KR101764848B1 - Smart pressure reduction device through real-time status sensing electric transformer - Google Patents

Abstract

The purpose of the present invention is to provide a smart-type pressure reduction device using a real-time transformer state sensing application module. According to a conventional pressure reduction device, once pressure is discharged by instant high pressure, the device is damaged and cannot be reused. Thus, the device should be replaced. Damage and replacement periods should be confirmed by a naked eye, and the device should be frequently inspected. Therefore, manpower and time are wasted, and a large quantity of maintenance costs are consumed. Also, a defection in a transformer should be confirmed by a naked eye to be repaired, and an explosion period is difficult to be grasped through the outer appearance thereof. Then, an operator is exposed to a dangerous situation. To this end, the smart-type pressure reduction device of the present invention comprises: an instant pressure reduction device unit; a smart transceiving module; and a pressure reduction device application module. When internal pressure of a transformer rapidly increases due to a gas generated when a temperature of insulation oil increases due to a defection such as an interlayer shortage, overload, or partial discharge in the transformer, the gas is discharged to the outside. Thus, the body of the transformer is prevented from being damaged, and the pressure reduction device can be repeatedly used. Accordingly, maintenance costs are saved. Also, a state of a large quantity of transformers is monitored in real time, and a defection is grasped. Thus, a time for preventing a transformer accident can be ensured, and an operator is prevented from being exposed to a danger. Also, an operation environment of an operator can be improved.

Description

[0001] SMART PRESSURE REDUCTION DEVICE THROUGH REAL-TIME STATUS SENSING ELECTRIC TRANSFORMER [0002] FIELD OF THE INVENTION [0003]

In the present invention, temperature, humidity, and pressure inside each transformer are checked in real time through an instantaneous pressure reducing device installed at the upper end of each transformer, and the abnormal state of the transformer is transmitted to the manager in real time to prevent a transformer explosion accident , Due to rapid temperature rise due to the transformer failure, the gas generated inside is discharged to the outside to prevent the transformer body from being damaged by the explosion or fire due to the high pressure, and the life of the transformer due to explosion accident, To a smart pressure control device through a real-time transformer state detection application module that can prevent a secondary damage of the smart pressure control device.

Generally, a transformer that changes the value of AC voltage or current by using electromagnetic induction phenomenon has insulation function and incorporates insulating oil which performs cooling function.

However, if an overcurrent or a short-circuit current occurs due to an overload in the transformer, the temperature of the transformer winding rises sharply or the insulation oil is decomposed by the electric energy due to arc discharge, .

In this case, if the gas generated inside can not be discharged instantaneously, the pressure inside the transformer rapidly rises and the transformer body will explode, causing not only damage to the transformer itself, but also damage to the surrounding people, damage to the fire, There was a serious problem of secondary property damage.

In order to prevent this, a pressure reducing device has been developed and used to reduce the pressure by instantaneously discharging a high-pressure gas at the upper end in order to relieve the internal pressure of the transformer which rises abruptly due to the gas generated by the abnormality of the transformer.

However, the conventional pressure reducing device is required to replace the pressure reducing device once the pressure is released due to the momentary high pressure and the device is damaged and can not be reused. It is necessary to check the replacement time visually for the breakage or the replacement time. Waste, and maintenance and repair costs.

In addition, it is difficult to visually check whether the transformer is abnormal or not, and whether the operation of the pressure reducing device can be visually confirmed. Thus, the operator is exposed to a dangerous blind spot in the process of retransmitting the transformer.

In order to solve the above problems, according to the present invention, when the temperature of the insulating oil rises due to a failure such as an inter-layer short circuit, an overload or a partial discharge inside the transformer, It is possible to prevent the breakage of the main body, reduce the maintenance cost by enabling the use of the pressure reducing device repeatedly instead of one time, and monitor the state of a large number of transformers in real time to prevent the transformer accident And to provide a smart type pressure control device through a real-time transformer state detection application module which can prevent a worker from being exposed to a risk and improve a work environment of a worker.

