MagneLink designs and manufactures magnetic switches for customers in a broad range of industries. We specialize
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in the development of custom-designed magnetic switches engineered to meet particular application requirements. Our extensive selection of switches includes high-performance magnetic limit switches in various designs and configurations.
What Is a Traditional Limit Switch?
A limit switch is an automatic sensor assembly that requires direct physical contact to detect the position of an object or material. It is commonly used to monitor the presence/absence, proximity, and/or movement of items or materials within a system. Based on what it detects, an actuator opens or closes the electrical contacts, which automatically stops or starts the flow of electricity to connected equipment. This capability makes limit switches ideal for use in applications where strict limits must be observed.
What Is a Non-Contact Magnetic Limit Switch?
Non-contact magnetic switches are similar to traditional limit switches, but with the added advantage of operating without requiring physical contact between the switch and actuator. This added feature makes a non-contact magnetic switch a better performer in harsh or dirty environments, as well as making it more difficult to override. A non-contact magnetic limit switch also has a longer lifespan thereby reducing potential down-time for equipment repair.
How Does a Limit Switch Work?
The original purpose of limit switches was to monitor the movement of objects or materials within a system and stop their progression at a pre-set limit without the need for direct human intervention. They perform this function by having an actuator that breaks an electrical connection when an object or material comes into contact with it. This stops the operation of the equipment and, consequently, the movement of the load.
In other applications, a limit switch may make an electrical connection when an object or material comes into contact with it. This activates a connected device or system, enabling it to perform the necessary function for the situation.
For more information, please visit Plunger Limit Switch.
Components of a Limit Switch
A standard limit switch consists of an actuator with an operating head, switch body, and electrical terminals.
- The operating head transmits the linear or rotary force from contact with the triggering object to the actuator.
- The actuator opens or closes the switch in response to the application or removal of force.
- The switch body contains the switch contact mechanism that opens or closes the connections between electrical terminals.
- The electrical terminals connect the switch to the electrical circuit it is controlling.
Industrial applications often require highly durable and reliable switches that can withstand heavy use without compromising accuracy. Limit switches can be customized to meet the needs of particular equipment and operations. By adjusting the size, mounting, stroke rate, electrical rating, and operational force of the switch, you can ensure dependable, safe equipment operation even in harsh industrial conditions.
Types of Limit Switches
There are many types of limit switches, each of which offers unique characteristics that make it suitable for different uses and environments. They can be divided into four categories based on the operating head design and actuation method:
- Non-contact magnetic limit switch: Non-contact magnetic limit switches are highly responsive switches that are controlled using a magnet actuator on a moving component of the equipment (i.e. door, gate, piston). The actuator triggers the switch when in close proximity to it. The switch can then electrically trigger alarms, shutoffs, etc. Non-contact magnetic limit switches offer a quick response time, making them an excellent choice for applications in door switches, elevators, light switches, lifts, conveyors, pressure switches, and temperature switches.
- Whisker limit switch: Whisker limit switches have a long flexible spring arm (i.e., whisker) that bends when an actuating force is applied and springs back to its normal position when it is removed. They are often used in conveyor and assembly line applications, where they can monitor the flow and placement of materials and sound an alarm if items are out of place.
- Roller limit switch: Roller limit switches use a roller on a stationary shaft to measure the flow of material or the number of items passing down a line or conveyor. They measure item quantity, volume, or flow based on the number of roller revolutions.
- Lever limit switch: Lever limit switches are highly responsive switches that are controlled using a lever mounted on a rotating shaft. The lever allows motion to continue to a pre-set limit. Once the lever rotates around the shaft to the limit point, the switch opens the circuit, triggering alarms or shutoffs. Lever limit switches provide a very quick response time, which makes them ideal for use in door-open indicators, elevators, lifts, conveyors, pressure switches, and temperature switches.
- Plunger limit switch: Plunger switches are equipped with a plunger that requires less physical force to activate than other limit switches. The plunger is connected to a spring and electrical contact such that it opens or closes the circuit when it is depressed. They are ideal for use in filling and conveyor applications where quick response time is a must.
Limit switches can also have a design that combines characteristics of two of the above four types.
Applications & Uses for Limit Switches
Limit switches are incorporated into a variety of flow control, conveyance, and sensing applications. They are durable, versatile, and accurate, with a range of designs, mounting systems, and sizes to meet even the most stringent specifications. Some of the most common applications for limit switches include:
- Conveyors: Limit switches are used to monitor and control the location, speed, and quantity of material and objects in conveyor applications.
- Assembly lines: Assembly lines use limit switches to monitor and control the location, position, quantity, and speed of components on the assembly line.
- Magnetic control circuits: Limit switches are used in electric motors to control start, stop, acceleration, and deceleration operations.
- Emergency systems: Limit switches are used to notify operators of equipment malfunctions, overloading, temperature fluctuations, pressure extremes, open enclosures, and other conditions that can affect the safety of your operation.
- Appliance lights: Limit switches are incorporated into ovens, refrigerators, microwaves, and other household devices that activate lights when you open the door.
- Automotive systems: Limit switches are used to turn on interior vehicle lights when the door is opened. They are also incorporated into automotive manufacturing and assembly equipment.
