KR102623089B1 - EM Locking Apparatus for Preventing Confinement Accident by Using CdS sensor and Darkroom and Method thereof - Google Patents

Abstract

The EM electrostatic device of the present invention for preventing entrapment accidents using the CdS sensor and dark room effect is linked to a power supply unit that supplies power to the LED, CdS, and relay units, and an electromagnet, and operates to turn the contact point of the electromagnet on or off depending on whether or not it is excited. It is composed of a relay unit, an electromagnet that turns the electrical contact on or off depending on the ON or OFF of the relay unit, and a dark room in the electric well main body, and displays a status such as locking or unlocking the electric well, which receives power from the power supply and generates light. It consists of an LED, a CdS sensor that changes the resistance value as it receives the light generated by the LED, and turns the contact point of the relay unit on or off according to the change in resistance value, and a CdS sensor that determines whether or not the power supply is supplied. It is characterized by being composed of a controller that controls the opening and closing of the door by receiving the contact signal of the electromagnet.

Description

EM Locking Apparatus for Preventing Confinement Accident by Using CdS sensor and Darkroom and Method thereof}

The present invention relates to an EM electric well to prevent people from being trapped in a building or warehouse by combining an inexpensive and simplified circuit using a CdS sensor (illuminance sensor) and a relay with a status display LED included in the electric well.

The prior art related to the present invention is disclosed in Republic of Korea Patent No. 10-2174596 (announced on November 5, 2020). 1 is a block diagram of a conventional electric boat control device. In Figure 1, the conventional electric lock control device includes a power supply unit 110, a lock control unit 120, a switch 130, a charging unit 140, an opening/closing sensor 150, and a control unit 160. The power supply unit 110 applies power to the lock control unit 120 to perform a locking operation of the electric lock control device 100. The charging unit 140 is charged by power applied by the power supply unit 110. That is, the charging unit 140 is charged during the locking operation of the electric vehicle control device 100. The opening operation of the electric control device 100 may be implemented by the power charged in the charging unit 140. After the lock is locked by the electric lock control device 100, when the switch 130 is operated by the user, the power charged in the charging unit 140 is applied to the lock control unit 120, thereby opening the electric lock control device 100. This is done. The open/close sensor 150 detects the open/closed state of the lock. When the power supply unit 110 supplies power and the lock moves, the open/close sensor 150 detects the lock moving from the open position to the closed position. When the open/close sensor 150 detects that the lock is in the closed position, the power unit 110 stops supplying power. While the lock is detected to be in the closed position by the open/close sensor 150, the power supply unit 110 does not supply power to the lock control unit 120. When the switch 130 is operated by the user and the lock moves, the open/close sensor 150 detects the lock moving from the closed position to the open position. When the lock is detected to be in the open position by the opening/closing sensor 150, the lock control unit 120 fixes the lock in the open position for a predetermined time. After a predetermined time has elapsed, the power supply to the power unit 110 is resumed. The control unit 160 may determine whether the electric boat control device 100 is broken based on the sensing result of the open/close sensor 150. If it is determined that the electric boat control device 100 is in trouble, the control unit 160 may output different displays depending on the type of trouble. For example, if the opening/closing sensor 150 does not detect the closing of the lock even though power is supplied from the power unit 110 for more than a predetermined time, the control unit 160 determines that the electric lock control device 100 is malfunctioning (e.g. For example, it can be determined that the power supply is defective, the power supply is low on battery, etc.). Alternatively, if the opening/closing sensor 150 does not detect the opening of the lock even after a predetermined time has elapsed after the switch 130 is closed, the control unit 160 determines that the electric lock control device 100 is malfunctioning (e.g., charging unit failure). It can be judged that

The conventional electromagnet device configured as described above operates to lock the door by bringing the electromagnet part and the iron armature into close contact when an electric current flows through the electromagnet of the electromagnet device. When a weak current flows continuously, the electromagnet part operates to keep the door in a closed state. Therefore, adult men can open the door with strong force, but the elderly and infirm cannot open the door, so they may become trapped, which can lead to a serious accident in an emergency evacuation situation such as a fire. Therefore, the present invention is intended to allow the door to be opened even when a weak current due to external factors continues in the electric well release situation as described above.