In order to achieve the above object, a smart pressure control device through a real-time transformer state detection application module according to the present invention includes:

It is installed on the upper surface of the transformer, the insulation oil is decomposed by the internal fault of the transformer, and the generated high temperature gas is instantaneously opened according to the pressure inside the transformer so that the high pressure gas is discharged, Wow,

A smart transmission / reception module installed near a transformer provided with an instantaneous pressure reducing device unit and transmitting / receiving real-time information sensed by the instantaneous pressure reducing device to a smartphone,

And an application module connected to the smart transmission / reception module through a 3G or WIFI network and an optical communication network and displaying a plurality of transformer information on the screen in real time through a portable smart device of the manager.

As described above, when the internal pressure of the transformer rises suddenly due to the gas generated by the rise of the temperature of the insulating oil due to a failure such as an interlayer short circuit, an overload or a partial discharge in the transformer, the gas is instantly opened to the outside and discharged By preventing the transformer main body from being broken by sealing, it prevents infiltration of outside air and moisture, and it is possible to use the pressure reducing device repeatedly instead of one time, thereby reducing the maintenance and repairing cost and monitoring a large amount of transformer state in real time It is possible to obtain a time for preventing an accident of a transformer by detecting an abnormality, prevent a worker from being exposed to a risk, and improve a work environment of a worker.

1 is a block diagram showing the overall configuration of a smart pressure control device through a real-time transformer state detection application module according to the present invention;
2 is a perspective view showing the overall shape of the instantaneous pressure reducing apparatus according to the present invention,
FIG. 3 is an exploded perspective view of the instantaneous pressure reducing apparatus according to the present invention,
4 is a side cross-sectional view of the instantaneous pressure relief device provided at the upper end of the transformer according to the present invention,
FIG. 5 is a side cross-sectional view of the instantaneous pressure reducing device installed on the upper end of the transformer according to the present invention. The elastic spring of the instantaneous pressure reducing device is compressed by the gas generated inside the transformer, FIG. 5 is a side cross-sectional view showing the gas moving path in which the gas inside is discharged to the outside,
6 is a diagram showing a state in which the gas inside the transformer is discharged to the outside through the instantaneous pressure reducing device installed on the upper end of the transformer according to the present invention,
FIG. 7 is a block diagram showing the overall configuration of a smart transmission / reception module according to the present invention.
FIG. 8 is a diagram showing a state where a real-time transformer temperature, humidity, and internal pressure status are displayed on a display module of a smart transceiver module according to the present invention,
FIG. 9 is a diagram illustrating an example of setting a set allowable temperature in the display module of the smart transceiver module according to the present invention,
FIG. 10 is a graph showing the relationship between the real-time humidity status and the average humidity trends by date, with the setting allowable humidity set in the display module of the smart transceiver module according to the present invention,
FIG. 11 is a graph showing the relationship between the real-time internal pressure status and the average pressure trend by date in the display module of the smart transceiver module according to the present invention,
12 is a block diagram showing components of the pressure-resistant device application module according to the present invention;
13 is a diagram showing a state in which a real-time transformer map of the pressure-resistant device application module according to the present invention is executed in a manager's smart device,
FIG. 14 is a diagram showing a state in which the real-time transformer status of the pressure application device application module according to the present invention is executed in a smart device of an administrator; FIG.

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram showing a general configuration of a smart pressure control device through a real-time transformer state detection application module according to the present invention. This block diagram illustrates an instantaneous pressure reducing device 100, a smart transceiver module 200, And an application module 300.

First, the instantaneous pressure reducing apparatus 100 according to the present invention will be described.

The instantaneous pressure reducing apparatus 100 is installed on the top surface of the transformer, and the insulating oil is decomposed due to an internal failure of the transformer. The generated high temperature gas is instantaneously opened according to the pressure inside the transformer, The upper cover 110, the elastic spring 120, the pressure reducing frame 130, and the lower end body 140. The upper end of the upper cover 110,

The upper cover 110 is formed in an upright cylindrical shape and has a circular step protruded at the center of the upper end surface, and forms the upper end of the instantaneous pressure reducing apparatus, and protects and supports the device from external pressure.

This comprises a stent-doping insertion hole 111, a non-penetrating stent dope 112, and an upper spring supporting groove 113.

