Measuring DC resistances is one of the functions pretty much every bench multimeter provides. Then why would you need a separate resistance meter?
One of the best digital multimeters available on the market offers a lowest resistance range of 1 Ohm. That is great and more than sufficient when developing circuits or testing PCBs. However, when measuring the electrical resistance of conductive materials or welding contacts, then you are looking at values which are more in the mOhm or µOhm range. That’s why the “smallest” bench resistance meter from HIOKI – the RM3544 – has a lowest resistance range of 30 mOhm. It’s “bigger brother”, the RM3545, has a lowest resistance range of 10 mOhm and a resolution of just 0.01 µOhm.
Another aspect is measurement time: Multimeters are not necessarily optimized to perform measurements at high speed. HIOKI’s resistance meters, on the other hand, have been designed to also perform resistance measurements in mass production environments where speed is an important factor. For example, when a module of lithium ion batteries is produced then typically the quality of every spot weld connection to the busbar is tested by measuring the contact resistance. The RM3545 can perform such a measurement in it’s smallest 10 mOhm resistance range in just 41 ms (fast mode). In higher resistance ranges the measurement time is as low as 2.2 ms.
A very useful function – which is hard to find even in top of the range multimeters – is a contact check function: If activated, it only starts a measurement after ensuring that the probe has proper contact to the device under test. This is a feature surely not critical in a lab environment, but really useful in production environments where it helps to avoid rejects caused by poor contact of the probe to the DUT. N.B.: The contact check function is featured in all versions of the RM3545, but neither in the RM3544 nor the RM3544-01.
Coming back to the example with the busbar welds of the battery module: The longest time in a test process is mechanically moving the DUT to the test probe or test fixture. Once positioned, you want to perform as many tests as possible before having to mechanically move the DUT again. This is where multiplexers come into play. Especially when the number of tests to be performed is high, dedicated multiplexers like HIOKI’s SW1002 provide the required number of measurement channels. If the number of channels required is 20 or less, then such a dedicated multiplexer unit isn’t required. In this case the RM3545-02 offers two slots on the backside that can each hold a multiplexer card Z3003. Each of these multiplexer cards offers 10 measurement channels for 4-wire measurements and they can be easily added to the RM3545-02 models. N.B.: You can only add multiplexer cards to the RM3545-02 model, but not to any other version of the RM3545 as those others don’t have the slots required to add the cards.
4-wire measurements usually mean 4 connectors at the measurement instrument for the test lead. However, if you look closely at the RM3544 or RM3545 then you will see 5 connectors instead of 4. The 5th connector is the so called “guard terminal”, which is designed to reduce measurement noise that can become relevant especially when test currents are small, i.e. in the high resistance ranges. Technically the guard terminal allows to “ground the shield” of the test lead. The guard terminal is supported in HIOKI’s test leads L2101, L2102, L2103 and L2104. Of course you can also use test leads with the RM3544 and RM3545 that don’t connect to the guard terminal, such as HIOKI’s test lead L2100. Especially when you intend to measure small resistances then the test currents are high and the impact of noise is low. But again, especially in the MOhm resistance ranges not using the guard terminal can impact the measurement results.
The temperature sensor Z2001 is not just a nice add-on that allows you to also read the temperature when making a resistance measurement. Instead it allows to correct the measured resistance value by taking into account a user-specific resistance temperature coefficient. This is especially useful when measurements can’t be performed in a temperature controlled environment. The Z2001 temperature sensor is an included accessory of the RM3545 models and an option for the RM3544.
Another really useful accessory is the LED Comparator Attachment L2105: It indicates judgment results with green and red LEDs, eliminating the need to look at the instrument’s screen. Since the lamps do not light up when the measurement leads are open, this little optional accessory can also be used to ensure a proper connection to the DUT.
And finally, should you have an application which does require a measurement instrument with a low resistance range but at the same time doesn’t allow you to use a bench resistance meter, then HIOKI’s RM3548 might be the solution: It is portable, yet still features a smallest resolution of just 1 µOhm and offers a smallest measurement range of only 3 mOhm.
The RM3548 doesn’t feature a guard terminal, as this portable resistance meter is typically used for lower resistances. Lower resistances mean that predominantly higher measurement currents are used for the measurements, making the “grounding of the shield” of the test lead unnecessary. Also, the above mentioned RM3545 resistance meter has a largest resistance range of 1200 MOhm, while the RM3548‘s largest resistance range is “just” 3.5 MOhm.
Like the bench models RM3544 and RM3545, the RM3548 also supports the L2105 Comparator Attachment. And like the bench models the RM3548 offers a temperature correction and temperature conversion function. That said, bear in mind that the temperature sensor for the RM3548 is called Z2002, which is a different one than the Z2001 used for the bench models.
Conclusion:
Multimeters without any doubt offer a huge range of functions that make it one of the most important test tools on a lab bench. At the same time there are requirements where dedicated resistance meters can make a real difference.