The EM electrostatic device of the present invention for preventing trapped accidents using the CdS sensor and darkroom effect for the above purpose is linked to a power supply unit that supplies power to the LED, CdS, and relay unit, and an electromagnet, and the contact point of the electromagnet depending on whether or not it is excited. It is composed of a relay unit that operates to turn on and off, an electromagnet that turns the electrical contact on or off depending on the ON and OFF of the relay unit, and a dark room in the main body of the electric well, which displays status such as locking or unlocking the electric well and supplies power from the power source. An LED that receives light and generates light, and a CdS sensor that is configured in a dark room formed in the main body of the electric well and whose resistance value changes as it receives the light generated by the LED, and that turns the contact point of the relay unit on and off according to the change in resistance value, It is characterized by being composed of a controller that controls the power supply of the power unit and controls the opening and closing of the door by receiving the contact signal of the electromagnet.

The EM electric boat device of the present invention configured as described above to prevent trapped accidents using the CdS sensor and the darkroom effect, and the EM electric boat release method using the same, ensure that the electric boat continues to maintain visibility when abnormal low power is introduced due to a problem in the power supply unit. Entrapment accidents occur, and the present invention has the effect of preventing entrapment accidents by increasing the storage of the CdS sensor and turning off the contact point of the relay unit to release the electromagnet even in such cases. In addition, the present invention has the effect of reducing construction costs by using an inexpensive CdS sensor while using existing electric wells.

1 is a schematic diagram of a conventional electric boat control device;
Figure 2 is a configuration diagram of an EM electrostatic device for preventing entrapment accidents using the CdS sensor of the present invention and the dark room effect;
Figure 3 is a perspective view of the EM electrostatic device for preventing entrapment accidents using the CdS sensor of the present invention and the dark room effect;
Figure 4 is a control flowchart of the EM electric well release method for preventing entrapment accidents using the CdS sensor of the present invention and the dark room effect.

The CdS sensor of the present invention, which has the above-described purpose, the EM electric well device for preventing entrapment accidents using the darkroom effect, and the EM electric well release method using the same will be described based on FIGS. 2 to 4 as follows.

Figure 2 is a diagram showing the configuration of an EM electrostatic device for preventing entrapment accidents using the CdS sensor of the present invention and the dark room effect. In Figure 2, the EM (ElectroMagnetic) electromagnetic device for preventing entrapment accidents using the CdS sensor of the present invention and the dark room effect is linked to a power supply unit 10 that supplies power to the LED, CdS sensor, and relay unit, and an electromagnet to determine whether or not it is excited. It is composed of a relay unit 20 that operates to turn on and off the contact point of the electromagnet, an electromagnet 30 that turns the electrical contact point on and off according to the excitation of the relay unit, and a dark room of the electric well main body, such as locking or unlocking the electric well. It is composed of an LED (40) that receives power from the power supply to display the status and generates light, and a dark room formed in the main body of the electric well. As the light generated and emitted from the LED is received, the resistance value changes and according to the change in resistance value. It is characterized by being composed of a CdS sensor 50 that excites or de-energizes the relay unit, and a controller 60 that controls whether or not power is supplied to the power unit and controls the opening and closing of the door by receiving a contact signal from the electromagnet. In the case of the CdS sensor above, when light continues to be normally incident on the LED, the resistance value is lowered to excite the relay unit, and when the power unit is turned off but small power is input to the LED beyond the power unit, the LED generates a small amount of light. , when the small amount of light is incident on the CdS sensor, the resistance value of the CdS sensor increases, eliminating the excitation of the relay unit, turning off the interlocked electronic contact point, and controlling the controller to open the door. In addition, when a small power of about 20% of the standard EM electrostatic voltage (12V) with a tensile force of about 300 kg is continuously input, a magnetic force is generated that makes it very difficult for the elderly and infirm to open the door. In addition, generally, when using a DC relay, the relay unit is turned off only when the standard voltage drops below 10%, so when low power of about 20% is input as above, it is not possible to prevent trapping accidents by using the relay alone.