The stent-doping insertion holes 111 are formed to penetrate vertically so as to insert the fixing bolts at regular intervals of 120 ° with respect to the center of the top surface.

The non-penetrating stent dope 112 is inserted in the upper end to the lower end of the stent-doping insertion hole formed at an interval of 120 °, and protrudes in the vertical direction at the lower end, and separates the gap between the upper cover and the lower end body .

The threaded bolts formed on the lower end face and the fixing bolts on the lower end body are vertically aligned and bolted to the threaded bolt to be spaced apart from the lower end of the upper end by a protruding height and coupled to the upper end of the lower end body.

The upper spring support groove 113 has a step protruding in the upper direction inside the middle of the lower end surface to support the upper end of the elastic spring.

This prevents the upper end of the elastic spring from being detached in the outward direction.

The upper end of the elastic spring is distorted in the lateral side direction by the impact applied suddenly to the elastic spring to prevent the pressure reducing frame abutting against the elastic spring from being lost by the function of opening and closing by the internal pressure.

The upper end of the resilient spring 120 is vertically mounted on the lower end of the upper cover. The upper end of the resilient spring 120 is in close contact with the upper end of the upper spring, The lower end is closely attached to the support groove.

The repulsive force of the elastic spring according to the present invention is 3 to 5 kgf / cm 2.

The reason why the repulsive force of the elastic spring is selected between 3 and 5 kgf / cm 2 is that when the reaction force is 3 kgf / cm 2 or less, the elastic spring is contracted by the repulsive force even when the pressure inside the transformer is normal, There is a problem that foreign substances such as moisture and moisture or dust are opened from the outside or completely sealed off from the outside and leakage of rainwater may occur. When the repulsive force is 5 kgf / cm 2 or more, Even if the internal pressure is increased beyond the permissible pressure, the elastic spring is not properly contracted due to the repulsive force, so that it is difficult to smoothly discharge the gas, thereby failing to efficiently discharge the gas of high pressure. There is a problem that follows.

In addition, the elastic spring 120 according to the present invention

A stainless steel elastic spring having a chemical composition of 18.87 wt% of Cr, 9.23 wt% of Ni, 1.70 wt% of Mn, 0.842 wt% of Si, 0.718 wt% of Nb, 0.0647 wt% of C, 0.0290 wt% of P, Ti and Cr; Or composite deposition of Ti and Al by electron beam evaporation (EB-PVD)

The composite deposition, sputtering (sputter) for 10-20 minutes was added in the degree of vacuum, -450V, 160mA conditions of the Ar gas 4 × 10 ^-2 torr to remove the oxide films of stainless steel, the degree of vacuum of 10 ^-6 torr or more conditions Lt; / RTI >

After the sputtering, the temperature of the stainless steel elastic spring was raised to 280 to 350 ° C. by a halogen lamp of 450 to 550 W so that a vacuum condition of 10 ^-6 torr or more was obtained. Ti, Al bulk and 99.99% Cr powder with a purity of 99.99% are separately put into a tungsten filament, and a voltage and an electric current are applied to the tungsten filament to sequentially perform Ti deposition and Cr deposition, or Ti deposition and Al deposition, The voltage is set to 3.0 to 5.0 kV, the current is 220 to 300 mA in the case of Ti, 180 to 250 mA in the case of Al, and 230 to 280 mA in the case of Cr, followed by deposition for 20 to 40 minutes.

Stainless steel has excellent corrosion resistance and mechanical properties and is used in various industrial equipment including petrochemical plants, reactors, aircraft, kitchen equipment, building materials and machine parts.

However, stainless steel is corroded in certain environments and conditions of use. Factors affecting the rate of corrosion are known as pH, chloride, sulfide and temperature. Degradation corrosion caused by corrosion and corrosion fatigue in prolonged exposure to various corrosive environments will cause unexpected damage and destruction.

In the present invention, since the elastic force is strong, the elasticity is little changed, and the material is made of a material having high corrosion resistance,

A stainless steel having a chemical composition of 18.87 wt% of Cr, 9.23 wt% of Ni, 1.70 wt% of Mn, 0.842 wt% of Si, 0.718 wt% of Nb, 0.0647 wt% of C, 0.0290 wt% of P, , Cr and Al by electron beam evaporation, and more specifically, composite deposition in which Ti and Cr are sequentially deposited; Ti and Al are successively deposited.

