REPAIRING AND NOT THROWING AWAY

Richtige Fernseher haben Röhren!

Richtige Fernseher haben Röhren!

In Brief: On this site you will find pictures and technical information about Service Modes, Circuit Diagrams, Firmware Update procedure, Disassemble procedure, Universal remote control set-up codes, Troubleshooting and more....

If you go into the profession, you will obtain or have access to a variety of tech tips databases HERE IT IS Master Electronics Repair !.

These are an excellent investment where the saying: 'time-is-money' rules. However, to learn, you need to develop a general troubleshooting approach - a logical, methodical, method of narrowing down the problem. A tech tip database might suggest: 'Replace C536' for a particular symptom. This is good advice for a specific problem on one model. However, what you really want to understand is why C536 was the cause and how to pinpoint the culprit in general even if you don't have a service manual or schematic and your tech tip database doesn't have an entry for your sick TV or VCR.

While schematics are nice, you won't always have them or be able to justify the purchase for a one-of repair. Therefore, in many cases, some reverse engineering will be necessary. The time will be well spent since even if you don't see another instance of the same model in your entire lifetime, you will have learned something in the process that can be applied to other equipment problems.
As always, when you get stuck, checking out a tech-tips database may quickly identify your problem and solution.In that case, you can greatly simplify your troubleshooting or at least confirm a diagnosis before ordering parts.

Happy repairing!
Today, the West is headed for the abyss. For the ultimate fate of our disposable society is for that society itself to be disposed of. And this will happen sooner, rather than later.

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..............The bitterness of poor quality is remembered long after the sweetness of todays funny gadgets low price has faded from memory........ . . . . . .....
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Tuesday, 18 August 2020

TS590S KENWOOD HF 50MHZ ALL MODE TRANSCEIVER CIRCUIT DESCRIPTION AND SCHEMATIC HOW TO DISASSEMBLE

TS590S Kenwood HF 50MHz ALL MODE TRANSCEIVER How to disassemble, circuit description and schematic