- Counting operations: Limit switches are used to count the number of products on conveyors for production, assembly, packaging, and other industrial and manufacturing operations.
- Fill stations: For operations that use buckets, baskets, boxes, and other containers, limit switches are used to automatically detect when a container is full for faster and more accurate filling operations.
Magnetic Switches From MagneLink Inc.
At MagneLink, we pride ourselves on providing superior quality limit switches to customers in virtually every industry. Whether you need a simple limit switch for refrigerator doors or complex safety shutoff limit switches for heavy industrial operations, our seasoned experts can help you find the perfect solution. Our limit switches are available in a wide selection of configurations, including Reed switches, Hall Effect switches, triac and transistor switches, coded switches, and interlock switches. To learn more about our product solutions, contact us today.
If you are looking for more details, kindly visit Safety Limit Switch.
Posted in Limit Switch
My Tormach mill came with microswitch limit switches. They have a plunger with a roller on the end which contacts a ramp and are relatively immune to flood coolant. However, I found them to be less accurate than desired for use as a homing switch so I devised my own optical homing sensors. The OEM had a repeatability of around =/- .. The optical system is =/-.".
The Grizzly G mill uses mechanical switches in conjunction with spring loaded plungers. The spring loaded feature permits overruns without hard crashes. The parts could be ordered as replacement parts. The actual switch is located in a housing and should also be relatively immune to flood coolant.
If reproducible homing isn't required, either of these mechanical systems should be suitable.
My Tormach mill came with microswitch limit switches. They have a plunger with a roller on the end which contacts a ramp and are relatively immune to flood coolant. However, I found them to be less accurate than desired for use as a homing switch so I devised my own optical homing sensors. The OEM had a repeatability of around =/- .. The optical system is =/-.".
The Grizzly G mill uses mechanical switches in conjunction with spring loaded plungers. The spring loaded feature permits overruns without hard crashes. The parts could be ordered as replacement parts. The actual switch is located in a housing and should also be relatively immune to flood coolant.
If reproducible homing isn't required, either of these mechanical systems should be suitable.
The optical homing sensors that you came up with if you could share what you ended up doing, that would be fantastic repeatability on your system versus microswitches is far superior.
Thanks,
Lynn M.
The optical homing sensors that you came up with if you could share what you ended up doing, that would be fantastic repeatability on your system versus microswitches is far superior.
Thanks,
Lynn M.
I had done a write up some time in the distant past. There is a fairly complete discussion of the project on CNC Zone. https://www.cnczone.com/forums/torm...ng-proximity-sensors-tormach-pathpilot-2.html I also have a full set of documentation on Dropbox.
The modification is by no means plug & play. To get the required sensitivity, I used a special optoisolator and designed my own optics and electronics. The system has been in operation for more than ten years and t date there have only been three failures. One was a component failure; another had to do with coolant getting into one of the optointerupter windows after some prolonged heavy usage. That was clear up with a blast of compressed air and a redesign of the shield corrected the problem. The third occurred recently when I was using the mill for some wood work and a lot of fine dist was generated. Again, a blast of compressed air solved the problem.
I left the OEM limit switches intact as a backup. Should the optical system fail to properly home for some reason, it will hit the mechanical switches some .040" in back of them. PathPilot has a feature in that once the system is homed, it knows where the the limits are and will never exceed them, even traversing at rapid speed so it has been literally years since my mechanical switches have been activated.
Would anybody, have a suggestion or information on what switches they’re using for the limit switch inputs something that’s relatively impervious to flood coolant
Thanks,
Lynn M.
$114 at Grainger. I've used many of these in another life and found them to be high quality.
HONEYWELL MICRO SWITCH General Purpose Limit Switch: 1NC/1NO, 15A @ 600V, 2A @ 250V, Top, Surface
Item 12U161
Mfr. Model BZE6-2RN
Product Details
Catalog Page262
Limit Switch StyleGeneral Purpose Limit Switch
Basic Actuator Style - Limit SwitchPlunger
Actuator Style - Limit SwitchPlunger
Actuator Location - Limit SwitchTop
AC Contact Rating - Limit Switch15A @ 600V
DC Contact Rating - Limit Switch2A @ 250V
Contact Form- Switches1NC/1NO
Actuator Length - Limit Switch0.97 in
Body Height - Limit Switch1.75 in
Body Width - Limit Switch3.04 in
Body Depth - Limit Switch1 in
Boot Sealed Actuator - Limit SwitchYes
Mounting - Limit SwitchSurface
Body Style - Limit SwitchMiniature
NEMA Rating1; 3; 4
Wiring Entry1/2 in NPT
Electrical ConnectionScrew Terminals
IP Rating66
MovementRelease Force 0.25 lb min
TravelDifferential Travel 0. in to 0. in; Maximum Pretravel 0.078 in; Minimum Over Travel 0.219 in
Operating Temp. Range-25° to 160°F
Mounting Hole Pattern - Limit Switch2 Hole Horizontal
Mounting Hole Spacing - Limit Switch1.00 in
Mounting Hole - Limit Switch(2) 0.22 in dia
Stem Thread - Limit SwitchNo Stem
Body MaterialZinc Die Cast
StandardsCSA; UL
UNSPSC
Country of OriginUSA (subject to change)
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