Sunday, 22 November 2015

Lunch Box Launch

The EZTube Lunch Box design is now advanced enough to make it available to the DIY community. All the power supply and enclosure issues have now been resolved and the majority of the documentation is complete. An overview of the Lunch Box Project is given in the following document:

Lunchbox User Manual

This document describes the overall objectives of the project, and top level constructional information including the enclosure alternatives and basic module mechanics. It also lists all the other documents related to the Lunch Box project.

There are now four power supply PCB options, two with dc heaters and two with ac heaters. One dc heaters power supply is for use solely with an external power supply and the other one is on a standard Eurocard that plugs directly into the backplane. One of the dc heaters power supplies is the 100mm by 100mm PCB intended solely for use in Frank Rollen's enclosure. The other dc power supply PCB is  Eurocard sized and plugs directly into the back plane. All four power supply PCBs are covered in a single document that can be found here:

Power Supply PCBs

The remaining documentation covers various aspects of the the EZTube Mixer project that are relavent to the Lunch Box project. They are:

EZTube Mixer Reference Manual

Classic Construction and User Guide

EZTube Mixer V3 PCB. Documentation and Assembly Notes

Twin Line Amp Eurocard. Configuration Options and BOM

Pultec 3 Band EQ Documentation

Helios 3 Band EQ Documentation

REDD EQ. Design and Assembly Information

EZTube Mixer Motherboards

EZTube Mixer Module Mechanics

EZTube Mixer Routing and Mixing

Further documentation will be added later to include topics such as monitoring and the new EQ with gain make up PCBs which are under development.

A support thread including links to all the documentation has been set up at groupDIY.com

EZTube Lunch Box Support Thread

If you have any questions about the EZTube Mixer Lunch Box project please use the above thread.

Sunday, 26 July 2015

Power Supply Saga (continued)

It is more than 6 months since my last post here but a lot has happened and much of it has been to do with the power supply. I started building the 28HP plug in power supply in January. Initially I spent a lot of time sorting out a multi-pin dc output connector that could handle both the high voltage of the HT and the high current of the heater supplies. I ended up using an AMP connector with crimp inserts. The number of options available for this connector is enormous and it takes ages to wade through the data sheets to find all the right compatible components. Although I used this connector for the prototype 28HP power supply I have since abandoned it as too complex to specify.

Once the supply was basically built it was time to commission it. It was then that I realised that I had somehow managed not to connect the output pins of all three supplies to their output pads! Passing the wires through the PCB holes and soldering direct to the PCB underneath fixed it and all supplies provided the correct voltages. I then fitted the PCB to an SRS sub-rack and connected the dc outputs to the four module motherboard and tested it with the new Classic mic pre module. This is a 3U Eurocard version of my original mic pre design based on a pair of mu followers. To fit into the standard width module, the 6CG7 tubes of the original design were replaced with 6922 tubes. These also give a little more gain but need to be operated at a higher current to achieve distortion levels as low as the original 6CG7 design. The extra current does mean that this version has a better drive capability than the 6CG7 version (see later).

It was at this point that problems began to surface. I was unable to set the Classic gain to maximum (70dB) without the circuit going into oscillation. At 60dB it did not oscillate but the noise level was far too high and there was a lot of hum. At this stage I did not know if this was the Classic or the power supply at fault. So I built a regular Eurochannel mic pre and tried that. I know this works so when it too oscillated at about 1MHz I knew there was something else wrong. I spent a lot of time adding decoupling, re-routing wires and  adding grid stoppers and small caps the the NFB loop but nothing seemed to work. I could not tame this oscillation. I tried removing the input tube. The oscillation was still present at the output but it was smaller and disappeared after a few minutes. Removing the output tubes removed the oscillation from the output. I tried PCC88 tubes instead of the 6922; I even tried the original 6CG7 tubes but they all oscillated. I even tried a couple of boards where only the tube heaters were wired up and I still got the oscillation at the output! Something very odd was going on here.

This went on for most of January without finding the cause. Eventually I decided to put my oscilloscope across the heaters and there was the oscillation, even with the HT disconnected it was there. It was the new power supply heater regulator oscillating. I checked the datasheet of the new 12V regulator the LT1084V and sure enough it needs a much larger output capacitor for stability - at least 150uF. I changed the existing cap for a 220uF and the oscillation disappeared completely.

The Classic could now be turned up to its full 70dB gain and its EIN with the input shorted was -123dBu, a very satisfactory result. Via  2:1 output transformer I loaded the output with 600 ohms. At 1KHz and +4dBu the distortion was just 0.18%. At +20dBu it rose to 1.08%, again very satisfactory for a mu follower. I then made the same tests on the Eurochannel. Its EIN was slightly worse at -121.5dBu but its distortion into a 600 ohm load was much better as expected, It was  0.026% at 0dBu and only 0,25% at +20dBu.

