How To Choose An Electric Strike Lock

The electric strike lock may not be a colorful component in a locking system, but it is one of the most important. This type of lock is not only cost-effective, but also a better alternative than electrified lock mechanisms in some circumstances.

 

Reasons for An Electric Strike Lock

Electric strikes are devices installed on doors to allow entry via an access system or remote release system.

 

Unlike a magnetic lock, a strike does not secure a door; that’s the responsibility of the door handle or lockset. The electric strike allows access to a secured door with a key card, pass, etc., without the need for a key to the lockset.

 

Types of Electric Strike Locks

There are two styles of electric strike lock:

 

  • Fail-Safe Locks

Fail-safe locks (also called fail-open) operate as a magnetic lock would. A direct electric current is applied to the strike, causing the door to lock. In a power failure, the door can be pushed or pulled open.

 

  • Fail-Secure Locks

Fail-secure locks (also called non-fail safe or fail-locked) open when an electric current is applied to them. In a power failure, this kind of lock will remain locked, although the mechanical can still be used to open the door from the inside.

 

An electric strike lock is useful on any door where high traffic occurs and requires monitoring or where items need to be secured and safeguarded. It also regulates employee access and helps prevent employee theft.

 

Choosing An Electric Strike Lock

Choosing the right kind of electric strike lock depends on the kind of door you have. The door material, and whether the door is internal or external, double or single, determines which electric strike lock is best. Strikes are available for nearly all door styles and of various material types, like aluminum and timber.

 

Security and Monitoring Requirements

The level of security desired will impact the type of strike that is best for your doors and circumstance.

 

For example, a low-security situation with no defined holding force may only require a low-cost electric strike. However, in a high-security environment, a strike with a maximum holding force of 1,500 pounds or more may be necessary.

 

Most electric strike manufacturers produce strikes with or without a monitoring facility. Door state monitoring should involve the use of a separate reed switch on the door or frame.

 

Type of Lockset

Your electric strike lock must be compatible with the type of lockset on your door. Use the lockset manufacturer’s compatibility chart to determine if your electric strike works with the lockset in question.

 

Latch Bolt Dimensions

Similar to a lockset, your choice of electric strike lock will need to accommodate the type of lock bolt sizes. Make sure that the centerline location of the latch bolt is correctly positioned around the centerline of the lockset to ensure that the lock will work as desired.

 

Power Needs

Most electric strike locks are 24 VDC, although 12 and 24 VAC options are also available. Choosing AC or DC power is critical because each strike application is different. Consider regulated or filtered power sources where practical as these sources will extend life to the strike’s operating capacity.

 

Code Compliance

Fail-secure electric strike locks must be used on fire-rated doors so that the door automatically goes into a locked position when the power is turned off. Because fail-safe locks go into an unlocked state when no power is applied, they do not meet code requirements for fire doors.

 

Consult the professional electric locks company if you are uncertain about what kind of electric strike lock you need for your building or office. Here, I recommend that you can visit Pongee Industries Co., Ltd.

 

Pongee is an experienced automatic identification systems manufacturer in Taiwan. They have different type of high quality electric strike locks to meet various needs of clients. If you need more information about strike locks, welcome to check out their product pages and feel free to send inquiry to Pongee.

 

 

Article Source: KENNYSLOCK.COM

How to Increase the Process Speed of Die Sinking EDM

Developments in the EDM process and its technology along with improvements in accuracy, automation and micro-mold making technology can pay enormous dividends to the domestic mold making industry.

 

Speed Is Not the Solution

Increasing drive speed is one solution to improving the speed of die sinking EDM. In this way the unproductive times for lifting movements are reduced; however, the gain in speed is limited to small electrodes and very deep cavities. In addition, above a certain speed the electrode wear is considerable and very high axis speeds result in extreme strain on the mechanism, make the machine more expensive and shorten its working life. Therefore, it is wrong to believe that a general increase in the process speed is only to be achieved by rapid lifting movements. The contribution of fast axes to the machining process is just one supplementary aspect to a complex interaction that encompasses the generator, process control, gap width regulation and the mechanism. And die sinking EDM requires intelligent flushing.

 

Potential Lies in the Flushing

You can imagine the EDM process as being a balance between the EDMed and evacuated material in the gap. If this balance is not present, then either you flush the machining area unnecessarily—involving a loss of time and additional instability of the process—or you EDM the same particles several times, which cannot be removed from the gap sufficiently.

 

Die Sinking EDM

Before the material can be evacuated from the gap you must remove it from the workpiece. So how can you achieve more removal? As in the case of all optimization problems, the greatest gain potential lies where the efficiency is smallest. The efficiency of a single discharge with a cathodic poled workpiece is theoretically about 25 percent.1 In addition there are some factors that make the efficiency even worse (e.g., process control problems, non-ideal flushing conditions, small gap width), so that realistically you must reckon with an efficiency of less than 10 percent.

