KR101091886B1 - Circuit for erasing exciter of electromagnetic lock - Google Patents

Abstract

The present invention relates to an exciter canceling circuit of an electromagnetic lock that can be prevented from malfunctioning of the lock by erasing the exciter remaining in the lock using the electromagnetic when the lock is released. The exciter canceling circuit of the electromagnetic lock according to the present invention includes an electromagnetic lock for generating an electromagnetic force by a driving power supplied from a power supply stage, and an electromagnetic lock for canceling an exciter generated in an armature coupled by the electromagnetic lock and the electromagnetic. Wherein the excitation canceling circuit of the excitation canceling circuit relays the driving power to the electromagnetic lock and charges the driving power therein so that the charged power is not supplied to the driving power. By providing the exciter canceling circuit of the electromagnetic locking device, the excitation circuit remaining in the components of the locking device can be erased by providing the excitation circuit of the electromagnetic locking device with a polarity to discharge the electromagnetic lock, thereby preventing the malfunction of the locking device. have.

Electromagnetic Lock

Description

Circuit excitation circuit of electromagnetic locks {Circuit for erasing exciter of electromagnetic lock}

The present invention relates to an exciter canceling circuit of an electromagnetic lock that can be prevented from malfunctioning of the lock by erasing the exciter remaining in the lock using the electromagnetic when the lock is released.

Currently, homes, shops, government agencies, and businesses are widely using access control systems to restrict unauthorized outsiders from entering.

Access control systems are used in many forms, ranging from simple, low-cost locks to expensive mechanical devices with complex mechanical mechanisms, and electronic devices that combine mechanical technology with electronic technology.

A simple lock realizes opening and closing of a door by mechanical matching of a key and a lock.

However, as the number of devices that require access control, such as a home, an office, a car, a computer, and a safe, increases in proportion to the number of keys to be carried, there is a disadvantage that it is difficult to carry many keys. In addition, there is a problem that it is not easy to find a key corresponding to a specific lock in the key package.

In order to improve the shortcomings of the simple lock, various electronic locks using a password input method through a key input unit, a magnetic card method coated with a magnetic stripe, an RF (Radio Frequency) card method, and an IC (Integrated Circuit) card method Digital door locks are widely used.

Such electronic locks are widely used to improve security functions of manual locks using keys and to provide users with more convenience.

In recent years, the range of the biometric lock device using the biometric information such as the user's fingerprint, iris, and voice is gradually spreading.

Such an electronic lock is basically unlocked by an external electric signal, and is automatically corrected when the door is closed. In addition, in case of a power failure, it should be kept open (or closed) automatically.

In particular, the doors installed at the entrances of branches, etc. should always be opened through the touch type automatic door switch so that they can evacuate quickly in case of an emergency such as a fire.

Hereinafter, an electromagnetic lock according to the related art will be described with reference to the accompanying drawings.

1 is a view for explaining an electromagnetic lock according to the prior art, Figure 2 is a view for explaining the electromagnetic lock of the electromagnetic lock shown in FIG.

The electromagnetic locking device according to the prior art is composed of an electromagnetic lock 10 and an armature 20 corresponding to the electromagnetic lock 10.

Here, the electromagnetic lock 10 is operated to open and close the door by energization or interruption of the driving power source.

As shown in FIG. 2, when the coil 12 is wound around the core 11 having an “E” shape and a driving power is applied to the coil, a current flows through the coil 12. 11) is formed of magnetism.

When the armature 20 formed of the iron component approaches the core 11, the arm 20 is locked, and if the driving power supplied to the coil 12 is cut off, the magnetism disappears and the armature 20 is removed from the core 11. Fall off and become unlocked.

In such a conventional electronic locking device, as the magnetic power is generated as the driving power is supplied to the core 11, the induction magnet is also generated in the armature 20 as time passes. At this time, if the driving power supplied to the electromagnetic lock 10 is cut off for the opening of the door, the magnetic force gradually disappears and the armature 20 falls.

However, even if the driving power supplied to the electromagnetic lock 10 was cut off, the door could not be unlocked due to the exciter and thus could not be opened.

