Hydraulicspneumatics 2189 Assemblyline595
Hydraulicspneumatics 2189 Assemblyline595
Hydraulicspneumatics 2189 Assemblyline595
Hydraulicspneumatics 2189 Assemblyline595
Hydraulicspneumatics 2189 Assemblyline595

Why Solenoid Coils on Hydraulic Valves Burn-Out

March 10, 2015
The high current draw of an open AC solenoid is known as inrush current. And the current draw when the solenoid is closed is called holding current. AC solenoids can only dissipate the heat generated by their holding current. This means it's very important for the plunger to close completely when an AC solenoid is energized, otherwise the coil will burn out.

I got this question from one of our members:

"Could you explain heat generation in hydraulic valve solenoid coils? If the temperature of the coil increases what will happen to the directional control valve's function?"

The short answer to this is: the solenoid coil will fail and therefore the hydraulic valve itself will cease to function.

In AC electric coils the resistance or impedance of the coil is lowest when the solenoid is open, i.e. when the plunger is out. Impedance increases as the plunger is pulled into the closed position. As a result, the current draw of an AC solenoid is highest when the solenoid is open (plunger out) and lowest when the solenoid is closed (plunger in).

The high current draw of an open AC solenoid is known as inrush current. And the current draw when the solenoid is closed is called holding current. AC solenoids can only dissipate the heat generated by their holding current. This means it's very important for the plunger to close completely when an AC solenoid is energized.

In other words, the high inrush current generates more heat than can be continuously dissipated by the solenoid. So if the plunger is not able to be completely pulled into its coil - due to a mechanical problem with the valve for example, then the insulation around the coil windings will burn and the coil will short out.

But what could go wrong with a hydraulic valve that would stop the solenoid plunger from being pulled in completely? Well, contamination is a common cause. When hard or soft particles invade the clearance between the spool and its bore, the solenoid may not have enough power to fully shift the valve's spool. This is often referred to as "silt-lock".

If silt-lock is the problem, then replacing the solenoid is a waste of time. Replacing the entire valve will BUY some time - until it too becomes 'silt-locked'. The solution of course, is to get the contamination problem under control.

Another problem presented by the inrush current characteristics of AC solenoids, is the possibility of overheating due to rapid cycling. Each time the solenoid is closed it is subject to the heating affect of the high inrush current. If the solenoid is switched on and off too rapidly, the successive inrush currents can generate more heat than can be dissipated, leading to failure of the solenoid.

Still, an AC solenoid can be cycled quite rapidly. To give you some idea, a class H solenoid, which has insulation rated to 180C, can be safely switched twice per second. But a DC solenoid with class F insulation rated to 150C can be cycled four times per second without any fear of overheating. And the nice thing about DC solenoids is they don't burn out if the plunger doesn't get pulled in completely - due to silt lock or any other reason.
 
Bottom line: burnt-out valve solenoids is another cost of failing to properly control contamination. And to discover six other costly mistakes you want to be sure to avoid with your hydraulic equipment, get "Six Costly Mistakes Most Hydraulics Users Make... And How You Can Avoid Them!" available for FREE download here.

About the Author

Brendan Casey Blog | Author

Brendan Casey is a war-weary and battle-scarred veteran of the hydraulics industry. He's the author of The Hydraulic Troubleshooting Handbook, Insider Secrets to Hydraulics, Preventing Hydraulic Failures, The Definitive Guide to Hydraulic Troubleshooting, The Hydraulic Breakdown Prevention Blueprint and co-author of Hydraulics Made Easy and Advanced Hydraulic Control. And when he's not writing about hydraulics or teaching it, Brendan is flat-out helping consulting clients from a diverse range of industries solve their hydraulic problems. To contact him visit his company's Website:
www.HydraulicSupermarket.com

Continue Reading

Hydraulic-Electric Analogies, Part 5: Current and Electrical Fields

Aug. 12, 2014
Electrical engineers take pride in the precision of their language, despite contradictions such as in the case of open and closed switches.

Rotary selector air valves

April 13, 2006
Multi-port rotary selector valves are quiet replacements for solenoid valves. Single input can be switched between 2 to 6 output ports. They are available with detents for manual...

Sponsored Recommendations

7 Key Considerations for Selecting a Medical Pump

Feb. 6, 2024
Newcomers to medical device design may think pressure and flow rate are sufficient parameters whenselecting a pump. While this may be true in some industrial applications, medical...

How Variable Volume Pumps Work

Feb. 6, 2024
Variable volume pumps, also known as precision dispense pumps, are a positive displacement pump that operates by retracting a piston to aspirate a fluid and then extending the...

What is a Check Valve and How Does it Work?

Feb. 6, 2024
Acheck valve, a non-return or one-way valve, is a mechanical device that allows a gas or liquid to flow freely in one direction while preventing reverse flow in the opposite ...

The Difference Between Calibrated Orifices and Holes

Feb. 6, 2024
Engineers tasked with managing fluid flow talk about both holes and calibrated orifices, but they are two distinct entities. A hole can be any opening, but a calibrated orifice...