % failure rate per year would be only 0.35%. The extra 35 watts is very costly in terms of amplifier lifetime. Conclusion: Set up the amplifier carefully. Measure the current draw and adjust the drive for the best efficiency. At VOCOM, we carefully choose our power levels at each stage of amplification to obtain total failure rates below 0.5% per year even in amplifiers with MRF transistors. But it's up to you to set them up properly. SECTION 5: APPLICATION NOTE There are a number of low power fixed output exciters on the market and it has come to our attention that may users are reducing the output power of these exciters by detuning them. NEVER REDUCE THE POWER INPUT TO THE AMPLIFIER BY DETUNING ANY STAGE OF EITHER THE EXCITER OR THE AMPLIFIER! De-tuning the exciter will almost certainly cause it to produce spurious in-band signals. These spurious signals will be amplified by the amplifier. If they are high enough in level, amplifier damage may result not to mention FCC involvement. If drive reduction is necessary to keep the amplifier within operating limits, always use a power attenuator if the exciter does not have a power control! In an emergency, a power attenuator may be constructed out of a length of RG-58 or smaller coax (see cable attenuation specs for your frequency). Also be aware that we can adjust the drive requirement at the factory to match the fixed output exciter.
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