In other words, even when the driving power is cut off, the door is short-circuited due to various excitation such as the residual current remaining in the coil 12 or the remaining magnetism remaining in the core 11 and / or the induction magnetism remaining in the armature 20. There was a problem that did not open.

In the worst case, the force was forced to open the door, but the elderly, such as women, children, or the elderly, could not or could not open the door easily.

At this time, if the door does not open in an emergency situation, such as a fire there is a problem that can lead to casualties.

On the other hand, in order to secure such a problem in the case that the drive power is cut off by attaching a separate leaf spring to the armature, there is also a method to force the armature to fall off the core by the leaf spring to make an unlocked state.

However, if a separate leaf spring is used, a problem arises in that the leaf spring is attached separately.

Accordingly, the present invention is to solve all the disadvantages and problems of the prior art as described above, the present invention is to enable the exciter remaining in the components of the locking device using the electromagnetic to be erased when unlocking the lock device to prevent the malfunction of the locking device It is an object of the present invention to provide an excitation canceling circuit of an electromagnetic lock that can be prevented.

The present invention for achieving the above object, an electromagnetic lock for generating an electromagnetic force by the drive power supplied from the power supply stage, and an electromagnetic lock for erasing the exciter generated in the amateur coupled to the electromagnetic lock and electromagnetic In the exciter canceling circuit of an apparatus, the exciter canceling circuit relays the driving power to the electromagnetic lock, charges the driving power therein, and if the driving power is not supplied, the charged power is connected with the driving power. An exciter canceling circuit of an electromagnetic lock is provided which is discharged to the electromagnetic lock with opposite polarity.

According to the present invention as described above has the following effects.

First, because the excitation of the excitation remaining in the components of the locking device is erased, there is an effect that can prevent a malfunction when unlocking the locking device.

Second, as it can prevent malfunctions, it is possible to improve the reliability of the electronic access device products and to minimize the damage to life in emergency situations such as fire.

Hereinafter, a preferred embodiment of an exciter canceling circuit of an electromagnetic lock according to the present invention will be described in detail with reference to the accompanying drawings.

In addition, the terminology used in the present invention was selected as a general term that is widely used at present, but in certain cases, the term is arbitrarily selected by the applicant, and in this case, since the meaning is described in detail in the corresponding part of the present invention, a simple term It is to be understood that the present invention is to be understood as a meaning of terms rather than names.

Further, in describing the embodiments, descriptions of technical contents which are well known in the technical field to which the present invention belongs and which are not directly related to the present invention will be omitted. This is to more clearly communicate without obscure the subject matter of the present invention by omitting unnecessary description.

3 to 4 are circuit diagrams illustrating the exciter canceling circuit of the electromagnetic lock according to the present invention, and FIGS. 5 to 6 illustrate polarity change in the core of the electromagnetic lock shown in FIGS. 3 to 4. It is for the drawing.

As shown in Figs. 3 to 6, the magnetic demagnetization circuit of the electromagnetic locking device according to the present invention is composed of an electromagnetic lock 100, an armature 200 and an exciter erasing circuit 300.

Here, the electromagnetic lock 100 generates an electromagnetic force by the driving power supplied from the power supply terminal.

The armature 200 is composed of iron material coupled by the electromagnetic force generated in the electromagnetic lock 100.

The exciter canceling circuit 300 switches the driving power supplied from the power supply terminal to the electromagnetic lock 100 between the power supply terminal and the electromagnetic lock 100, and charges the power supplied from the power supply terminal therein.

At this time, when the driving power is not supplied from the power supply stage, the electric power charged therein is discharged and switched to the electromagnetic lock 100 so that the exciter of the electromagnetic lock 100 and the armature 200 is erased.

The exciter erase circuit 300 of the electromagnetic lock according to the present invention includes an electromagnetic lock 100 and a power input terminal (+,-) of a driving power source (direct current) of an electromagnetic lock including an armature 200. It is comprised between 100.

The exciter canceling circuit 300 includes a relay 310, first to third diodes D1, D2, D3, a resistor R1, and an electrolytic capacitor C1.

