Sansui 310 Receiver Restoration

Unit: AM/FM Stereo Receiver

Manufacturer: Sansui

Model: 310

SN: 822081042

Today, I'm showcasing a Sansui 310 receiver that has come in for restoration. It was designed as an entry-level receiver in Sansui's early solid-state lineup. This receiver is less common than other models, but its warm, smooth sound and classic design make it appealing to those who appreciate vintage aesthetics.

Sansui 310 was introduced to the market in 1972. It produces 15 watts per channel into 8 ohms with no more than 1% total harmonic distortion. The damping factor at 8 ohms is 30.

Tone Control, Power Amplifier & Power Supply Board (F-1380)

Power supply circuit

The power supply circuit has 8 aluminum electrolytic capacitors: C004, C005, C006, C007, C008, C009, C010, and C011.

All aluminum e-caps except C005 were replaced with Nichicon UPW/UHE low-impedance capacitors. I didn't replace the main filter capacitor in this unit. The original capacitor has a very large lead spacing of 22mm. Modern capacitors have a maximum lead spacing of 10mm. So, it is very difficult to find a suitable modern e-cap that will fit. In any case, the original filter cap is still in very good condition with a small tolerance and low ESR.

The original e-caps were tested with an Atlas ESR70 capacitance meter; the results are below.

Test results on original capacitors removed from the power supply circuit:

C004: rated capacitance – 330uF, measured – 444uF, ESR – 1.16Ω, deviation: +35%

C005: rated capacitance – 1500uF, measured – 1820uF, ESR – 0.79Ω, deviation: +21%

C006: rated capacitance – 220uF, measured – 286uF, ESR – 1.21Ω, deviation: +30%

C007: rated capacitance – 470uF, measured – 761uF, ESR – 1.47Ω, deviation: +62%

C008: rated capacitance – 100uF, measured – 129uF, ESR – 1.76Ω, deviation: +29%

C009: rated capacitance – 330uF, measured – 438uF, ESR – 1.18Ω, deviation: +33%

C010: rated capacitance – 470uF, measured – 574uF, ESR – 1.16Ω, deviation: +22%

C011: rated capacitance – 100uF, measured – 146uF, ESR – 2.42Ω, deviation: +46%

Tone control circuit

The tone control circuit has 4 aluminum electrolytic capacitors (C707, C708, C711, C712) installed in the signal path. 

To reduce the noise generated in the circuit, the ordinary 1uF capacitors were replaced with film polyester WIMA caps, and the ordinary 3.3uF capacitors were replaced with modern low-leakage Nichicon UKL caps. 

Test results on original capacitors removed from the tone control circuit:

C707: rated capacitance – 1uF, measured – 1.3uF, ESR – 6.4Ω, deviation: +30%

C708: rated capacitance – 1uF, measured – 1.3uF, ESR – 5.8Ω, deviation: +30%

C711: rated capacitance – 3.3uF, measured – 4.7uF, ESR – 7.5Ω, deviation: +42%

C712: rated capacitance – 3.3uF, measured – 5.2uF, ESR – 8.7Ω, deviation: +58%

The tone control circuit has two 2SC871 transistors installed in positions TR701 and TR702. This transistor is on my list of transistors prone to failure. I replaced them with a modern low-noise Fairchild KSC1845. Watch the pinout when replacing transistors. The original 2SC871 transistor is BCE, and the new one (KSC1845) is ECB.

Power amplifier circuit

The power amplifier circuit has 12 aluminum electrolytic capacitors: C801, C802, C805, C806, C807, C808, C809, C810, C813, C814, C817, and C818.

The ordinary 1uF capacitors installed in the signal path were replaced with film polyester WIMA caps to reduce the noise. The ordinary 10uF capacitors were replaced with modern low-leakage Nichicon UKL caps for the same purpose. The coupling capacitors C817 and C818 were replaced with Nichicon LKG caps. The remaining aluminum e-caps were replaced with Nichicon UPW/UPM low-impedance capacitors.