All these issues with the power supply ( squeezing it into the 28HP box, providing adequate heat sinks and the oscillation problem) prompted me to try something I had been meaning to check out for some time - AC heaters. I had an old home made power supply that had a 6.3VAC heater output. I modified the heater wiring on the Eurochannel card so it would work on 6.3V heaters and connected it to this power supply. I was very pleased to discover that the measured EIN was exactly the same as with DC heaters. I then tried various types of 12AX7 input tube on the basis that if heater hum was going to get into the circuit, the first stage would be the most susceptible. I tried WA, WC and EH variants as well as the type with the spiral wound heaters the LPS. All of them performed exactly the same. I also tried changing the output tubes and this also made no difference.

These results meant that AC heaters were a viable option. The main benefit would be a considerable simplification of the power supply along with a consequent reduction in mains transformer size and a useful cost saving. About this time I became aware of a new 19 inch rack mounting enclosure made by Frank Röllen (who also makes my front panels). One unique feature of this new enclosure is that you can fit support rails in a variety of positions and in one configuration you can create a 10 slot 500 series lunch box. My modules are 2.8 inches wide and double width 500 series modules are 3.0 inches wide. This means that with suitable module front panels and a new motherboard you could possibly built a 5 slot lunch box using Frank's enclosure. The question is, is there room to for an internal power supply.

With AC heaters this looked like a definite possibility. There is about 100mm of space in Frank's enclosure between the back of the motherboard and the rear panel. So I designed a 100mm by 100mm power supply PCB; just HT and phantom power and a couple of resistors to make a virtual centre tap for the AC heaters. Here is a picture of the PCB layout:


And here is its schematic:



 I used a standard Don-Audio toroidal transformer type TB25048 which has 250V, 50V and 12V secondaries. The 12V secondary is only rated at 2 amps which is only enough for four Eurochannel modules but this was sufficient for my initial test purposes. Here is a picture of a test build I did to see how all the components would fit (the motherboard is a standard 6 module one just used for the test).


The mains transformer fits on the right hand side wall with the power supply PCB beneath it and the mains inlet above the PCB. I discovered you can mount three VTB2291 transformers on the left hand wall one above the other so for a five slot lunch box you only need to find room for two more output transformers on the rear panel. Here is a close up of the PSU board and the mains transformer:


So far it looked good. Next I designed a 5 slot motherboard with double width 500 series module spacings that could be attached to Frank's support rails:


There were some issues with fixing the PCB to Frank's rails but in the end it turned out the easiest thing to do was to tap the holes in Frank's rails with a 2.5mm thread and use the same 2.5mm machine screws used to fit the motherboard into an SRS sub-rack. Here are a some of pictures of the new motherboard in Frank's case with a couple of modules:





This all looked pretty good. Notice how the right hand module is very close to where the mains transformer will be mounted. I did not realise it at the time but this would prove to be a problem. I carried out some initial tests on the Classic module plugged into the left most slot and the results were fine. EIN was perhaps not quite as good as when I last measured it but it was within a dB.

In the meantime I began building a four slot lunch box for a German customer - SRS sub-rack, four Eurochannels housed in Fischer extruded aluminium cassettes and full lunch box power supply with DC heaters. All went well until I tested each module with all four plugged in. As I tested each one I noticed that the noise got slightly worse as the module I was testing got nearer to the mains transformer and there was a small hum component in it. The hum was not large and only made a couple of dBs difference to the noise floor even when the module gain was set to 70dB. Moving the transformer and testing with an external power supply soon confirmed the hum was caused by stray magnetic field from the mains transformer. The solution is to screen the transformer and at the moment we are waiting for a mu-metal enclosed transformer to be manufactured.

Naturally, this prompted me to test the  slot right next to the mains transformer in Frank's enclosure. I used the Classic module and, because it is not in a screened box, I was not surprised to find the noise was about 4dB higher than than in the left most slot. Aaron from Don-Audio kindly sent me some GOSS (grain oriented silicon steel) strip to try screening the transformer. I could not get rid of the hum using this but by placing it close to the transformer I could reduce it by a couple of dBs. Mu-metal is very expensive and therefore not really a viable option for a DIY project. I tried shortening the leads to the transformer and twisting them tightly but this did not improve the hum, so I looked around for a cheaper alternative. I found a steel box 100mm x 100mm x 50mm for £5 on eBay. I fitted the mains transformer into it, made a hole in the lid for the wires to come through and mounted the assembly in Frank's enclosure. I turned on, measured the noise and it was back to normal levels and there was no sign of hum. So, although the leakage is small it has a measurable effect, but it can easily be eliminated by some simple low cost screening. The steel box I built is really too big so Aaron is sending me a GOSS top plate to fit over the transformer. Hopefully this will be as effective as the steel box.