The composite deposition is performed by an EB-PVD method using electron beam deposition (EB-PVD) equipment.

The EB-PVD equipment includes a copper crucible for containing tungsten filament and an evaporant for generating electrons, a substrate for fixing the specimen, an oil pump for vacuum operation, A diffusion pump, a heater for heating the substrate by a halogen lamp, and the like.

Vacuum deposition using electron beam (EB) is a type of PVD method in which evaporation material is evaporated by heat generated by colliding hot electrons emitted from tungsten filament with evaporation source at high voltage to form a deposition layer on a target object.

Ti, Al, and Cr used as the corrosion-resistant material are metals having excellent corrosion resistance, and corrosion resistance is imparted by forming films such as Al, Ti, AlCr, and Alti.

In the composite deposition process, the current of the aluminum is lowered because, when a high current is applied, the material in the pot is melted by the electron beam and small particles are splashed out of the crucible and disturbed in the deposition process.

The pressure reducing frame 130 is disposed between the upper cover and the lower body and has a groove formed at the center in the lower direction to define a lower spring support groove for supporting the lower end of the elastic spring to support the lower end of the impact absorption spring And acts to rise and fall according to the pressure inside the transformer.

Which is supported on the upper circular step 141 of the lower body along the side of the lower side face, and the central lower side face is exposed inside the transformer and is opened / closed in accordance with the amount of pressure change inside the transformer to control the pressure.

In this case, when the pressure applied to the lower end surface of the pressure reduction frame becomes higher than the repulsive force of the elastic spring due to the pressure elevated by the expansion due to the gas generation inside the transformer, the pressure reduction frame rises and the elastic spring contracts in the upper direction, The inner gas is discharged to the outside. When the pressure applied to the lower end surface of the pressure reduction frame due to the discharged gas becomes lower than the repulsive force of the elastic spring, the pressure reducing frame descends and the elastic spring is tension- And the inside of the transformer is sealed.

When the internal pressure of the transformer is increased, the internal pressure is lowered to the allowable pressure to prevent the explosion due to the internal expansion. When the transformer is in normal operation, the inside of the transformer is sealed so that moisture, moisture, And prevents leakage of rainwater to prevent abnormalities in the transformer.

The lower end body 140 has a cylindrical shape and a circular step formed along the upper inner side surface thereof around the outer lower end of the shock absorbing frame, and a coupling hole for fixing the transformer coupling bolt is protruded outward, It plays a fixed role.

This is constituted by the upper circular step 141, the detection sensor part 142, the fixing bolt 143, the coupling hole 144, and the pressure-proof device coupling bolt 145.

The upper circular step 141 protrudes in the upper direction along the inner surface of the upper end in a cylindrical shape to support the outer lower end of the shock absorbing frame.

The sensing part 142 is inserted and fixed in the sensor insertion groove on one side of the upper side of the upper circular step, the outer side is formed to face the side of the shock absorption frame located at the upper side, and the inner side is exposed to the inside of the transformer And transmits information such as temperature, humidity, pressure, etc. inside the measured transformer to the smart transmission / reception module 200 through the near field wireless communication module.

This is because a motion sensing sensor is formed in the outward direction to detect upward and downward movement of the pressure reduction frame 130, and temperature, humidity, and pressure sensors are formed in the inner direction, Sensing the pressure and delivering the measured information to the smart transmitter module.

Here, when the pressure reduction frame is supported at the upper circular step 141, the motion sensing sensor is brought into close contact with the inner surface formed along the lower side edge of the pressure reduction frame as shown in FIG. 4, When the pressure reduction frame is raised by the pressure inside the transformer, the motion detection signal is separated from the pressure reduction frame as shown in FIG. 5, and the motion detection signal is transmitted to the smart transmission / reception module.

By detecting the upward and downward movement of the pressure reducing frame of the instantaneous pressure reducing device, it is detected whether gas is generated in the transformer, and the gas is transmitted to the smart transmission / reception module, and the alarm notification message is transmitted to the manager through the pressure application device application module .

