KR100690585B1 - The apparatus of compare experience with explostion-proof construction - Google Patents

Abstract

An experiencing device of explosion-prevention comparison for education is provided to enable persons to experience an explosion by installing explosion-proof and non-explosion-proof equipment in a chamber comprising transparent acryl covers and exploding the explosion-proof and non-explosion-proof equipment by supplying gas at the intervals of 0.5~3 seconds. An experiencing device of explosion-prevention comparison for education is composed of an explosion-proof safety chamber(10) having a stainless lid(12) of a hinged structure(11) installed at both transparent acryl cases(13) and an explosion-proof structure(14) connected with one side of a gas supply pneumatic valve(30) and installed in the transparent acryl case; a non-explosion-proof safety chamber(20) having a stainless lid(22) of a hinged structure(21) installed at both transparent acryl cases(23) and a non-explosion-proof structure(24) connected with the side of the gas supply pneumatic valve and disposed in the transparent acryl case; the T-shaped pneumatic valve connected between the explosion-proof and non-explosion-proof safety chambers to emit the gas at the intervals of 5~3 seconds under the control of a control unit; an ignition coil unit(40) connected to the lower end of the explosion-proof and non-explosion-proof safety chambers to generate instant sparks under the control of the control unit; a solenoid valve installed at the lower end of the pneumatic valve to control the direction of supply gas under the control of the control unit; the control unit, that is a microcomputer, controlling the gas supply direction of the solenoid valve to successively supply gas the explosion-proof and non-explosion-proof safety chambers through a relay switch by receiving a signal of a start switch(70) and to generate the instant sparks at the ignition coil unit by the relay switch; the start switch formed at a panel to input a start signal for letting persons experience an explosion by causing an explosion in the explosion-proof and non-explosion-proof safety chambers; and a display unit(80) formed at the start switch to display the power supply state and the countdown in igniting and exploding.

Description

Explosion-proof experiential device for education {THE APPARATUS OF COMPARE EXPERIENCE WITH EXPLOSTION-PROOF CONSTRUCTION}

1 is a block diagram of the explosion-proof comparison experience device for education according to the present invention,

Figure 2 is an embodiment showing that the flameproof type (flameproof type) is formed inside the explosion-proof safety chamber 10 according to the present invention,

Figure 3 is an embodiment showing that a pressure explosion-proof structure (Pressureized type) is formed inside the explosion-proof safety chamber 10 according to the present invention,

Figure 4 is an embodiment showing that the oil immersed type (Oil immersed type) is formed inside the explosion-proof safety chamber 10 according to the present invention,

5 is an embodiment showing that an increased safety type (Increased safety type) is formed in the explosion-proof safety chamber 10 according to the present invention,

Figure 6 is an embodiment showing that the intrinsic safety explosion-proof structure (Intrinsic safety type) is formed inside the explosion-proof safety chamber 10 according to the present invention,

Figure 7 is an embodiment showing that the injection explosion-proof structure (Powder Filing) is formed inside the explosion-proof safety chamber 10 according to the present invention,

Figure 8 is an embodiment showing an explosion-proof comparison experience device for education according to the present invention,

9 is a circuit diagram of the explosion-proof comparison experience device for education according to the present invention,

10 is a flow chart of the explosion-proof comparison experience device for education according to the present invention.

<Brief description of the main parts of the drawings>

10: explosion proof safety chamber 20: non-explosion proof safety chamber

30: pneumatic valve 40: ignition coil portion

50: solenoid valve 60: control unit

70: start switch 80: display unit

The present invention is an explosion-proof safety chamber, non-explosion-proof safety chamber, pneumatic valve, ignition coil unit, solenoid valve, in order to prevent fire or explosion of electrical equipment generated in an oil refinery or gas refinery plant and industrial sites handling flammable materials It consists of a control unit, a start switch, and a display unit. By comparing explosion-proof electrical equipment with non-explosion-proof electrical equipment, a virtual explosion occurs, and the student learns about the explosion effect when sparks can occur in actual explosion-proof and non-explosion-proof equipment. The present invention relates to an experiential explosion-proof experience device for education that can prevent fire and explosion accidents in an industrial site by making the user visually experience and feel the importance of explosion-proof electric equipment.