The electromagnetic lock 100 forms an electromagnetic force as the magnetism is formed in the “E” core 110 as a current flows in the coil 120 according to the driving power, and forms a lock state with the armature 200 of the iron component. .

Here, the relay 310 is a switch, pin 1 (first relay pin), pin 7 (fifth relay pin) and pin 8 (seventh relay pin) are connected to the + power input terminal, pin 4 ( The second relay pin) and the tenth pin (sixth relay pin) are connected to the power input terminal, and the sixth pin (the third relay pin) and the nineth pin (the fourth relay pin) are respectively connected to the electromagnetic lock 100. It is connected to the coil 120 side, pin 5 (eighth relay pin) is connected to the-terminal of the electrolytic capacitor (C1).

In addition, the first diode D1 is configured between the + power input terminal (+) of the driving power supply and the first pin of the relay 310, the anode of the first diode D1 is connected to the + power input terminal, and the cathode It is connected to pin 1 of the relay 310.

On the other hand, the resistor R1 is connected at one side to the cathode of the first diode D1 and the other side is connected to the anode of the third diode D3. The cathode of the third diode D3 is connected to pins 7 and 8 of the relay 310.

The second diode D2 has a cathode connected to pin 10 of the relay 310 and a power input terminal, and an anode connected to pin 5 of the relay 310 and the terminal of the electrolytic capacitor C1.

In the electrolytic capacitor C1, the + terminal is connected to pin 8 of the relay 310, and the − terminal is connected to pin 5 of the relay 310.

For reference, when a DC power supply of 12 to 24 V is supplied from the power input terminal, the electrolytic capacitor C1 may be configured to correspond to 500 to 1500 µF.

In the exciter cancellation circuit of the electromagnetic lock of the present invention as described above, the first diode D1 prevents the reverse current from the relay 310 to the + power input terminal.

The third diode D3 prevents the reverse current from the pins 7 and 8 of the electrolytic capacitor C1 and the relay 310 charged in the electrolytic capacitor C1 to the + power input terminal.

On the other hand, the electrolytic capacitor C1 is charged by the power applied to pins 7 and 8 of the relay 310 by the third diode D3 when the power is supplied from the power input terminal, and driving power is not applied from the power input terminal. Otherwise, the charged power is discharged to the electromagnetic lock 100 side through the relay 310.

The resistor R1 is a power supplied to the electromagnetic lock 100 through pins 7 and 8 of the relay 310 and the power supplied to the pin 1 of the relay 310 among the power input from the power input terminal. It is configured for the supply time difference.

In more detail, first, when driving power for driving the electromagnetic lock 100 is applied from the power input terminals (+,-), + power is supplied to pin 1 of the relay 310, and − power is supplied to the relay 310. It is supplied to pin 4 of).

Accordingly, pins 6 and 9 of the relay 310 are switched to pins 7 and 10 of the relay 310 as shown in FIG. 3. Accordingly, the + power of the driving power of the power input terminal is applied to the coil 120 of the electromagnetic lock 100 through pins 7 and 6 of the relay 310.

At this time, the driving power is also applied to pin 8, which is a pin in the open state of the relay 310, is also supplied to the electrolytic capacitor C1, and the electrolytic capacitor C1 is charged with charge.

Referring to FIG. 5, as power is applied to the coil 120 of the electromagnetic lock 100, a magnetic (magnetic field) is formed in the core 110 while a current flows in the coil 120. At this time, according to the flow direction of the current in FIG. 5, the N pole is formed above the core 110, and the S pole is formed below the core 110 to generate an electromagnetic force.

When the armature 200 formed of the iron component approaches the core 110, the door is locked by the electromagnetic force generated by the core 110. At this time, the S pole magnetism is formed in the armature 200 of the surface in contact with the core 110.

On the other hand, of the power applied from the power input terminals (+,-), + power is supplied to pin 7 of the relay 310 through the resistor R1 and the third diode D3. At this time, the-input terminal of the power input terminal and the pin 5 of the relay 310 are disconnected by the second diode D2.

Subsequently, when driving power applied from the power input terminals (+,-) is cut off to open the door, driving power is not supplied to pins 1 and 4 of the relay 310. Therefore, pins 6 and 9 of the relay 310 are returned to their original states as shown in FIG. 4, so that pin 6 of the relay 310 is connected to pin 5, and pin 9 is connected to pin 8 do.