Here, the temperature / humidity pressure sensor is positioned to face the inside of the transformer as shown in FIG. 4 and exposed to the inner side of the upper end of the transformer to transmit sensed signals of temperature, humidity and pressure inside the transformer to the smart transmission / do.

It detects real-time temperature, humidity, and pressure information inside the transformer and transmits it to the smart transceiver module and transmits it to the administrator through the pressure application device application module.

At this time, when the detected internal temperature of the real-time transformer rises above the set allowable temperature, a red frame light indicating that the allowable temperature is exceeded is lighted in the smart transceiver module as shown in Fig. 8, The notification manager is activated.

At this time, when the detected humidity of the real-time transformer rises above the set allowable humidity, a blue frame light indicating that the allowable humidity is exceeded is lighted in the smart transceiver module as shown in Fig. 8, The notification manager is activated.

At this time, if the detected internal pressure of the real-time transformer rises above the set allowable pressure, a green frame light indicating that the allowable pressure exceeds the allowable pressure is turned on in the smart transceiver module as shown in Fig. 8, The manager is running.

This enables the manager to check the information inside the transformer in real time and to grasp the condition inside of the transformer in real time so as to secure the safety of the operator and to identify the problem inside the transformer and to repair and maintain it easily.

The fixing bolts 143 are formed at regular intervals of 120 ° with respect to the center on the outer upper end surface, and are positioned so as to be vertically aligned with the non-penetrating stent dope of the upper cover.

This is bolted to the lower end of the non-penetrating stent dope of the top cover to separate the top cover and the bottom body by the lower height not inserted with the bolt, thereby forming a spacing space in which the pressure reduction frame formed between the upper and lower covers can move upward and downward .

The coupling hole 144 protrudes outward at a constant interval of 120 ° with respect to the center along the lower end to insert and fix the transformer coupling bolt.

The pressure-tightening device coupling bolt 145 is inserted in a vertical direction when the coupling hole of the lower-end body and the upper-end coupling hole of the transformer are aligned in the vertical direction, thereby fixing the instantaneous pressure reducing device tightly to the upper end of the transformer.

Next, the smart transmission / reception module 200 according to the present invention will be described.

The smart transmission / reception module 200 is installed near the transformer provided with the instantaneous pressure reduction device, and transmits and receives the real time information sensed by the instantaneous pressure reduction device to the smartphone. A display module 220, and a remote wireless communication module 230.

The short range wireless communication module 210 is connected to a short range wireless communication network based on a motion detection sensor and Bluetooth, which are fixed to one side of the instantaneous pressure reduction device, and receives the temperature, humidity, pressure, It plays a role.

The display module 220 provides the real-time information of the instantaneous pressure reducing device, which is transmitted to the near-field wireless communication module, as a screen.

The display module 220 according to the present invention confirms the temperature, humidity, and pressure information in the transformer in real time in a touch screen manner, sets an allowable temperature which is an upper temperature limit for operating the temperature notification manager, The upper limit of humidity, the allowable humidity, is set, and the pressure upper limit for operating the pressure notification manager is set to the allowable pressure.

If the real-time temperature rises above the allowable temperature set in the Smart Transmitter / Receiver module, the allowable temperature exceeding notification message is transmitted to the smart device of the administrator installed with the pressure application device module via the remote wireless communication module.

Also, touching the temperature information, you can check the real time temperature status of the transformer and the transformer temperature change trend by date in a graphical manner.

Through this, it is possible to visually check temperature change by time and date easily, and it is possible to check whether the temperature of the transformer is increased, thereby preventing a failure due to a rise in temperature.

If the real-time humidity rises above the set allowable humidity set in the Smart Transmitter / Receiver module, the allowable temperature override notification message is transmitted to the smart device of the administrator installed with the pressure application device module via the remote wireless communication module.

Also, if you touch the humidity information, you can check the real time humidity status of the transformer and the trend of the humidity change of transformer by date.

Through this, it is possible to visually confirm the change of humidity by time and date easily, and it is possible to check whether the humidity of the transformer is increased, thereby preventing the failure due to the increase of humidity.

