There are numerous environmental factors that may interfere with the performance of a pressure transducer. Two factors that sometimes overlooked to engineers are shock and vibration. Knowing the system where the pressure transducer is installed can help avoid high shock and vibration conditions, minimizing premature failure of your instrumentation. Before understanding the risks associated with shock and vibration, how a pressure transducer may experience or encounter these effects must be defined.
Shock is a sudden, unexpected impact that transmits energy to a device in a relatively short time interval. For a pressure transducer, that energy passes through the stainless steel up through the housing. Shock may originate from rough transportation and handling, such as by trucks, forklifts and conveyors. Alternately, shock can be caused simply by dropping the transducer
Vibration is yet another consideration. Vibration is continuous oscillation directed at the transducer. In the case of an engine test cell, for instance, the running engine emits a constant vibration that might affect transducer operation if it is mounted too close.
Shock and vibration can cause a wide range of problems, including dented enclosures, disconnected wires, broken circuit boards, faulty signals, intermittent problems and shortened life. To prevent shock and vibration during the assembly procedure, OEMs should first realize this potential problem — many do not — and then take measures to prevent it. As simple as it sounds, the best remedy is to install transducers as remotely as possible from obvious sources of shock and vibration. Depending on the installation, another possible solution is the use of shock and vibration isolators.
Transducer suppliers can provide OEMs with information needed to design a system where the transducer can be handled appropriately during installation. They advise engineers to design their transducer installation so only a few tools are used for its assembly rather than an entire toolbox, increasing the likelihood that the correct tool will be used during the assembly process. Also, care should be taken to ensure the correct tools are used. For example, assemblers shouldn’t use channel locks that may gouge and scratch the pipe when a standard open-end wrench will suffice. Moreover, if the assembly is heavier than the approved weight limit, work procedures should state that two people are required to lift it, rather than one who might drop and damage the assembly.
CLICK HERE to learn how to select a sensor to handle high temperature environments.