Test results on original capacitors removed from the power amplifier circuit:

C801: rated capacitance – 1uF, measured – 1.3uF, ESR – 6.4Ω, deviation: +30%

C802: rated capacitance – 1uF, measured – 1.3uF, ESR – 5.2Ω, deviation: +30%

C805: rated capacitance – 100uF, measured – 148uF, ESR – 2.4Ω, deviation: +48%

C806: rated capacitance – 100uF, measured – 155uF, ESR – 1.8Ω, deviation: +55%

C807: rated capacitance – 10uF, measured – 13uF, ESR – 19.5Ω, deviation: +30%

C808: rated capacitance – 10uF, measured – 16uF, ESR – 11.1Ω, deviation: +60%

C809: rated capacitance – 33uF, measured – 45uF, ESR – 1.73Ω, deviation: +36%

C810: rated capacitance – 33uF, measured – 40uF, ESR – 1.56Ω, deviation: +21%

C813: rated capacitance – 100uF, measured – 140uF, ESR – 1.58Ω, deviation: +40%

C814: rated capacitance – 100uF, measured – 146uF, ESR – 2.2Ω, deviation: +46%

C817: rated capacitance – 1000uF, measured – 1178uF, ESR – 1.18Ω, deviation: +18%

C818: rated capacitance – 1000uF, measured – 1247uF, ESR – 1.44Ω, deviation: +25%

This circuit also has two 2SC632 prone-to-failure transistors installed in positions TR801 and TR802. I replaced them with a modern, low-noise Fairchild KSC1845. Make sure the new transistors have a current gain >350. Also, when replacing transistors, pay attention to the pinout. The original 2SC632 is a BCE, and the new transistor is an ECB.

Tone control, power amplifier & power supply board - before and after

Head Amplifier Board (F-1379)

The head amplifier board has two low-leakage capacitors (C601, C602) installed in the input signal path, two solid electrolytic capacitors (C613, C614) installed in the output signal path, and 6 ordinary aluminum electrolytic capacitors (C605, C606, C609, C610, C611, C612).

To reduce noise in this circuit, the original low-leakage capacitors were replaced with modern low-leakage Nichicon UKL caps. The original solid e-caps were replaced with film polyester WIMA caps. The ordinary aluminum e-caps C611 and C612 were upgraded to modern low-leakage Nichicon UKL caps to further minimize noise. The remaining aluminum e-caps were replaced with Nichicon UPW low-impedance capacitors.

Test results on original capacitors removed from the head amplifier board:

C601: rated capacitance – 3.3uF, measured – 3.1uF, ESR – 1.46Ω, deviation: -6%

C602: rated capacitance – 3.3uF, measured – 3.3uF, ESR – 1.39Ω, deviation: 0%

C605: rated capacitance – 100uF, measured – 150uF, ESR – 0.91Ω, deviation: +50%

C606: rated capacitance – 100uF, measured – 151uF, ESR – 1.08Ω, deviation: +51%

C609: rated capacitance – 47uF, measured – 70uF, ESR – 1.52Ω, deviation: +49%

C610: rated capacitance – 47uF, measured – 72uF, ESR – 1.39Ω, deviation: +53%

C611: rated capacitance – 10uF, measured – 15uF, ESR – 1.85Ω, deviation: +50%

C612: rated capacitance – 10uF, measured – 15uF, ESR – 2.1Ω, deviation: +50%

C613: rated capacitance – 0.68uF, measured – 0.65uF, ESR – N/A, deviation: -4%

C614: rated capacitance – 0.68uF, measured – 0.65uF, ESR – N/A, deviation: -4%

This circuit also has four 2SC632 prone-to-failure transistors installed in positions TR601, TR602, TR603, and TR604. I replaced them with a modern, low-noise Fairchild KSC1845. Again, ensure the new transistors have a current gain >350 and pay close attention to the pinout.

Head amplifier board - before and after

FM, MPX, and AM Unit (F-1353)

Be aware, that replacing the original capacitors in the tuner section may require subsequent tuner alignment. I do not recommend servicing the tuner section of any vintage receiver unless you have all the necessary equipment and sufficient experience in tuner alignment.

The tuner section has 13 aluminum electrolytic capacitors: C211, C221, C316, C323, C334, C341, C343, C402, C406, C407, C408, C409, and C412.

The original 1uF e-caps were replaced with film polyester WIMA capacitors. The remaining aluminum e-caps were replaced with Nichicon UPW low-impedance capacitors.