If the real-time pressure rises above the set allowable pressure set in the Smart Transmitter / Receiver module, the over-pressure notification message is sent to the smart device of the manager installed with the pressure application device module via the remote wireless communication module.

Also, if you touch the pressure information, you can check the real time pressure status of the transformer and the trend of the transformer pressure change by date.

Through this, it is possible to visually confirm the change of pressure by time and date easily, and it is possible to check whether the pressure of the transformer is increased, thereby preventing the failure due to the pressure increase.

The remote wireless communication module 230 transmits / receives the temperature, humidity, pressure, and shock absorption frame inside / outside the transformer in real time to the smart device of the manager through the 3G or Wifi network and optical communication network.

Next, the pressure-proofing device application module 300 according to the present invention will be described.

The pressure application device application module 300 is connected to the smart transmission / reception module through a 3G or Wifi network and an optical communication network, and displays a plurality of transformer information on the screen in real time through a portable smart device of an administrator. A temperature event setting unit 340, a humidity event setting unit 350, a pressure event setting unit 360, and a smart control unit 370. The TSP activity unit 320, the intent unit 330, the temperature event setting unit 340, do.

The map activity unit 310 generates each instantaneous pressure reduction device unit installed on the upper end of the plurality of transformers on a map by position.

This makes it possible to set the transformer in the management area of the manager and display the location of each transformer on the map so that the position can be easily grasped.

The TSP activity unit 320 includes a real time transformer internal temperature T, a transformer internal humidity S, and a transformer internal pressure P, which are views and event responses of the instantaneous pressure reducing apparatus selected on the map, Interface on the smart device screen, respectively.

Through this, the internal information of the selected transformer among the transformers in each management area can be selectively checked, and the inspection for maintenance and repair can be confirmed by real-time monitoring, thereby minimizing the inconvenience of the operator and effectively managing the transformer in the area.

The intent unit 330 sends a request command to an event setting unit to perform an event when an administrator's interface is moved to another screen according to an administrator's touch on the displayed screen and the screen is switched.

And controls the selected screen through the pressure application application module and transmits the control information according to screen switching to the smart control unit.

The temperature event setting unit 340 sets an allowable temperature when the temperature measurement screen is selected, displays the internal temperature of the real time transformer, and calculates and stores an average value classified by date and time.

The humidity event setting unit 350 sets the allowable humidity when the humidity measurement screen is selected, displays the humidity inside the real time transformer, and calculates and stores the average value classified by date and time.

The pressure event setting unit 360 sets an allowable pressure when the pressure measurement screen is selected, expresses the internal pressure of the real time transformer, and calculates and stores an average value classified by date and time.

When the received temperature information exceeds the set allowable value, the smart control unit 370 turns off the temperature display frame in red. If the humidity information exceeds the set allowable value, the humidity display frame is turned off in blue, If the set allowable value is exceeded, the pressure display frame is turned off green, and if any of the temperature, humidity, and pressure information exceeds the allowable value, it activates the notification manager in real time.

Hereinafter, a specific operation of the smart pressure control device through the real-time transformer state detection application module according to the present invention will be described.

First, the pressure reduction frame is inserted into the upper circular step of the upper end of the lower body,

A pressure reduction frame, an elastic spring and an upper cover are sequentially arranged on the upper end of the lower body.

Next, the positions of the non-penetrating stent dope of the lower body fixing bolt and the upper cover are vertically aligned and then bolted together.

At this time, the spring is positioned upright in the upper end spring supporting groove of the upper cover and the inner groove of the pressure reducing frame, and a space is formed between the upper cover and the lower end body.

Next, an instantaneous pressure reduction device connected to the smart transmission / reception module and the short-range wireless communication module is installed and fixed in the hand hole formed on the upper surface of the transformer.

Next, the pressure application device module is installed in the manager's smart device.

Next, the real-time temperature, humidity, and pressure information of the transformer measured by the temperature and humidity pressure sensor of the instantaneous pressure reducing device are transmitted to the smart transmission / reception module, the measured information is displayed on the display module, The module provides real-time measurement information to the administrator.