Figure 3 is a perspective view of the EM electrostatic device for preventing entrapment accidents using the CdS sensor of the present invention and the dark room effect. In FIG. 3, (a) is a diagram showing a state in which the protective cover for forming a dark room has been removed, and (b) is a state diagram in which the protective cover is fastened. The EM electrostatic device for preventing entrapment accidents using the CdS sensor of the present invention and the dark room effect is shown on a PCB. A power supply unit 10 that is mounted on the LED, CdS sensor, and supplies power to the relay unit, and a relay unit 20 that is mounted on the PCB and interlocks with the electromagnet and operates to turn the contact point of the electromagnet on or off depending on whether or not the electromagnet is excited. and an electromagnet 30, which is configured on one side of the electric boat main body and whose electrical contact points are turned on and off depending on the excitation of the relay unit, and a power supply unit which is mounted on a PCB configured in the dark room on the other side of the electric boat main body and displays a status such as locking or unlocking the electric boat. The LED (40), which receives power supply from and generates light, is mounted on a PCB configured in a dark room formed on the other side of the electric well main body, and the resistance value changes as it receives the light generated and radiated from the LED, and the relay relay according to the change in resistance value A CdS sensor 50 that excites or de-energizes the unit, a controller 60 mounted on the PCB that controls whether or not to supply power to the power unit and controls the opening and closing of the door by receiving a contact signal from the electromagnet, and the other side of the electric well main body. It is fastened to the front of the dark room formed in the PCB (70) on which the power supply unit, relay unit, LED, CdS sensor, and controller are mounted, and is fastened to one side of the protective cover to allow the light generated from the LED to flow into the CdS sensor. It is characterized by consisting of a light leak prevention stopper (80) and a protective cover (90) fastened to the rear of the electric well main body to form a dark room on the other side of the electric well main body.

Figure 4 is a control flowchart of the EM electric well release method for preventing entrapment accidents using the CdS sensor of the present invention and the dark room effect. In Figure 4 above, the EM electric lock release method to prevent trapped accidents using the CdS sensor and the dark room effect includes the step (S11) of the user turning off the power to the power source through the controller in order to open the door, and the abnormal power loss from the power source due to an abnormality in the power source. A step (S12) of maintaining the electric well in a visible state by inputting the input to the LED and the relay unit and exciting the relay unit, a step (S13) of emitting a small amount of light from the LED installed in the dark room formed in the electric well main body, and the dark room of the electric well main body. A step (S14) in which the installed CdS sensor absorbs a small amount of light emitted from the LED, a step (S15) in which the resistance of the CdS sensor increases and the excitation of the relay unit connected to the CdS sensor is eliminated, and the contact point of the electromagnet. It is characterized in that it includes a step (S16) in which the contact point of the electromagnet is turned off and a signal off is received by the controller, and a step (S17) in which the controller opens the door. As described above, even when the controller turns off the power supply, if a problem occurs in the power supply, the relay will be energized and the electric well will be in a locked state, which may cause an accident where the elderly or vulnerable are trapped. In this case, if a CdS sensor and a dark room are additionally configured, the power supply can be abnormal. Even when low power is continuously input, the electric well can be released and the door can be opened. In addition, in step S12, if the power supply is cut off without any abnormality, the electric well maintains the unlocked state and the door remains open.

10: power unit, 20: relay unit,
30: electromagnet, 40: LED,
50: CdS sensor, 60; controller,
70: PCB, 90: protective cover

Claims (11)