Test results on original capacitors removed from the FM, MPX, and AM unit:

C211: rated capacitance – 10uF, measured – 17uF, ESR – 5.6Ω, deviation: +70%

C221: rated capacitance – 3.3uF, measured – 4.1uF, ESR – 3.9Ω, deviation: +24%

C316: rated capacitance – 1uF, measured – 1.4uF, ESR – 5.4Ω, deviation: +40%

C323: rated capacitance – 3.3uF, measured – 4.5uF, ESR – 4.1Ω, deviation: +36%

C334: rated capacitance – 47uF, measured – 67uF, ESR – 2.1Ω, deviation: +43%

C341: rated capacitance – 100uF, measured – 129uF, ESR – 1.02Ω, deviation: +29%

C343: rated capacitance – 3.3uF, measured – 5.1uF, ESR – 3.8Ω, deviation: +55%

C402: rated capacitance – 3.3uF, measured – 4.2uF, ESR – 3.8Ω, deviation: +27%

C406: rated capacitance – 10uF, measured – 16uF, ESR – 2.2Ω, deviation: +60%

C407: rated capacitance – 1uF, measured – 1.2uF, ESR – 6.4Ω, deviation: +20%

C408: rated capacitance – 10uF, measured – 14uF, ESR – 2.6Ω, deviation: +40%

C409: rated capacitance – 10uF, measured – 15uF, ESR – 5.7Ω, deviation: +50%

C412: rated capacitance – 1uF, measured – 1.3uF, ESR – 6.6Ω, deviation: +30%

FM, MPX, AM unit - before and after

Dial and Meter Lamps

The original dial and meter incandescent bulbs were replaced with warm white LED lamps to maintain the original look and decrease heat.

Audio Adjustments

The service manual has no instructions for main amplifier adjustment. I used the following procedure to adjust the amplifier. 

First of all, I checked the center voltage at fuses F801/F802 on the main amplifier board. The measured voltage was 46.64V. Then I set the collector voltage of transistor TR811 to half of the center voltage with trimming resistor VR801. Similarly, the collector voltage of transistor TR813 was set to half of the center voltage with trimming resistor VR802. After that, the oscilloscope was connected across the speaker terminals, and a sine-wave signal of 1kHz was applied to the AUX jacks. The audio signal level was increased until the audio output on the oscilloscope began to clip. The trimming resistor VR801 (VR802) was slightly adjusted for equal clipping on each channel.

The idling current was set to 15mA in each channel with trimming resistor VR803 (VR804).

Center voltage measured at fuses F801/F802

Collector voltage of transistors TR811 and TR813 (half of the center voltage)

Idling current of the left and right channels

Output Power Test

The final output power test was performed at the end of my restoration. The amplifier was loaded with a low inductance 8Ω/100W dummy resistor for each channel. The oscilloscope was connected across the speaker terminals, and a sine-wave signal of 1kHz was applied to the AUX jacks. The output sine-wave signal was perfectly symmetrical on both channels with no clipping up to 9.82 VRMS (left channel) and 9.87 VRMS (right channel). It corresponds to the output power of 12.1W on the left channel and 12.2W on the right channel.

Output power test

As usual, all the knobs and the front panel were gently cleaned in warm water with dish soap. All controls have been cleaned with DeoxIT 5% contact cleaner and lubricated with DeoxIT FaderLube 5% spray. The wood case was treated with Howard's Restor-A-Finish.

The final result can be seen in the photos below. The sound is beautiful, clear, and warm. Please watch a short demo video at the end of this post. Thank you for reading.

Sansui 310 - after restoration

Demo video after repair & restoration

Pioneer SX-790 Receiver Restoration

Unit: AM/FM Stereo Receiver

Manufacturer: Pioneer

Model: SX-790

SN: YF3600217S

Take a look at what’s on my bench today! This is the rare Pioneer SX-790 receiver from the late 1970s. This model you don’t come across very often. The SX-790 is the blackout version of the SX-780, featuring a slightly different appearance while maintaining similar internal specifications. This receiver is truly a gem for any audio enthusiast.

The SX-790 was manufactured from 1978 to 1980. It produces 45 watts per channel into 8 ohms with no more than 0.05% total harmonic distortion. The damping factor at 8 ohms is 30.

Although the Pioneer SX-790 is essentially identical to the SX-780 model I serviced a few years ago, I felt it was worthwhile to document this restoration as well. This post can serve as a helpful reference for anyone looking to restore his own SX-790. Let’s dive in!

According to the Pioneer database, this particular unit was manufactured in June 1978.

AF Amplifier Board (GWK-118)

Power Supply Circuit

The power supply circuit has 14 aluminum electrolytic capacitors: C301, C302, C303, C304, C305, C306, C307, C308, C309, C310, C311, C314, C315, and C316. 

All of them were replaced with Nichicon UPW/UPM low-impedance capacitors. Those e-caps are designed for switching power supplies and can operate in the temperature range from -55 to +105 C.

The original e-caps were tested with an Atlas ESR70 capacitance meter; the results are below.