 

Removal and Surface Quality Determine the Time Requirement

In the case of EDM, the objective is always to optimize the removal performance of the machining on one hand, and to achieve the surface quality of the workpiece to be machined on the other hand. The workpiece, when machined, is intended to display a certain final roughness and a certain form precision. In addition, two conditions are called for:

 

  1. As small a thermally influenced area of the workpiece surface as possible
  2. As low an electrode wear as possible.

 

These marginal conditions determine the machining time and costs for workpiece production. In practice, a sequence of technological parameters is used because starting out from the roughing to finishing settings, the pulse energy is gradually reduced until the required technological results are achieved. Once again the law of nature applies: you can quickly achieve results of modest quality, but only slowly results in high quality.

 

Physical Processes Show a Solution

The approach toward an ideal state means moving the characteristic curve in the direction of the arrow. That means faster EDM with the same gap width, roughness and wear. If, up to now, the discharge energy of the EDM pulses was increased, regrettably you also only had greater roughness and a greater gap width so that the gains in speed during roughing were lost again through longer finishing. You will find a way to a solution if you return to the basics of EDM theory—to the physical processes leading to the formation of the spark and metal removal.

 

During the discharge, you can identify three main physical phases in succession:

 

  1. The Build-Up
  2. Discharge
  3. Fade Phases

 

In the first phase the discharge canal is built up. After passing through the working medium, the current flows almost exclusively on the surface area of the discharge canal and the anode is partially evaporated by the electron bombardment. The electrode wear mainly takes place here. Every pulse—whether contributing intensively to removal or not— causes microscopic wear. In the discharge phase, the electrical energy supplied causes melting or evaporation of material mainly on the workpiece. The fade phase begins with the switching off of the power supply. The plasma canal collapses and the partially evaporated, partially liquid material is ejected.

 

When to Interrupt Pulses

During the discharge, a crater forms in the workpiece. Fundamental studies of discharges have shown that the growth of the crater in the workpiece stagnates from a certain time. This is because a balance forms between the energy supplied and the energy lost, as well as energy that is used for the maintenance of the plasma and the heat loss to the workpiece and dielectric. This asymptote of the crater growth can be recorded in real time from the spark voltage and current.

 

However, why is the asymptote of the crater growth so important? Because this is the right moment to interrupt the pulse. It is unnecessary to let a pulse last longer if the target radius of the crater and the required roughness have been achieved. You can begin with the next pulse immediately. The time required by the pulse to reach this state also is not constant, as the speed with which a discharge reaches a certain spark base diameter depends on the macroscopic situation in the gap and the local geometry in the spark discharge area. With this first measure alone, you will optimize the number of discharges per unit of time and increase the removal rate.

 

When to Increase the Current

If you now observe the charge’s fade phase you will see that the removal from the workpiece is caused by the collapse of the plasma canal. The sudden drop in pressure—triggered by switching off the power—causes the evaporation and ejection of superheated material. The plasma canal has a very high temperature and pressure. The gradient of its collapse influences material removal. The more abruptly the energy disappears, the better the crater material will be ejected. In order to enhance this effect, a special trick is employed: before the pulse is interrupted, the current is increased briefly. The idea of increasing the pulse current is not new, the innovation is the definition of the point in time when this increase is to take place. The increase in the pulse current has no consequences for the roughness, wear or gap width, but does increase the removal. In addition, as the removal per pulse is greater, you need fewer pulses for the machining, and therefore the wear sinks.

 

Removal Rate Doubles in Part

This new machining strategy (asymptote detection, current increase and pulse interrupt) is the subject of a patent application for its use in new EDM die sinking systems. The results are in accordance with the theoretical reflections, especially where good flushing is guaranteed (e.g., pre-machined workpieces). For these machining jobs removal rates have doubled.

 

Generator Brings Striking Improvements in Performance

The innovative generator offers an increase in productivity of approximately 30 percent; however, up to 100 percent with pre-milled molds that occur increasingly nowadays through synergies with HSM. This refers to all roughing and finishing using copper and graphite electrodes. The advantages are particularly great with good flushing conditions and pre-milled workpieces. These convincing results explain that it is possible to increase the speed and productivity of die sinking EDM, and the potential for improving this technology is still considerable.

 

If you need more information about die sinking EDM, please try to visit the website of Excetek Technologies Co., Ltd. – the company is the well-known brand for its EDM machines. Get more details about Excetek, welcome to check out their product pages and feel free to send inquiry to them.

 

Article Source: MoldMaking Technology