In general, there is always the risk of explosions and fires in oil refineries, gas refineries and plants handling flammables.

Therefore, these hazardous areas are classified according to their risk status in international conventions such as the National Electric Code (NEC) or the International Electro-technical Committee (IEC).

As a representative example of this classification, the dangerous place is divided into three places.The place where the dangerous atmosphere is continuously generated or is likely to occur in the normal state is identified as the 0 species and the place where the dangerous atmosphere may occur in the normal place. There are two kinds of places, one place and a place where dangerous atmosphere can exist for a short time under abnormal conditions.

There are always risks of explosions and fires in the 0 and 1 of these hazardous areas, so electrical appliances (power cables, switches and switch boxes, connectors, etc.) used in these areas may have sparked or unsafe power connections. If this occurs, it will cause an explosion and fire, and electric appliances require a means to prevent them from being particularly exposed to explosion and fire.

Therefore, electrical appliances used in hazardous areas are usually defined to have an explosion-proof structure.

However, due to the lack of awareness of what explosion-proof structure is and why explosion-proofing of electrical equipment is important for the general public, it is true that there is an unreasonable caution that it can be installed as non-explosion-proof equipment where it should be installed. .

As a result, unknown fire and explosion accidents frequently occur in industrial sites such as oil refineries, gas refining plants, and plants handling flammable substances every year, and there is an urgent need for countermeasures to solve them.

The present invention devised to solve the problems described above is made of a transparent acrylic cover so that the general public can safely indirectly experience what is explosion-proof structure and how important explosion-proof of electrical equipment is inexpensive. It is an object of the present invention to provide an explosion-proof experiential exploration device for explosive education by installing explosion-proof equipment and non-explosion-proof equipment in a chamber, and supplying gas at a rate of 0.5 to 3 seconds.

Educational explosion-proof experience device for education according to the present invention to achieve the above object,

An explosion-proof safety chamber having a hinged stainless steel lid formed on both sides of a transparent acrylic case, and an explosion-proof structure connected to one side of a gas supply pneumatic valve inside the transparent acrylic case;

A non-explosion-proof safety chamber in which a hinged stainless steel lid is formed on a transparent acrylic case on both sides, and a non-explosion-proof structure connected to one side of a pneumatic valve for gas supply is formed in the transparent acrylic case;

A pneumatic valve connected between the explosion-proof safety chamber and the non-explosion-proof safety chamber and configured to have a “T” shape so as to discharge a gas amount at a period of 0.5 to 3 seconds through control of a controller;

An ignition coil unit connected to the lower end of the explosion-proof safety chamber and the non-explosion-proof safety chamber to generate an instant spark through control of a controller;

A solenoid valve installed at one side of a lower end of the “T” pneumatic valve and controlling a direction of a supply gas through control of a controller;

It consists of a microcomputer, and receives the signal of the start switch connected to one side to control the gas supply direction of the solenoid valve so that the gas is sequentially supplied to the explosion-proof safety chamber and the non-explosion-proof safety chamber through the relay switch, the relay switch connected to one side A control unit for controlling the instantaneous spark to be generated in the ignition coil unit installed at the lower end of the explosion-proof safety chamber and the non-explosion-proof safety chamber;

A start switch which is formed in the panel and causes an explosion in the explosion-proof safety chamber and the non-explosion-proof safety chamber for comparison,

It is achieved by being formed on one side of the start switch, which is composed of a display unit for displaying the presence or absence of power supply, the countdown during ignition and blasting.

Hereinafter, described in detail by the accompanying drawings as follows.

1 is related to the configuration of the explosion-proof experiential device for education according to the present invention, which is explosion-proof safety chamber 10, non-explosion-proof safety chamber 20, pneumatic valve 30, ignition coil unit 40, The solenoid valve 50, the control part 60, the start switch 70, and the display part 80 are comprised.

The explosion-proof safety chamber 10 is configured to form an explosion-proof structure 14 in an enclosed chamber to set fire / explosion conditions and explode safely in the chamber. The stainless steel lid 12 of the structure 11 is formed in the transparent acrylic case 13 on both sides, and the explosion-proof structure 14 connected to one side of the gas supply pneumatic valve 30 is formed in the transparent acrylic case 13. do.