In this case, as shown in FIG. 4, pin 5 of the relay 310 is connected to the negative terminal of the electrolytic capacitor C1, and pin 8 is connected to the + terminal of the electrolytic capacitor C1. Power charged in the discharge is discharged to the coil 120 of the electromagnetic lock 100 through the pins 8 and 5 of the relay 310. That is, the power of the polarity-converted electrolytic capacitor C1 is supplied to the coil 120 of the electromagnetic lock 100.

Accordingly, as shown in FIG. 6, the power of the opposite polarity to the driving power is supplied from the capacitor C1 to the coil 120 of the electromagnetic lock 100. Therefore, it can be seen that the S pole magnetism is generated above the core 110 of the electromagnetic lock 100 and the N pole magnetism is generated below the core 110. That is, the polarity of the core 110 is reversed.

Then, as described above, since the polarity induced on the surface corresponding to the armature 200 surface on the contact surface of the core 110 was also the S pole, the polarity of the contact surface of the electromagnetic lock 100 and the armature 200 becomes the same.

As the discharge in the electrolytic capacitor C1 is completed, various exciters generated in the core 110 and the armature 200 disappear. Then, as the exciter of the core 110 or the armature 200 is extinguished, the electromagnetic lock 100 and the armature 200 are unlocked, and the door can be easily opened.

7 is a view for explaining an installation example of the electromagnetic lock according to the present invention, Figures 8 to 10 is a cross-sectional view for explaining various installation examples for the case of installing the electromagnetic lock shown in FIG. .

As shown in FIG. 7, the electromagnetic locking device of the present invention can be installed in the door frame 410 of the door 400. The door frame 410 has a plurality of hinges 420 coupled to the door 400 to support the door 400 to the door frame 410. In addition, the handle 400 is attached to the door 400.

At this time, the electromagnetic lock 100 may be installed on the door frame 410 side, the armature 200 may be installed on the door 400 side of the position corresponding to the electromagnetic lock 100.

When the electromagnetic lock 100 and the armature 200 are installed in the door, the armature 200 is coupled to the door 400 using the armature coupling member 210 as shown in FIG. 8, and the electromagnetic lock 100. Is coupled to the door frame 410 using the electromagnetic lock coupling member 110.

At this time, it is preferable that the armature coupling member 210 or the electromagnetic lock coupling member 110 use a suitable bracket according to the material of the door 400 and the door frame 410.

In other words, the door 400 may be made of wood, steel or glass, so that the door 400 may be joined after the fastening work (punching work, bonding work) suitable for each material, and in the case of the door frame 410, each material may be wood or steel. After joining to fit it is to combine.

9 and 10, the electromagnetic lock coupling member 110 is installed after installing a separate horizontal member 500 and an “L” shaped bracket 600 on the door frame 410 according to the side width of the door frame 410. The horizontal material 500 and the "L" shaped bracket 600 are shown, respectively.

Although the present invention has been described by way of example as described above, the present invention is not necessarily limited to these examples, and various modifications can be made without departing from the spirit of the present invention. Therefore, the examples disclosed in the present invention are not intended to limit the technical idea of the present invention but to explain the present invention, and the scope of the technical idea of the present invention is not limited by these examples. The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

1 is a view for explaining an electronic locking device according to the prior art,

2 is a view for explaining the electromagnetic lock of the electronic locking device shown in FIG.

3 to 4 are circuit diagrams for explaining the excitation canceling circuit of the electromagnetic locking device according to the present invention.

5 to 6 are views for explaining the polarity change in the core of the electromagnetic locking device shown in FIGS.

7 is a view for explaining an installation example of the electromagnetic lock according to the present invention;

8 to 10 are cross-sectional views illustrating various installation examples for the case where the electromagnetic locking device shown in FIG. 7 is installed in a door.