Since it was now clear that AC heaters and an internal power supply would work fine with a little care and the right screening, it seemed appropriate to revisit the 28HP power supply PCB. With no need for a regulated heater supply, the PCB layout was very much simpler. I also took the opportunity to change the large 4 amp SIL bridge rectifiers I had used for the HT and 48V supplies to small one amp DIL types which should be more than adequate for the 100mA or so of output current required. I then realised there was no real need for a 28HP module. The mains transformer could be fitted to an SRS rack side panel just as in Frank's enclosure. If I made the power supply PCB Eurocard size it could possibly just plug in like any other module. If I was smart it could feed HT and phantom power straight to the motherboard and apply the heater elevation voltage to the centre tap of a pair of resistors across the heater pins of the PCB. As the heaters would be AC they could be wired direct from the transformer to the power connector on the motherboard. The only question was how to get the HT and 48V AC inputs to the PCB? I then realised the mic and line inputs on this PCB would obviously be unused. What if I fed the HT and phantom AC  supplies into the board through these unused inputs? Here is the PCB layout I came up with:


The HT AC supply comes in via the mic input, goes around the outside of the PCB and exits at the HT pins of the PCB. Inside this loop the phantom AC is fed to the line input pins and its output goes direct to the +48V pins. There was enough room to allow the second two HT smoothing capacitor to be larger diameter types with values up to 470uF for additional smoothing if required. There was also enough room to make provision for a small heatsink to be fitted to the TL783 phantom power regulator. Prototype PCBs are currently being manufactured.

What this means is that it is now possible to build a 5 slot lunch box using the SRS sub-rack and the standard 6 module motherboard. Normal modules occupy the first five positions and the 6th houses the PSU. It should now therefore be possible to build a 5 slot lunch box using either frank's enclosure or a Eurorack. It is an odd number but I am very tempted to standardise on 5 slots for the lunch box. Four Classic mic pres fitted with LCR bus assign toggle switches and a Twin Line Amp for bus amplification would make a simple, self powered, four mic input, stereo all tube mixer in a 3U lunch box.

Friday, 19 December 2014

Power Supply and Enclosure update

The original plan for the Lunch Box was to have an external supply. One of the reasons for this was the relatively high dissipation in the 12V heater regulator and the corresponding size of heatsink required which meant it would not fit inside the rack. After a lot of discussion with Sven on groupdiy.com, this situation has changed. Sven was very keen to have a built in power supply option and wanted to squeeze it into a 28HP wide, 3U high module. I had already tried and failed to squeeze the power supply PCB layout into a 3U high Eurocard format mainly because of the size of the heat sinks. However, with a built in power supply you can only fit a further four modules into the lunch box. Even if all four are mic pre-amps, the 48V phantom power requirement is much reduced. This means the size of its heat sink can be reduced considerably. It also became clear that for good screening, fitting the PSU into a Fischer Electronik cassette would be a good idea. One advantage of using such a cassette is that it can also be used as a heat sink provided the regulator is electrically insulated from the cassette. This is easy to do with the TL783 regulator used for the 48V phantom supply so it was decided to delete its heat sink entirely and rely on the cassette.

Only having four modules to power also reduces the 12V heater supply requirements to just under 2 amps easing the burden its heatsink. To reduce this even further it was decided to replace the TO3 package LM338 regulator of the original 12V supply design with a TO220 package low drop out regulator the LD1084. This has a guaranteed maximum drop out voltage of 1.5V at 5 amps. Not only can this reduce the overall dissipation but it means we can reduce the transformer secondary ac voltage from 14V RMS to 12V RMS which is a much more convenient standard value. I had already built  a small bench supply to power the 6U sub-rack based test rig for the MK3 mixer using the original lunch box PSU board. So I removed the LM338 regulator from this board and replaced it with an LD1084 and changed the transformer secondary voltage to 12V. The temperature rise in the 12V heatsink was much reduced - with a four module load it was less than 20 degrees C which is quite satisfactory.



I later tried the same regulator on an external power supply using the same PCB and a much larger off board heat sink. With a 6 module load, the temperature rise was less than 15 degrees C.




By removing the 48V heatsink, enough room was made available to allow a Eurocard sized PSU PCB to be designed and still retain the existing 12V regulator heatsink as shown below:



As you can see, the TL783 regulator for the 48V supply on the left has no heat sink.