Then, a gas amount control valve 15 for controlling the amount of gas supplied through the pneumatic valve 400 to one side of the acrylic case 13 is formed.

The stainless steel lid 12 is made of a hinge structure 11, there is a good effect that can be easily exhausted and ventilated in the chamber after ignition and explosion.

Explosion-proof structure 14 formed inside the explosion-proof safety chamber 10 is a flameproof type (flameproof type), pressure explosion-proof structure (Pressureized type), oil immersed type, increased explosion-proof structure (Increased safety type) It consists of Intrinsic safety type and Powder Filing.

Flameproof type (flameproof type) is a totally enclosed structure, the container withstands the pressure when the explosive gas or vapor exploded inside the container, and also to the external explosive gas through the joint surface, opening, etc. As a structure in which there is no fear of ignition, in the present invention, as shown in FIG.

Pressurized explosion-proof structure (Pressureized type) is a structure that prevents the ingress of explosive gas or vapor by injecting a protective gas (non-combustible gas such as fresh air or nitrogen) into the container to maintain the internal pressure as shown in FIG. Is formed.

Oil immersed type (Oil immersed type) is, as shown in Figure 4, the structure to prevent the ignition of the explosive gas or vapor present on the oil surface by putting a portion of the electrical equipment ignition, arc or high temperature in the oil surface Is formed.

Increased safety type (Increased safety type), as shown in Figure 5, to prevent the occurrence of arcs, explosions, etc. in the part that should not be high temperature, or electric flame arc that will be the ignition source to the explosive gas or steam during normal operation In order to achieve a mechanical and electrical structure or to increase the temperature, it is formed in a particularly safe structure.

Intrinsic safety type (Intrinsic safety type) is, as shown in Figure 6, that is not ignited by explosive gas or steam by electric flame, arc or high temperature generated during normal and accident (disconnected, short circuit, ground, etc.). It is formed into a structure confirmed by an ignition test.

As shown in FIG. 7, powder filing is mainly covered with a filling material such as quartz powder or glass particles to prevent ignition of the surrounding explosive atmosphere, mainly for electric equipment having a potential ignition source. It is formed into a structure.

The non-explosion-proof safety chamber 20 is configured to form a non-explosion-proof structure in a sealed chamber to explode safely in the chamber by setting the fire / explosion conditions, it is configured to be compared with the explosion-proof structure, which is a hinge structure 21 on the upper end Stainless steel lid 22 of the () is formed in the transparent acrylic case 23 on both sides, the non-explosion-proof structure 24 connected to one side of the pneumatic valve 30 for gas supply is formed in the transparent acrylic case 23.

A gas amount control valve 25 for controlling the gas amount supplied through the pneumatic valve 30 to one side of the acrylic case 23 is formed.

The non-explosion-proof structure 24 may be an ignition source in a normal operation state, the commutator of the DC motor, the winding type induction motor slip ring, the switch and the breaker contact, the heater of the high temperature portion, etc., has a non-explosion-proof structure.

The pneumatic valve 30 is to create an explosion atmosphere in the explosion-proof safety chamber 10 and the non-explosion-proof safety chamber 20, which is connected between the explosion-proof safety chamber 10 and the non-explosion-proof safety chamber 20 And it is formed in a "T" shape so as to release the gas amount in a cycle of 0.5 to 3 seconds through the control of the control unit 60.

The ignition coil unit 40 is connected to the lower end of the explosion-proof safety chamber 10 and the non-explosion-proof safety chamber 20 to generate the instant spark through the control of the control unit 60, which is shown in Figures 1 and 9 As shown, one side is connected to the lower end of the explosion-proof safety chamber, the lower end of the non-explosion-proof safety chamber, respectively, the other side is configured to be connected to the output terminal of the control unit through a relay switch.

In other words, by generating sparks in explosion-proof equipment and non-explosion-proof equipment in the same explosion atmosphere, the ignition coil part is configured to serve as an ignition source above the minimum ignition energy, which is one of the basic conditions of explosion, to compare which is safer. .

