Magnetometers
At PCE Instruments you will find magnetometers for electromagnetic fields (EMF) and electromagnets. Magnetometers for electromagnetic fields are becoming increasingly important due to the increasing negative influences of EMF on the environm ent. Magnetometers are used to detect electromagnetic charges found in the personal and professional environments, such as those emitted by transformers, overhead power lines and electrical devices. If you want more information relating to radioactivity, access this link to see more details about it. Magnetometers have a wide range of uses within the industrial sector or in research and development. They have DIN ISO 9000 calibration certificates and other optional accessories available if needed. If you can't find the magnetometers you are looking for, please contact us and we will help you find the best solution to suit your needs by calling our offices on: +44 (0)2380 987030 and our technical staff will advise you regarding our measuring instruments. 

Here you can see magnetometers from this company:

Technical specifications for magnetometers can be found at the following links:

- PCE-MFM 3000 Magnetometers
  (Magnetometers to determine static and dynamic fields / polarity indication)

- Magnetometers PCE-EMF 823 
  (electromagnetic field-tester)

- Magnetometers PCE-G28 
  (for megnetic fields, triaxial probe, up to 2000 µTesla or. 20000 mGauss)

- Magnetometers Fauser FM 6

  (to measure alternating magnetic fields up to 20000 nT, optional probes f.e. for TCO directive)

- Magnetometers Gigahertz Solutions NFA 30M

  (Magnetometers to measure alternating magnetic fields up to 32 kHz, measuring range up to 19999 nT)

- Magnetometers Simco FMX-003
  (to measure static clampings up to ±22 kV, LED, battery operation)

- Magnetometers Fauser STS 1
  (to measure static clampings in two measuring ranges, up to ±20 kV, battery operation)

- Magnetometers Statech Systems DZ4
  (to measure static charges, up to ±19,99 kV, swiveling measuring head)

- Magnetometers ME3851A

  (up to 100 kHz, to measure eletric and magnetic fields, variable filters)

- Magnetometers ME3951a

  (TCO Magnetometers up to 400 kHz,  for alternating electric and magnetic fields)

 - Magnetometers Fauser FM 10

   (to measure alternating magnetic and electric fields, up to 400 kHz, 3 filter ranges, optional probes)

- Magnetometers NFA 1000

  (Magnetometers, Datalogger, for alternating electric und magnetic fields, effect as a Geiger counter)

- Magnetometers PCE-EM 29
  (for RF-radiation, triaxial probe, frequence range up to 3,5 GHz, display f.e. in mW/m²)

- Magnetometers PCE-EM 30
  (for electromagnetic radiation V/m, W/m², mW/cm², 100 kHz ... 3,5 GHz)

- Magnetometers HFW35C
  (Magnetometers up to 6 GHz, for alternating electric fields, for prof. HF-measuring)

 - Magnetometers HF58B

   (Magnetometers up to 2,5 GHz, for building biology, battery- und mains operation, for GSM and DECT)

- Magnetometers HF58B-r

  (Magnetometers up to 2,5 GHz, for professional HF-measurings, for GSM and DECT)

- Magnetometers HF59B

  (Magnetometers up to 2,5 GHz, for GSM and DECT, with Audio-analyse)

- Magnetometers Set HFE35C

  (Magnetometers up to > 3,3 GHz, for GSM, DECT, WLAN, with LogPer-aerial)

- Magnetometers Set HFE59B

  (Magnetometers up to > 3,3 GHz for EMVU and product development)

- Magnetometers Koffer MK30

  (Magnetometers case, HF38B, ME3840B incl. supplies)

- Magnetometers Koffer MK60 3D

  (Magnetometers with measuring kit, HF58B-r, NFA-400, incl. supplies, plastic case)

- Magnetometers Koffer MK70 3D

  (Magnetometers in practical kit, HFE59B, NFA1000, incl. supplies, plastic case)

In physics, radiation is the way in which energy spreads through space, in analogue form, light can be used to express to refer to the movement of particles at high velocity across this medium.

Electromagnetic fields are generated by electrical devices and installations. They can have a strong influence upon us depending on their frequency. The consequences can go from a general ill feeling to nervousness up to and including internal burns. For these reason, based on labour protection laws and industrial provisions, it is necessary to determine the risk to workers exposed to electromagnetic fields.

Examples of variations in electromagnetic fields by distance

Density values of magnetic flow (B, in microteslas, µT), measured one meter from ground level, near a railway's electrical line (the tower is not to scale). You can see that value B is significantly reduced at greater distances from the line. In this way, in the vertical portion of the line, B can increase values up to 6 µT; at 15 meters from the line B is reduced by half, and for distances greater than 30 meters B will be in the order of tenths of a micro tesla.

If you wish to view or print the selection of magnetometers m our catalogue, click on the PDF symbol