Macro Sensors
7300 US Route 130 , North Building 22 , Pennsauken, New Jersey, United States

Macro Sensors Company History

Macro Sensors is "your sensor business partner...," solving position measurement problems as an extension of the customer's engineering resource. Macro Sensors designs and manufactures highly accurate, extremely rugged position sensors utilized in industrial and aerospace applications worldwide.

Macro Sensors traces its origins directly to Herman Schaevitz who founded Schaevitz Engineering in 1945. Mr. Schaevitz is widely recognized as the pioneer developer of LVDT technology. He transformed the LVDT from a hand-made laboratory device to the mission critical position sensor it is today and built Schaevitz Engineering into a successful enterprise with the LVDT as the core product. His son, and former Shaevitz CEO Howard, formed Macro Sensors.

Macro Sensors major strengths include application support, semi-custom and custom design engineering, extensive product testing and qualification, and excellent on-time delivery. The core LVDT technology is proven as a long term reliable electro-mechanical device. Macro Sensors is ISO 9001:2008 certified with various other third party approvals. Macro Sensors has built upon this by expanding the technology's reach into higher pressures, extremely high and low temperatures, digital signal conditioning and miniature sizes.

What Is An LVDT?

The letters LVDT are an acronym for Linear Variable Differential Transformer, a common type of electromechanical transducer that can convert the rectilinear motion of an object to which it is coupled mechanically into a corresponding electrical signal. LVDT linear position sensors are readily available that can measure movements as small as a few millionths of an inch up to several inches, but are also capable of measuring positions up to ±20 inches (±0.5 m).

Figure 1 shows the components of a typical LVDT. The transformer's internal structure consists of a primary winding centered between a pair of identically wound secondary windings, symmetrically spaced about the primary. The coils are wound on a one-piece hollow form of thermally stable glass reinforced polymer, encapsulated against moisture, wrapped in a high permeability magnetic shield, and then secured in a cylindrical stainless steel housing. This coil assembly is usually the stationary element of the position sensor.

The moving element of an LVDT is a separate tubular armature of magnetically permeable material called the core, which is free to move axially within the coil's hollow bore, and mechanically coupled to the object whose position is being measured. This bore is typically large enough to provide substantial radial clearance between the core and bore, with no physical contact between it and the coil.

In operation, the LVDT's primary winding is energized by alternating current of appropriate amplitude and frequency, known as the primary excitation. The LVDT's electrical output signal is the differential AC voltage between the two secondary windings, which varies with the axial position of the core within the LVDT coil. Usually this AC output voltage is converted by suitable electronic circuitry to high level DC voltage or current that is more convenient to use.

How Does An LVDT Work?

Figure 2 illustrates what happens when the LVDT's core is in different axial positions. The LVDT's primary winding, P, is energized by a constant amplitude AC source. The magnetic flux thus developed is coupled by the core to the adjacent secondary windings, S1 and S2. If the core is located midway between S1 and S2, equal flux is coupled to each secondary so the voltages, E1 and E2, induced in windings S1 and S2 respectively, are equal. At this reference midway core position, known as the null point, the differential voltage output, (E1 - E2), is essentially zero.

As shown in Figure 2, if the core is moved closer to S1 than to S2, more flux is coupled to S1and less to S2, so the induced voltage E1 is increased while E2 is decreased, resulting in the differential voltage (E1 - E2). Conversely, if the core is moved closer to S2, more flux is coupled to S2 and less to S1, so E2 is increased as E1 is decreased, resulting in the differential voltage (E2 - E1).