Test results on original capacitors removed from the power supply circuit:

C301: rated capacitance – 100uF, measured – 60uF, ESR – 1.09Ω, deviation: -40%

C302: rated capacitance – 100uF, measured – 68uF, ESR – 3.4Ω, deviation: -32%

C303: rated capacitance – 100uF, measured – 69uF, ESR – 1.53Ω, deviation: -31%

C304: rated capacitance – 100uF, measured – 74uF, ESR – 1.56Ω, deviation: -26%

C305: rated capacitance – 47uF, measured – 45uF, ESR – 1.98Ω, deviation: -4%

C306: rated capacitance – 47uF, measured – 45uF, ESR – 1.81Ω, deviation: -4%

C307: rated capacitance – 100uF, measured – 90uF, ESR – 1.09Ω, deviation: -10%

C308: rated capacitance – 100uF, measured – 91uF, ESR – 1.81Ω, deviation: -9%

C309: rated capacitance – 2.2uF, measured – 2.6uF, ESR – 3.6Ω, deviation: +18%

C310: rated capacitance – 2.2uF, measured – 2.6uF, ESR – 2.9Ω, deviation: +18%

C311: rated capacitance – 100uF, measured – 104uF, ESR – 1.13Ω, deviation: +4%

C314: rated capacitance – 470uF, measured – 408uF, ESR – 0.62Ω, deviation: -13%

C315: rated capacitance – 220uF, measured – 200uF, ESR – 0.72Ω, deviation: -9%

C316: rated capacitance – 47uF, measured – 45uF, ESR – 0.94Ω, deviation: -4%

Protection Circuit

The protection circuit in SX-790 is responsible for muting when the POWER switch is turned on and off. The delaying action is determined by the time constants of the timing capacitor C317 and the constant current circuit. The transistor Q26 is turning the relay S7 on and off thereby protecting the speakers. 

The protection circuit has 3 aluminum electrolytic capacitors: C317, C318, and C319. 

All of them were replaced with Nichicon UPW/UPM low-impedance capacitors.

Test results on original capacitors removed from the protection circuit:

C317: rated capacitance – 33uF, measured – 34uF, ESR – 1.48Ω, deviation: +3%

C318: rated capacitance – 10uF, measured – 13uF, ESR – 2.1Ω, deviation: +30%

C319: rated capacitance – 47uF, measured – 58uF, ESR – 1.45Ω, deviation: +23%

Phono Amplifier Circuit

The phono amplifier circuit has 4 low-leakage capacitors (C103, C104, C117, C118) installed in the signal path, and two aluminum electrolytic capacitors (C105, C106). 

All original low-leakage capacitors were replaced with modern low-leakage Nichicon UKL caps. The remaining aluminum e-caps were replaced with Nichicon UPW low-impedance capacitors.

Test results on original capacitors removed from the phono amplifier circuit:

C103: rated capacitance – 2.2uF, measured – 2.6uF, ESR – 6.4Ω, deviation: +18%

C104: rated capacitance – 2.2uF, measured – 2.6uF, ESR – 5.1Ω, deviation: +18%

C105: rated capacitance – 470uF, measured – 498uF, ESR – 1.94Ω, deviation: +6%

C106: rated capacitance – 470uF, measured – 502uF, ESR – 1.61Ω, deviation: +7%

C117: rated capacitance – 2.2uF, measured – 2.4uF, ESR – 5.6Ω, deviation: +9%

C118: rated capacitance – 2.2uF, measured – 2.3uF, ESR – 6.1Ω, deviation: +5%

Control Section

The control section has 8 low-leakage capacitors (C207, C208, C217, C218, C227, C228, C229, C230) installed in the signal path, and 4 aluminum electrolytic capacitors (C201, C202, C213, C214).

The original low-leakage capacitors C207, C208, C227, and C228 were replaced with film polyester WIMA and Kemet caps. The other low-leakage capacitors C217, C218, C229, and C230 were replaced with modern low-leakage Nichicon UKL caps. The remaining aluminum e-caps were replaced with Nichicon UPW low-impedance capacitors.