The next question was could it all be made to fit inside the 28HP cassette. First we needed to know how big the mains transformer would be. To allow it to also be used in an external power supply it was decided to rate the 12V heater supply for 6 modules and also to add a 12V utility supply winding. The specification we came up with was:

Primary 0-115, 0-115 @ 50/60Hz for series/parallel operation

Electrostatic Screen

Sec 1 240V @ 140mA

Sec 2 50V @ 70mA

Sec 3 12V @ 4.3A S

Sec 4 12V @ 1.6A GOSS band

Diameter not more than 95mm

Thickness not more than 50mm

Quotations from two manufacturers determined that this specification could be met and Sven and I each ordered a transformer. 

Extensive calculations and measurements then followed to establish if the toroid transformer and the 3U PSU board could all be fitted into a 28HP Fischer cassette along with an IEC mains input connector, a fuse and an on/off switch. I was also concerned about the heat dissipation in the 12V rectifier at higher current and you can see in the picture of the external power supply that I have replaced the on board DIL rectifier with an off board 25 amp rated type that is bolted to the chassis to act as a heat sink. Knowing the Fischer cassette could also be used as a heatsink, we looked at bolting a higher current rating bridge rectifier to it. Below is a sketch showing a possible layout of the major components:



In the last few days, prototype PCBs, the custom transformer and the 28HP cassette have arrived. Here they are fitted together:




So far it looks as though it will all fit in reasonably comfortably.Next step is to complete the build and test the power supply. In the meantime, a 3U rack has been obtained from SRS and filled with four 14HP modules and the 28HP power supply module to give an overall idea of what the lunch box will look like:




Sunday, 12 October 2014

Introduction

The EZ Tube Mixer is an ambitious DIY project (eztubemixer.blogspot.co.uk). As I discovered when building the 4 into 2 demo mixer, there is a lot of cabling between modules and other components and within the modules themselves. The lessons learnt in building the EZ Tube Demo Mixer are being incorporated into the MKIII design which will hopefully be a lot easier to build (mark3vtm.blogspot.co.uk). However, this does not mean that the EZ Tube Mixer design is now obsolete. In the last year it has become clear that there is a lot of interest in much smaller tube projects consisting of perhaps a couple of channels of mic pre, or tube EQ, or compressor or even simple tube mixers. The EZ Tube Lunch Box is intended to fulfil this need.

Just over a year ago I put out a feeler for the EZ Tube Lunch Box project in groupdiy.com. Early discussion centred around the two key issues of power supply and the mechanics. The question with the power supply was whether it should be internal or external to the Lunch Box. After a lot of discussion and some trial PCB layouts it was decided it should be external. This avoids any possible interference problems and gives some flexibility in configuring it for different numbers of modules. A PCB was designed that includes 12V heaters, 300V HT and 48V phantom supplies and a prototype was built and tested:


On testing, it was discovered that the 12V heatsink was not as effective as expected and its temperature rise when powering 4 modules was too high. The 12V rectifier also got hotter than expected. The PCB layout was modified to allow the 12V regulator and its heatsink to be mounted off board for larger projects. For these projects a separate off board rectifier should also be used. The schematic of the power supply is shown below:


The mechanics discussion centred on the overall size of the lunch box, the ability to expand it and how to make it for a reasonable price. There are plenty of off-the-shelf 3U high 19-inch sub-racks available that are not too expensive. One of these will hold up to six modules. However, making anything smaller, for example a three module lunch box, involves doing something special which generally ends up meaning more expensive. On balance, the general consensus was that a standard sub-rack was the best solution and one that everyone could live with. If someone really needs one that is three modules wide they could always cut down a standard sub-rack.

During the discussion, Holger revealed he had already built something very similar to the lunch box. It looks like this:


The thing that first struck me about this is that Holger has placed the input and output connectors on the front rather than at the rear as is more usual. My original thoughts were that the sub-rack would need to be quite deep. The reason is that the EZ Tube PCBs do not contain any output transformers so, if used, they need to be mounted externally. Since I had expected the input/output connectors would be at the back of the sub-rack it made sense to put the transformers there also. So this means you need sufficient depth in the rack to mount them from the rear panel. However, if instead you assign a couple of module widths to input output connectors on the front, then there will be space behind them to fit any output transformers. This means the sub-rack can be a little less deep and also a little cheaper. Once you allow connectors at the front you realise there are other possibilities, like fitting meters and faders, for example, to the front. This configuration is ideal for location recording where it can be a real nuisance to have to keep going round the back of a rack to plug things in.

As a result of this I have decided to develop two versions of the mechanics.  One will have the lesser depth rack and will be intended for use with front panel mounted input and output connectors. The second will be deeper and have room for rear mounted transformers. Connectors would also normally be rear mounted. In both cases, the dc supply would enter though the rear panel. I have ordered a rack of each type from SRS in the UK and I will build both of them as part of this project.