In the EM electrostatic device that uses CdS sensors and relays to prevent users from being trapped in a building or warehouse,
The EM electrostatic device using the CdS sensor and relay,
A power supply unit 10 that supplies power to the LED, CdS sensor, and relay unit;
A relay unit 20 that is linked to the electromagnet and operates to turn the contact point of the electromagnet on or off depending on whether or not the electromagnet is excited;
an electromagnet (30) whose electrical contact point is turned on or off depending on the excitation of the relay unit;
An LED (40) configured in the dark room of the electric well main body and generating light by receiving power from the power supply unit to display status such as visibility or unlocking of the electric well;
A CdS sensor 50 that is configured in a dark room formed in the main body of the electric well and whose resistance value changes as it receives light generated and radiated from the LED, and which excites or de-excites the relay unit according to the change in resistance value;
And a controller 60 that controls the power supply of the power unit and controls the opening and closing of the door by receiving a contact signal of the electromagnet. EM electrostatic device using a CdS sensor and a relay.
According to paragraph 1,
The electromagnet is,
An EM electric well device using a CdS sensor and relay, which is configured on one side of the electric well main body.
According to paragraph 1,
An EM electric device using a CdS sensor and relay, characterized in that the power supply unit, relay unit, LED, CdS sensor, and controller are configured on a PCB (70) mounted on the inner surface of the other side of the electric well main body.
According to paragraph 1,
An EM electric device using a CdS sensor and a relay, characterized in that the CdS sensor and LED can be configured in a dark room of the electric well main body.
According to paragraph 1,
In the LED,
An EM electrostatic device using a CdS sensor and a relay, characterized in that a light leakage prevention stopper (80) can be installed so that the generated light flows into the CdS sensor.
In the EM electrostatic device that uses CdS sensors and relays to prevent users from being trapped in a building or warehouse,
The EM electrostatic device using the CdS sensor and relay,
A power unit 10 mounted on the PCB that supplies power to the LED, CdS sensor, and relay unit;
A relay unit (20) mounted on the PCB and linked to the electromagnet, which operates to turn the contact point of the electromagnet on or off depending on whether or not the electromagnet is excited;
An electromagnet (30) configured on one side of the electric well main body and whose electrical contact points are turned on and off depending on the excitation of the relay unit;
An LED 40 that is mounted on a PCB configured in the dark room on the other side of the electric boat main body and generates light by receiving power from the power supply unit to display status such as visibility or unlocking of the electric boat;
A CdS sensor 50 that is mounted on a PCB configured in a dark room formed on the other side of the electric well main body and whose resistance value changes as it receives light generated and radiated from the LED to excite or de-energize the relay unit;
A controller 60 mounted on the PCB and controlling whether or not to supply power to the power supply unit and controlling the opening and closing of the door by receiving a contact signal from the electromagnet;
A PCB (70) fastened to the front of the dark room formed on the other side of the electric well main body and equipped with a power supply unit, relay unit, LED, CdS sensor, and controller;
A light leak prevention stopper (80) fastened to one side of the protective cover to allow light generated from the LED to flow into the CdS sensor;
And an EM electric boat device using a CdS sensor and a relay, characterized in that it consists of a protective cover (90) fastened to the rear of the electric boat main body to form a dark room on the other side of the electric boat main body.
According to clause 6,
The CdS sensor is,
When light is continuously incident on the LED normally, the resistance value is lowered to excite the relay unit, and when the power unit is turned off but small power is input to the LED beyond the power unit, the LED generates a small amount of light, and the small amount of light is An EM electrostatic device using a CdS sensor and a relay, characterized in that when incident on the CdS sensor, the resistance value of the CdS sensor increases and the excitation of the relay unit is eliminated.
According to clause 6,
The relay unit,
An EM electrostatic device using a CdS sensor and relay, characterized in that the relay is de-energized when the input voltage is 10% or less of the standard voltage.
In the EM electric lock release method to prevent users from being trapped in a building or warehouse using a CdS sensor and relay,
The EM electrostatic release method using the CdS sensor and relay is,
A step (S11) of the user turning off the power supply through the controller in order to open the door;
A step (S12) of inputting abnormally low power from the power supply unit to the LED and relay unit due to an abnormality in the power supply unit, thereby exciting the relay unit to maintain the electric well in a visible state;
A step (S13) of emitting a small amount of light from an LED installed in a dark room formed in the main body of the electric well;
A step (S14) in which a CdS sensor installed in the dark room of the electric well body absorbs a small amount of light emitted from the LED;
A step (S15) in which the resistance of the CdS sensor increases and the excitation of the relay unit connected to the CdS sensor is eliminated;
A step in which the contact point of the electromagnet is turned off and a contact point off signal of the electromagnet is received by the controller (S16);
And a method of unlocking an EM electric lock using a CdS sensor and relay, comprising a step (S17) of the controller opening the door.
According to clause 9,
The EM electrostatic release method using the CdS sensor and relay is,
EM electric well unlocking method using a CdS sensor and relay, characterized in that when the power supply is cut off without any abnormality in the power supply in step S12, the electric well maintains the unlocked state and the door remains open.
According to clause 9,
The step (S15) in which the resistance of the CdS sensor increases and the excitation of the relay unit connected to the CdS sensor is resolved,
An EM electrostatic release method using a CdS sensor and a relay, characterized in that excitation of the relay unit can be resolved when the input voltage of the relay unit is 10% or less of the standard voltage.