* Description of the symbols for the main parts of the drawings *

100: electromagnetic lock 110: electromagnetic lock bracket

200: amateur 210: amateur coupling member

300: exciter cancellation circuit 310: relay

410: door 420: hinge

430: handle 500: horizontal

600: L-shaped bracket

Claims (10)

The excitation of the electromagnetic lock device 100 to generate an electromagnetic force by the driving power supplied from the power supply stage, and the electromagnetic lock device for erasing the exciter generated in the armature 200 coupled by the electromagnetic lock 100 and the electromagnetic In the erasure circuit 300, The exciter erase circuit 300 relays the driving power to the electromagnetic lock 100 and charges the driving power therein so that the charged power has the opposite polarity as the driving power when the driving power is not supplied. Discharge to the electromagnetic lock (100), wherein the exciter canceling circuit (300) is configured between the power supply stage and the electromagnetic lock (100). delete The method of claim 1, The exciter erase circuit 300, A relay 310 for switching the driving power supplied from the power supply stage to the electromagnetic lock 100; And an electrolytic capacitor (C1) for charging the driving power. The method of claim 3, wherein The relay 310 is configured to be supplied with power inverted polarity when relaying the driving power supplied from the power supply stage and the power charged in the electrolytic capacitor C1 to the electromagnetic lock 100. Exciter cancellation circuit of electromagnetic lock. The method of claim 3, wherein The relay 310 is a first relay pin (pin 1) and a second relay pin (pin 4) to receive the +,-power from the driving power of the power supply stage to drive the relay 310, respectively, As the first relay pin (pin 1) and the second relay pin (pin 4) drive the driving power supplied from the power supply terminal or the driving power charged in the electrolytic capacitor C1 to the electromagnetic lock ( The third relay pin (No. 6 pin) and the fourth relay pin (No. 9) switching to 100), Fifth relay pin (No.7 pin) and Sixth relay pin (No.10 pin) for relaying the driving power of the power supply terminal to the third relay pin (No. 6 pin) and the fourth relay pin (No. 9 pin). , And A seventh relay pin (pin 8) and an eighth relay pin configured to relay the driving power charged in the electrolytic capacitor C1 to the third relay pin (pin 6) and the fourth relay pin (pin 9). Pin excitation circuit of the electromagnetic lock device, characterized in that it comprises a (pin 5). The method of claim 5, The exciter erase circuit 300, An anode is connected to the + power input terminal of the power supply terminal, and a cathode is connected to a first relay pin (No. 1 pin) of the relay 310 and a cathode of the first diode D1. A second diode (D2) having an anode connected to the fifth relay pin (pin 7) and a cathode connected to a seventh relay pin (pin 8), a-input terminal of the power supply terminal, and a pin 2 pin (pin 4) And a cathode connected to a sixth relay pin (pin 10), and an anode further connected to an eighth relay pin (pin 5) and a second diode D2 connected to the − terminal of the electrolytic capacitor C1. Exciter canceling circuit of an electromagnetic lock, characterized in that configured. The method of claim 6, The excitation canceling circuit of the electromagnetic lock device, characterized in that the resistor (R1) is further configured between the first diode (D1) and the third diode (D3). The method according to any one of claims 3 to 6, The + terminal of the electrolytic capacitor C1 is connected to the + terminal of the power input terminal and the seventh relay pin (No. 8 pin) of the relay 310, -Terminal of the electrolytic capacitor (C1) is an excitation canceling circuit of the electromagnetic lock device, characterized in that connected to the eighth relay pin (pin 5). The method of claim 5, The relay 310 is the first relay pin (pin 1) and the second relay pin (pin 4) is the third relay pin (pin 6) and when the driving power is applied from the power supply terminal and A fourth relay pin (pin 9) is driven to be connected to the fifth relay pin (pin 7) and the 6 relay pin (pin 9), respectively. When the driving power is not applied from the power supply terminal, the third relay pin (No. 6 pin) and the fourth relay pin (No. 9 pin) are the seventh relay pin (No. 8 pin) and the eighth relay pin (No. 9). And an excitation canceling circuit of an electromagnetic lock device, characterized in that it is configured to return to be connected with the pin). The method of claim 1, The electromagnetic lock (100) is an excitation canceling circuit of the electromagnetic lock device, characterized in that consisting of the "E" core (120) and the coil (110).

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