Next, the manager checks the temperature, humidity, and pressure inside a large number of transformers by time and by time with the application module of the pressure application device.

At this time, if the set temperature, set humidity, set pressure or more is detected due to the gas generated by the vaporization of the insulating oil due to the high temperature due to the failure inside the transformer, the danger signal notification manager is executed on the manager's smart device, .

Next, when the pressure of the transformer becomes higher than the elastic restoring force of the elastic spring due to the vaporization of the insulating oil due to the rapid temperature rise and the generated gas, the lower end surface of the pressure reduction frame formed between the upper cover and the lower body is pushed up, The high pressure gas is discharged to the space where it is compressed. When the internal pressure of the gas discharge path becomes less than the elastic restoring force of the elastic spring, the pressure reduction frame is lowered and sealed by the elastic force of the spring.

This prevents the internal pressure of the transformer from suddenly rising to prevent the transformer main body from exploding.

Next, the transformer information that has an abnormality in the measured value such as temperature, humidity, pressure, etc. is obtained through the pressure application device module, and it is inspected and repaired.

100: Instantaneous pressure reducing device 110: Top cover
120: Elastic spring 130: Pressure reducing frame
140: lower body 200: smart transmission / reception module
210: short range wireless communication module 220: display module
230: remote wireless communication module 300: pressure-resistant device application module
310: map activity unit 320: TSP activity unit
330: intent unit 340: temperature event setting unit
350: humidity event setting unit 360: pressure event setting unit
370: Smart control unit

Claims (7)