Test results on original capacitors removed from the control section:

C201: rated capacitance – 4.7uF, measured – 5.9uF, ESR – 2.8Ω, deviation: +26%

C202: rated capacitance – 4.7uF, measured – 6.1uF, ESR – 2.9Ω, deviation: +30%

C207: rated capacitance – 1uF, measured – 1.2uF, ESR – 6.6Ω, deviation: +20%

C208: rated capacitance – 1uF, measured – 1.1uF, ESR – 7.2Ω, deviation: +10%

C213: rated capacitance – 47uF, measured – 51uF, ESR – 2.1Ω, deviation: +9%

C214: rated capacitance – 47uF, measured – 51uF, ESR – 2.2Ω, deviation: +9%

C217: rated capacitance – 4.7uF, measured – 5.8uF, ESR – 8.2Ω, deviation: +23%

C218: rated capacitance – 4.7uF, measured – 5.7uF, ESR – 7.8Ω, deviation: +21%

C227: rated capacitance – 0.22uF, measured – 0.21uF, ESR – N/A, deviation: -5%

C228: rated capacitance – 0.22uF, measured – 0.21uF, ESR – N/A, deviation: -5%

C229: rated capacitance – 2.2uF, measured – 2.9uF, ESR – 6.3Ω, deviation: +32%

C230: rated capacitance – 2.2uF, measured – 2.8uF, ESR – 6.2Ω, deviation: +27%

FM Muting Circuit

The FM muting circuit has two low-leakage capacitors (C401, C403), and 4 aluminum electrolytic capacitors (C402, C404, C405, C406).

The original e-caps C401, C402, C403, and C404 were replaced with film polyester WIMA caps. The remaining capacitors were replaced with Nichicon UPW low-impedance capacitors.

Test results on original capacitors removed from the FM muting circuit:

C401: rated capacitance – 0.47uF, measured – 0.55uF, ESR – N/A, deviation: +17%

C402: rated capacitance – 0.47uF, measured – 0.58uF, ESR – N/A, deviation: +23%

C403: rated capacitance – 0.47uF, measured – 0.59uF, ESR – N/A, deviation: +26%

C404: rated capacitance – 0.47uF, measured – 0.56uF, ESR – N/A, deviation: +19%

C405: rated capacitance – 10uF, measured – 12uF, ESR – 2.6Ω, deviation: +20%

C406: rated capacitance – 220uF, measured – 233uF, ESR – 1.79Ω, deviation: +6%

VU Meters Circuit

The VU meters circuit has 4 aluminum electrolytic capacitors: C324, C325, C326, and C327. All of them were replaced with Nichicon UPW low-impedance capacitors.

Test results on original capacitors removed from the VU meters circuit:

C324: rated capacitance – 4.7uF, measured – 6.5uF, ESR – 2.2Ω, deviation: +38%

C325: rated capacitance – 4.7uF, measured – 6.2uF, ESR – 2.4Ω, deviation: +32%

C326: rated capacitance – 4.7uF, measured – 6.5uF, ESR – 2.2Ω, deviation: +38%

C327: rated capacitance – 4.7uF, measured – 6.3uF, ESR – 2.2Ω, deviation: +34%

Three transistors (Q19, Q20, and especially Q25) in the power supply circuit are running very hot under normal working conditions. Those transistors are mounted on heat sinks, but the size of each heat sink is not enough to efficiently dissipate the heat. If you need to service this model, I strongly recommend carefully investigating a PCB around those transistors for any signs of excess heating. Be aware that those heat sinks are electrically live.

All three transistors were replaced with modern Fairchild MJE transistors. A new silicone thermal compound (Wakefield-Vette, 120 series) was applied between each transistor and the heat sink.

The original relay driver transistor Q26 on this board is Panasonic 2SC1384. This transistor is on my list of prone-to-failure transistors and I replaced it with a new Fairchild KSC2690. The new transistor has the same pinout as the original one. 

Finally, the original protection relay was replaced with a new Omron relay to improve overall reliability.

AF amplifier board - before and after

Tuner Board (AWE-099)

Be aware, that replacing the original capacitors in the tuner section may require subsequent tuner alignment. I do not recommend servicing the tuner section of any vintage receiver unless you have all the necessary equipment and sufficient experience in tuner alignment.

The tuner board has 2 low-leakage capacitors (C38, C40), one solid tantalum capacitor (C37), and 12 aluminum electrolytic capacitors (C27, C28, C34, C35, C41, C43, C44, C53, C60, C61, C71, C76). An additional axial electrolytic capacitor is soldered on the foil side between pin 22 and the negative lead of e-cap C76.

The original low-leakage capacitors C38 and C40 were replaced with film polyester WIMA caps. The original solid tantalum capacitor C37 was replaced with a new low-leakage Nichicon UKL cap. Two ordinary aluminum e-caps (C34, C41) with a nominal capacitance of 1uF were replaced with film polyester WIMA caps. The original axial e-cap was replaced with a new Vishay (138 AML series) capacitor. The remaining capacitors were replaced with Nichicon UPW low-impedance capacitors.