The solenoid valve 50 is installed on one side of the lower end of the "T" -shaped pneumatic valve 30 to control the direction of the supply gas through the control of the control unit 60, as shown in FIG. The gas is supplied to the explosion-proof safety chamber and the non-explosion-proof safety chamber at the same time by the control of the control unit 60 through a relay switch.

The control unit 60 is composed of a microcomputer, the solenoid valve 40 so that the gas is sequentially supplied to the explosion-proof safety chamber 10 and the non-explosion-proof safety chamber 20 through a relay switch by receiving a signal of the start switch connected to one side To control the gas supply direction and control the instantaneous spark in the ignition coil part 40 installed at the lower end of the explosion-proof safety chamber 10 and the non-explosion-proof safety chamber 20 through a relay switch connected to one side. This is, as shown in Figure 9, when the power is applied through a regulator in a 220V, 60Hz power supply unit is driven by a control unit consisting of a microcomputer.

The input terminal RA0 / AN0 is connected to the photo coupler PC187 to input the input signal of the start switch 70, and the output terminals RB0 / INT, RB1, RB2, RB3, and RB4 are connected to the TR Array (array) IC terminal. It is connected to display the discount on the LED display unit 80, the output terminal RB5 is connected to the TR Array (array) IC terminal to control the ON / OFF of the ignition coil unit 40 through Q1 and relay, and the output terminal RB6 is It is connected to the TR Array (array) IC terminal and configured to control ON / OFF of the solenoid valve 50 through Q2 and relay.

The start switch 70 is formed on a square panel located at the front of the discharge safety chamber 10 and the non-discharge safety chamber 20 to explode the explosion-proof safety chamber 10 and the non-explosion safety chamber 20. It is a place for inputting a start signal for comparison, which is composed of a push switch.

It is connected to one side of the input terminal of the control unit through the resistor R1 and the port coupler (PC187).

The display unit 80 is formed on one side of the start switch 70 to display the presence or absence of power supply, ignition, and countdown during blasting, and is made of an LED element. It is configured to be connected to one output terminal of the control unit through the TR array (IC) IC terminal.

As such, the explosion-proof safety chamber 10, the non-explosion-proof safety chamber 20, the pneumatic valve 30, the start switch 70, and the display unit 80 according to the present invention have a box shape, as shown in FIG. 8. Is formed in the upper portion of the display panel 100, the ignition coil portion 40, the solenoid valve 50, the control unit 60 is formed in the lower portion of the display panel 100 in accordance with the present invention.

In addition, the display panel 100 is configured to include a fire extinguisher to prevent fire during ignition and blasting.

Hereinafter, a detailed operation process of the explosion-proof comparison experience for education through the control of the control unit according to the present invention will be described.

First, the explosion-proof structure, flameproof type, pressure-proofed type, oil-immersed type, increased safety type, and intrinsically safe explosion-proof structure in explosion-proof safety chamber. Intrinsic safety type, Powder Filing, Encapsulation In the present invention, as shown in Figure is formed of a pressure-resistant explosion-proof elbow made of a pressure-resistant explosion-proof structure is configured to be connected to the pneumatic valve.

In the non-explosion-proof safety chamber, any one of non-explosion-proof structures, such as a commutator of a non-explosion-proof structure, a DC-type induction motor slip ring, a switch and a circuit breaker contact, and a heater of a high temperature part, is selected and configured. In the present invention, a non-explosion proof structure consisting of a switch and a breaker contact is formed and is connected to the pneumatic valve.

As shown in Fig. 10, the controller checks whether the start switch is pressed. At this time, when the input signal that the start switch is pressed is input to the input terminal of the control unit through the photo coupler (PC817), the output terminal of the control unit is a explosion-proof safety chamber and non-explosion-proof safety chamber at the interval of 1.5 seconds through the solenoid valve installed at the lower part of the pneumatic valve. To supply gas.

Subsequently, when gas is supplied to the explosion-proof safety chamber and the non-explosion-proof safety chamber, the control unit turns off the operation of the solenoid valve, and five LED display units are connected through a TR array IC terminal connected to one output terminal. 5, 4, 3, 2, 1 sequentially turns on and starts counting down.

Subsequently, when the countdown is completed, the ignition coil unit connected to one side of the output terminal operates to generate an instant spark in the gas in the explosion-proof safety chamber and the non-explosion-proof safety chamber to cause ignition and explosion.