The smart type pressure suppressing device which prevents the explosion by reducing the pressure by discharging the expanding internal gas to the outside by the pressure rising due to the high temperature gas generated in the transformer due to the failure of the transformer
It is installed on the upper surface of the transformer, the insulation oil is decomposed by the internal fault of the transformer, and the generated high temperature gas is instantaneously opened according to the pressure inside the transformer so that the high pressure gas is discharged, (100)
A smart transmission / reception module 200 installed near the transformer provided with the instantaneous pressure reduction device and transmitting / receiving real-time information sensed by the instantaneous pressure reduction device to a smartphone,
A real-time transformer state detection application module 300 comprising a smart transmission / reception module and a pneumatic pressure application module 300 connected to a 3G or Wifi network and an optical communication network to display a plurality of transformer information on the screen in real time via a portable smart device of an administrator In a smart pressure-proofing apparatus,
The instantaneous pressure reducing device (100)
An upper cover 110 which surrounds the upper end in an upright cylindrical shape and protects and supports the device from external pressure,
An upper end is closely contacted with an upper end spring supporting groove protruding in the upper direction inside the lower end surface of the upper cover and a lower end is closely attached to the lower spring supporting groove recessed in the lower end direction inside the upper end surface of the impact absorbing frame An elastic spring 120,
A pressure reducing frame 130 positioned between the upper cover and the lower body and supporting the impact absorbing springs upright in the upper direction and rising and lowering according to the generation of the instantaneous pressure,
A lower end body (140) having a circular step formed in a cylindrical shape and having a circular step formed around an outer lower end of the impact absorbing frame and having a coupling hole for fixing the transformer coupling bolt around the outer periphery, And a smart pressure control device via a real-time transformer state detection application module.
delete The upper cover (110) according to claim 1, wherein the upper cover
A stent-dope insertion hole 111 penetrating the fixing bolt in a vertical direction at regular intervals of 120 DEG with respect to the center of the top surface,
Penetrating stent dope 112 inserted into the stent-doping holes formed at intervals of 120 占 and formed in the vertical direction at the lower end,
And a top spring support groove (113) for supporting an upper end of the elastic spring with a step protruded in an upper direction inside the center of the bottom surface.
The elastic spring (120) according to claim 1, wherein the elastic spring
A stainless steel having a chemical composition of 18.87 wt% of Cr, 9.23 wt% of Ni, 1.70 wt% of Mn, 0.842 wt% of Si, 0.718 wt% of Nb, 0.0647 wt% of C, 0.0290 wt% of P, And Cr; Or composite deposition of Ti and Al by electron beam evaporation (EB-PVD)
The composite deposition, sputtering (sputter) for 10-20 minutes was added in the degree of vacuum, -450V, 160mA conditions of the Ar gas 4 × 10 ^-2 torr to remove the oxide films of stainless steel, the degree of vacuum of 10 ^-6 torr or more conditions Lt; / RTI >
After the sputtering, the temperature of the stainless steel elastic spring was raised to 280 to 350 ° C. by a halogen lamp of 450 to 550 W so that a vacuum condition of 10 ^-6 torr or more was obtained. Ti, Al bulk and 99.99% Cr powder with a purity of 99.99% are separately put into a tungsten filament, and a voltage and an electric current are applied to the tungsten filament to sequentially perform Ti deposition and Cr deposition, or Ti deposition and Al deposition, Wherein the voltage is in the range of 3.0 to 5.0 kV, the current is in the range of 220 to 300 mA in the case of Ti, 180 to 250 mA in the case of Al, and 230 to 280 mA in the case of Cr and is deposited for 20 to 40 minutes. Smart type pressure control device through application module.
The lower body (140) according to claim 1, wherein the lower body
An upper circular step (141) projecting in the upper direction along the upper inner side surface in a cylindrical shape to support the outer lower end of the shock absorbing frame,
A temperature and humidity sensor 142 inserted into the sensor insertion groove on one side of the upper side of the upper circular step and facing the side of the shock absorbing frame located at the upper end,
A fixing bolt 143 formed at an outer top surface at regular intervals of 120 degrees with respect to the center and positioned so as to be vertically aligned with the non-penetrating stent dope of the top cover,
A coupling hole 144 protruding outward at a constant interval of 120 ° with respect to the center along the lower periphery to insert and fix the transformer coupling bolt,
And a pressure-tightening device coupling bolt (145) which is inserted in a vertical direction when the coupling holes of the lower body and the upper-end coupling holes of the transformer are aligned in the vertical direction, thereby fixing the instantaneous pressure reducing device in close contact with the upper end of the transformer Real-time transformer status detection Smart type pressure control device through application module.
The smart transmission / reception module (200) according to claim 1, wherein the smart transmission /
A short range wireless communication module 210 connected to the motion sensing sensor fixed on one side of the instantaneous pressure reduction device and connected to the short range wireless communication network based on the Bluetooth to transmit the temperature, humidity, pressure,
A display module 220 for providing real-time information of the instantaneous pressure reducing device, which is received by the short-range wireless communication module,
And a remote wireless communication module 230 for transmitting and receiving temperature, humidity, pressure, and shock-absorbing frames inside and outside the transformer in real time to the smart device of the manager through the 3G or Wifi network and the optical communication network. Smart type pressure control device via status detection application module.
The method of claim 1, wherein the application module (300)
A map activity unit 310 for generating, on a map, the respective instantaneous pressure reducing device units provided at the upper ends of the plurality of transformers,
The interfaces of the real-time transformer internal temperature (C), the transformer internal humidity (S), and the transformer internal pressure (P), which are the View and Event responses of the instantaneous pressure relief device selected on the map, A TSP activity unit 320 for generating the TSP activity information,
An intent unit 330 for sending a request command to an event setting unit so that an event is performed when an administrator's interface is moved to another screen according to a touch of an administrator on a screen on which an administrator has displayed,
A temperature event setting unit 340 for setting an allowable temperature when the temperature measurement screen is selected, displaying the internal temperature of the real time transformer, calculating and storing an average value classified by date and time,
A humidity event setting unit 350 for setting an allowable humidity when the humidity measurement screen is selected, displaying the humidity inside the real time transformer, calculating and storing an average value classified by date and time,
A pressure event setting unit 360 for setting an allowable pressure when the pressure measurement screen is selected, expressing the internal pressure of the real time transformer, calculating and storing an average value classified by date and time,
If the received temperature information exceeds the set allowable value, the temperature display frame will turn red. If the humidity information exceeds the set allowable value, the humidity display frame will light blue. If the pressure information exceeds the set allowable value, And a smart control unit (370) for activating the notification manager in real time when any one of the temperature, humidity, and pressure information exceeds the allowable value, Smart type pressure control device through application module.

Images