Test results on original capacitors removed from the tuner board:

C27: rated capacitance – 2.2uF, measured – 2.8uF, ESR – 2.9Ω, deviation: +27%

C28: rated capacitance – 4.7uF, measured – 6.5uF, ESR – 3.3Ω, deviation: +38%

C34: rated capacitance – 1uF, measured – 1.2uF, ESR – 3.2Ω, deviation: +20%

C35: rated capacitance – 22uF, measured – 25uF, ESR – 1.79Ω, deviation: +14%

C37: rated capacitance – 6.8uF, measured – 7.5uF, ESR – 4.2Ω, deviation: +10%

C38: rated capacitance – 1uF, measured – 1.2uF, ESR – 6.3Ω, deviation: +20%

C40: rated capacitance – 1uF, measured – 1.2uF, ESR – 6.7Ω, deviation: +20%

C41: rated capacitance – 1uF, measured – 1.2uF, ESR – 3.1Ω, deviation: +20%

C43: rated capacitance – 330uF, measured – 362uF, ESR – 0.89Ω, deviation: +10%

C44: rated capacitance – 220uF, measured – 170uF, ESR – 1.73Ω, deviation: -23%

C53: rated capacitance – 220uF, measured – 207uF, ESR – 1.25Ω, deviation: -6%

C60: rated capacitance – 4.7uF, measured – 6.2uF, ESR – 3.6Ω, deviation: +32%

C61: rated capacitance – 3.3uF, measured – 4.2uF, ESR – 3.2Ω, deviation: +27%

C71: rated capacitance – 10uF, measured – 12uF, ESR – 3.5Ω, deviation: +20%

C76: rated capacitance – 10uF, measured – 13uF, ESR – 2.9Ω, deviation: +30%

C# (axial cap): rated capacitance – 10uF, measured – 11, ESR – 1.75Ω, deviation: +10%

The original 2SA726 transistor in positions Q7 and Q8 is notorious for its shot noise. I replaced it with a modern low-noise Fairchild KSA992 transistor. See the pinout for the replacement transistors. The original transistor is BCE, and the new one is ECB. Also, make sure that the new transistors are gain-matched (note the blue dots on the original transistors).

Additional axial e-cap soldered on the foil side - before and after

Tuner board - before and after

Dial Lamps

As I mentioned in my previous post, I prefer to install new incandescent dial bulbs in any SX-x50 or SX-x80 model. In my opinion, the modern warm white LED lamps tend to change the original look of these receivers. To address the issue with the heat coming from these bulbs I installed a strip of foil tape inside the top cover. It reflects the light and substantially reduces the heat coming from incandescent bulbs.

Tip: there is a small opening at the center of each lamp socket. I used a small Allen wrench and gently pushed each lamp out of the socket. In that case, the brittle socket tabs won't be damaged or broken.

Push each dial lamp out of the socket with a small Allen wrench

DC Offset & Power Meters Adjustments

At the end of my restoration, I checked and adjusted the DC offset of the power amplifier as described in the service manual. No dummy load or input signal is required for this adjustment. The DC offset was adjusted close to zero volts on each channel with trimming resistors VR5 and VR6.

An AC voltmeter and function generator are required to adjust power meters. A sine-wave signal of 1 kHz should be applied to the AUX terminals and the level of this signal should be adjusted so that the voltage on the SPEAKERS terminals reads 20 VRMS. Then, the trimming resistors VR7 and VR8 should be adjusted so that the power meters read 50W.

DC offset on the left and right channels after restoration

Output Power Test

The final output power test was conducted at the end of the restoration. Two low inductance 8Ω/100W resistors connected across each speaker terminal were used as a dummy load. The output sine-wave signal was perfectly symmetrical on both channels with no clipping up to 20.63 VRMS (left channel) and 20.95 VRMS (right channel). It corresponds to the output power of 53.2W on the left channel and 54.9W on the right channel.

Output power test

As usual, all the knobs and the front panel were gently cleaned in warm water with dish soap. All controls have been cleaned with DeoxIT 5% contact cleaner and lubricated with DeoxIT FaderLube 5% spray.

The final result can be seen in the photos below. The sound is wonderful, very warm, and extremely clean. Please watch a short demo video at the end of this post. Thank you for reading.

Pioneer SX-790 - after restoration

Demo video after repair & restoration