The ignition of the ignition coil causes explosions in the explosion-proof safety chamber and the non-explosion-proof safety chamber. At this time, the explosion-proof elbow of the explosion-proof safety chamber does not explode and is composed of a switch and a breaker contact of the non-explosion-proof safety chamber. Explosions will occur in the width structure, allowing for comparative experiences.

Subsequently, after the explosion is completed, the stainless steel lids formed on the upper ends of the chambers are opened to vent and vent.

As described above, by using the educational explosion-proof comparison experience device according to the present invention, the public can safely indirectly experience how important it is to explosion-proof electric equipment even in a small space and a short time. The explosion rate of electrical facilities can reduce the rate of industrial accidents, so it can be a good effect to increase national industrial competitiveness by improving productivity by reducing the incidence of industrial accidents.

Claims (4)

The stainless steel lid 12 of the hinge structure 11 is formed on the transparent acrylic case 13 on both sides at the upper end, and the explosion-proof structure 14 connected to one side of the pneumatic valve 30 for gas supply inside the transparent acrylic case 13. Explosion-proof safety chamber 10 is formed; The stainless steel lid 22 of the hinge structure 21 is formed on the transparent acrylic case 23 on both sides at the upper end, and the non-explosion-proof structure connected to one side of the gas supply pneumatic valve 30 inside the transparent acrylic case 23 ( A non-explosion proof safety chamber (20) formed; A pneumatic valve (30) connected between the explosion-proof safety chamber (10) and the non-explosion-proof safety chamber (20) and configured to have a "T" shape so as to discharge a gas amount at a period of 0.5 to 3 seconds through the control of a controller; An ignition coil unit 40 connected to the lower end of the explosion-proof safety chamber 10 and the non-explosion-proof safety chamber 20 to generate an instant spark through control of a controller; A solenoid valve 50 installed at one side of a lower end of the “T” -shaped pneumatic valve to control a direction of a supply gas through a control of a controller; It consists of a microcomputer, and receives the signal of the start switch connected to one side to control the gas supply direction of the solenoid valve so that the gas is sequentially supplied to the explosion-proof safety chamber and the non-explosion-proof safety chamber through the relay switch, the relay switch connected to one side A control unit 60 for controlling the instantaneous spark to be generated in the ignition coil unit installed at the lower end of the explosion-proof safety chamber and the non-explosion-proof safety chamber; A start switch 70 formed in the panel and inputting a start signal for causing an explosion in the explosion-proof safety chamber and the non-explosion-proof safety chamber, and for a comparative experience; The explosion-proof comparison experience device for education, characterized in that formed on one side of the start switch consisting of a display unit 80 to display the power supply presence, ignition and countdown during blasting. The explosion-proof structure 14 is characterized in that the explosion-proof structure (Flameproof type), pressure-proof explosion-proof (Pressureized type), oil immersed type, increased safety type (Increased safety type), intrinsically safe explosion-proof Explosion-proof experiential device for education, characterized in that any one of the structure (Intrinsic safety type), the insertion explosion (Powder Filing) is selected. The non-explosion-proof structure (24) according to claim 1, wherein the non-explosion-proof structure (24) is formed by selecting one of a rectifier of a DC motor, a winding type induction motor slip ring, a switch and a circuit breaker contact, and a heater of a high temperature part which can be an ignition source in a normal operation state. Explosion-proof comparison experience device for education. The controller 60 of claim 1, wherein the controller 60 is driven through a regulator in a 220V, 60Hz power supply, and the input terminal RA0 / AN0 is connected to the photocoupler PC187 to provide an input signal of the start switch 70. Input, output terminal port RB0 / INT, RB1, RB2, RB3, RB4 are connected to TR Array (array) IC terminal to display discount on LED display unit 80, and output terminal port RB5 is TR Array (array) IC Connected to the terminal to control the ON / OFF of the ignition coil unit 40 through the transistor Q1 and the relay, and the output terminal port RB6 is connected to the TR Array (IC) terminal, the solenoid valve 50 through the transistor Q2 and the relay Educational explosion-proof experience apparatus, characterized in that configured to control the ON / OFF of the.

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