Such a PID-controller produces an ON/OFF-ouput, no nice smooth analog output for low EMI.
Switching power supply dont belong in a voltnut-lab/you would spend your time hunting for mysterious voltage offsets in your measurements due to those SMPS.
If youre really aiming for high resolution/low noise-measurements then such simple PID-controllers will give you headaches.
Thats at least my experience after having dealt with them. 
Ive gone from such PID-controllers + SMPS, to PID-controller + linear supply, to the mentioned Conductus LTC-10 to real TEC-controller as LDT5910B and Arroyo 5235.
I remember that i could see the errors due the on/off-control-loop from the PID-controller very well and that it was very annoying to use it with a PC to get temp-curves running via controller-Analog-In/Modbus.
If you only want to use heaters id suggest getting a LTC-10, costs ~150$ used and youll be lightyears ahead of the cheapest PID-controller + SMPS-solution and youll love it for its many functions, GPIB-connectivity and stability.
Thinking back i wasted much time, instead of just investing a bit more money for good gear and be done with it.
Sorry if thats not want you want to hear, but i think its better if you can avoid the trouble which ive gone trough.
A fan doesnt add much noise (afaik), but you should remember to shield youre measured device against air drafts.
Maybe wrap it a bit in paper for example, that way the measurement box gets thermally equalized well and you avoid air drafts at the critical device.
What do you want to measure exactly?
I decided to take your advice and get a LTC-21 I found... it wasn't easy to find (it seems the company changed hands as I found it under Neocera company) but I found the manual for it in digital format. Thanks for the tip. Here are the stats:
Display
Sensor data may be displayed in units of Kelvin, Fahrenheit, Celsius, Volts or Ohms.
• All displays are six digits plus sign, a floating decimal point and a units indicator.
• Time averaging may be performed by operator selection of intervals between 0.5 and
16 Seconds.
Accuracy of Sensor Measurements
The accuracy of linear resistance sensor measurements, including Platinum, Carbon-Glass
etc. is 0.1% within the resistance range of 100Ω to 1KΩ , 0.25% from 1KΩ to 10KΩ and
1% between 10KΩ and 30KΩ.
The accuracy of diode sensor measurements is 0.05%.
The accuracy of sensors using the variable ac constant voltage biasing is given in the
following table:
Excitation Accuracy Resistance Range
1mV 0.1% 1 Ω to 1 MΩ
320uV 0.1% 1 Ω to 500 kΩ
1% 500 kΩ to 1 MΩ
100uV 0.1% 1 Ω to 150 kΩ
1% 150 kΩ to 1 MΩ
32uV 0.5% 1 Ω to 50 kΩ
2% 50 kΩ to 500 kΩ
10% 500 kΩ to 1 MΩ
10uV 0.5% 1 Ω to 15 kΩ
2% 15 kΩ to 150 kΩ
10% 150 kΩ to 1 MΩ
Table 1 Sensor Accuracy vs Sensor Excitation
All accuracy specifications are valid over the rated environmental temperature range.
Range of Temperature Measurements.
The instrument will measure and display temperatures in the range of 0K to 800K. (That's -459.67 F to 980.33 F)
The actual temperature range for measurement is, of course, dependent on the type of sensor
used.
Temperature Resolution
The temperature resolution of the LTC-21 is 1 part in 512000.
Bill
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