Disassemble procedure - Removing the torque changeover lever
Insert the tip of a flat-head screwdriver (or other implement) under the tab of the torque changeover lever, and then lift the tab using the tip of the flat-head screwdriver. (1)
Caution: Be careful not to damage the panel when lifting.
Turn the lever section of the torque changeover lever to the right, as in the position described in step 1. (2)
Lift the torque changeover lever and remove it from the panel. (3)
Mounting the torque changeover lever
Insert the torque changeover lever by aligning the three tabs of the panel. (1)
Slightly turn the lever section of the torque changeover lever to the left (3) while pressing the surface near the tab at the lower right of the torque changeover lever (2).
Caution: Confirm that the torque changeover lever is caught by the lower right tab of the panel.
Turn the lever section of the torque changeover lever to the left (4) while pressing the surface near the tab at the upper right of the torque changeover lever (5), and then mount it onto the panel.
Procedures when Replacing the Diode (1SR139-400) for hand mounting
When replacing the diode (D304: 1SR139-400) used by the Control unit (A/3) (PCB number: J79-0279-09), cut the leg of a new diode.
Bend the leg of the diode as shown in the figure.
Solder the diode between Q61 (Collector) and the solder pad (Base) of the Control unit (A/3), as shown in the figure.
Confirm the direction of the cathode band when installing the diode.
Install the diode so that it is positioned on the dotted line.
 Install the diode so that its height from the surface of the PCB is 4mm (0.16 inches) or less (Height of rubber sheet (G11-4536-04): 4mm (0.16 inches)).
Precautions for Reassembly
Perform the following steps when assembling the bottom side of the transceiver.
1. Separate the two coaxial cables (E37-1495-05, E37-1496-05) as shown in the figure.
2. Push the two flat cables (E37-1491-05, E37-1492-05) into the gap of the chassis so they do not come into contact with the cabinet.
Caution for Replacing the LED (B30-2322-05, B30-2323-05)
When replacing the “B30-2322-05” or “B30-2323-05” LED used by the Display unit (A/6), order and replace the LED for service into which the rank is divided according to brightness, according to the following procedures, so that the brightness of the LED backlight remains uniform after replacing the LED.
Confirm whether the “A” or “Z” stamp is pushed on the foil side of Display unit (A/6).
Order and replace the LED for service as shown in the following table according to whether stamp “A” or “Z” exists or not.
Frequency Configuration
Figure shows the frequency configuration of this transceiver.
While transmitting, FM mode operates in a double conversion and other modes (AM, SSB, CW, FSK) operate in a triple conversion.
While receiving, the first IF operates in 73.095MHz triple conversion. In modes other than FM, the third IF is 24kHz, and the IF signal is converted by an A/D converter and input into DSP. The FM mode is detected in the FM IC, and the audio signal is converted by an A/D converter and input into the DSP. Under the following conditions, the first IF operates its reception in 11.374MHz double conversion.
1) Modes other than AM or FM
2) Amateur band within the 1.8/3.5/7/14/21MHz bands
3) DSP filter’s bandwidth is 2.7kHz or lower.
Reference Signal Generator
The reference frequency (fstd), which is used to control the individual LO frequencies, oscillates at 15.6MHz in a crystal oscillation circuit (X502, Q501). This 15.6MHz signal passes through a buffer (Q502) and is doubled in a multiplier (Q503) to generate a 31.2MHz signal. The 31.2MHz signal is used as a reference signal for LO3 (the third local oscillator) DDS (IC601). The 31.2MHz signal is doubled in multipliers (Q504, Q505) to generate a 62.4MHz signal. The 62.4MHz signal is used as a reference signal for LO1 (the first local oscillator) PLL (IC801).  The SO-3 (TCXO unit: 15.6MHz) is configured as an option in this transceiver, so that you can replace the crystal oscillation circuit (X502, Q501) with the SO-3. When using the SO-3, remove the CN903 and CN904 short jumper wires in order to stop the operation of the crystal oscillation circuit (X502, Q501).
LO1/ LO2/ LO3
LO1 (the first local oscillator)
The VCO (Q806) oscillates at 196.8MHz. Only the double frequency component, 393.6MHz, of this VCO’s oscillation output is extracted and input into PLL (IC801) pin 6.
This input signal is divided into 1/N within the PLL. Also, the 62.4MHz signal (15.6MHz reference frequency x 4) is input into PLL pin 8 and divided into 1/R within the PLL. By a phase comparator in the PLL, the frequency divided into 1/N and the frequency divided into 1/R are compared, and then the frequency is locked. The comparison frequency (fø) at this time is 120kHz when transmitting FM, and 2.4MHz otherwise.
393.6MHz signal locked by PLL (IC801) would be used as reference by DDS (IC803). The output signal from DDS (IC803) is 12.495MHz to 32.195MHz when RX-1 path is selected, amplified at the broad band amplifier (IC804), and then goes through BPF and is output as LO1. When
RX-2 path is selected or when transmitting, 36.5625MHz to 66.5475MHz is output, amplified by the broad band amplifier (IC804), and then doubled in the multiplier (D652), goes through BPF, and is output as 73.120MHz to 133.095MHz LO1
LO2 (the second local oscillator)
The reference oscillating circuit’s output signal 15.6MHz signal passes through a buffer (Q502) and is doubled in a multiplier (Q503) to generate a 31.2MHz signal. The 31.2MHz signal is also used as the DDS (IC601)’s reference frequency, and therefore its resistance is divided. Then, the 31.2MHz signal is doubled in multipliers (Q504, Q505) to generate a 62.4MHz signal.  The 62.4MHz signal’s high harmonic is cut in the BPF and the signal is amplified in the amplifier (Q506) to generate LO2. If IFB is selected, the diode switch (D501) cuts the LO2 output.
LO3 (the third local oscillator)
The LO3 used in the modulator and the detector is generated in the DDS (IC601). The DDS output signal passes through the buffer (Q602) and LPF to generate LO3.
Receiver Circuit
In an amateur frequency band or mode that requires antiproximate interference, the receive signal passes through the double conversion RX-1 path, and in other frequency bands and modes, it passes through the triple conversion RX-2 path.
From the antenna terminal to the preamplifier (Q236)
The receive signal from the antenna terminals (ANT1/ANT2) passes through the antenna changeover relay (K44) in the Final unit (X45-391 A/2), the antenna tuner’s IN/THROUGH changeover relay (K45), the transmission/reception changeover relay (K46), and an image filter, and is sent from CN51 to the TX-RX unit (X57-785 A/2)’s CN100 (RAT) through a co-axial cable.
The signal input into the TX-RX unit passes through the RX ANT changeover relay (K101) and enters the attenuator circuit (ATT) which is approximately 12dB. This can be switched to approximately 20dB by removing the CN101 short jumper. Then, the signal passes through LPF for IF trap, the surge absorption limiter, and the BC band attenuating circuit (removes 30kHz to 1.705MHz), and enters the BPF. In the BC band attenuating circuit, in order to avoid interference by high-output broadcasting stations, 11.7MHz and 15.5MHz trap circuit is inserted into E type only.
The BPF divides in the range as shown in table 3. The BC band’s BPF includes ATT for avoiding cross-modulation by medium wave band high-output station (ATT ON: CN102=open, CN103=short, ATT OFF: CN102=short, CN103=open). The transmit signal also passes through the BPF when transmitting. The preamplifier (Q236) receives the signal passed through the BPF. In this model, it is an emitter grounding circuit which uses a bipolar transistor. Q239 switches the emitter’s returning amount to adjust the gain. Approximately 20dB is gained in 21.5 to 60MHz and approximately 12dB in other frequencies. The preamplifier circuit can be passed by turning off the PRE display with the preamplifier key .
From the preamplifier (Q236) to the second IF frequency (10.695MHz/11.374MHz)
The signal from the preamplifier (Q236) output to the second IF amplifier 1 (Q451) is spread into 2 paths: RX-1 and RX-2, depending on the frequency band (refer to table)  The RX-1 path is selected when the “L” signal is added to Q273, and the RX-2 path is selected if the “H” signal is added.
The RX-1 path signal passes through the LPF for IF trap, is integrated with LO1 (12.495 to 32.195MHz) in the quadbalance first mixer (Q263 to Q266), and is then converted to the first IF (11.374MHz). The first IF signal passes through the 2-pole MCF (XF301) and enters the second IF amplifier 1 (Q451). The RX-2 path signal passes through the LPF for IF trap, is integrated with LO1 (73.120 to 133.095MHz) in the quadbalance first mixer (Q321 to Q324), and is then converted to the first IF (73.095MHz). The first IF signal passes through the 2-pole MCF (XF371), and by the trans-feedback type NFB (negative feedback) first IF amplifier (Q391), is amplified by approximately 12dB. The amplified signal is mixed with LO2 (62.4MHz) in the second mixer (D422, D423), converted to the second IF (10.695MHz), and then enters the second IF amplifier 1 (Q451). The second mixer is a passive type that uses a diode, and is a bilateral circuit that converts both receive signal's frequency at the time of reception and transmission signal's frequency at the time of transmission.  The second IF signal that passed through the RX-1 or RX-2 path is amplified by approximately 13dB in the second IF amplifier 1 (Q451), and is then divided into 2 paths: the NB (noise blanker) circuit and the blanking circuit (D461 to D464). Blanking is carried out by D461 to D464.  Then, the second IF signal passes through the IF filter.
One of 5 filters is selected, depending on the frequency and the mode (refer to table).
The second IF signal that passed through the IF filter enters the AGC circuit (diode ATT circuit: D522 to D524).  The AGC voltage output from the DSP is added to D522 to D524, the change of AGC voltage changes the current on the pin diode and controls the attenuation of the signal passing through. And, the second IF amplifier 2 (Q541) and the second IF amplifier 3 (Q521, Q522) altogether amplify by the total of approximately 32dB, and the signal passes through the simplified diode ATT circuit (D525). The voltage determined in the adjustment mode is added to D525, and adjusts the difference of the total gains of the RX-1 and RX-2 paths.
Kenwood TS590s Schematic