KR101216106B1 - Device detecting density of salt in air and device for dontrolling intake and exhaust valve in switch board using the same - Google Patents

Abstract

PURPOSE: A device for detecting salt concentration of air and a device for controlling an intake and an exhaust of a distributing board using the same are provided to remarkably extend lifetime by protecting various kinds of electronic products and machines from damage caused by salt and to prevent the frequent replacement of parts, thereby remarkably reducing costs for the replacement and maintenance. CONSTITUTION: A device for detecting salt concentration of air comprises a high voltage generator(11), a trigger sensor(2) for detecting the salt concentration, and a signal amplifier(13). The high voltage generator generates high voltage required for driving the trigger sensor. The trigger sensor for detecting the salt concentration discharges when the salt concentration of the air is over the set concentration while in the state receiving high voltage generated in the high voltage generator. The signal amplifier amplifies discharge signals when the discharge signals are generated by the trigger sensor. [Reference numerals] (11) High voltage generator

Description

Device detecting density of salt in air and device for dontrolling intake and exhaust valve in switch board using the same}

The present invention relates to a salt concentration detector in the air and a control device for intake and exhaust of a switchgear using the same. More specifically, the salt concentration in the air is detected by detecting a salt concentration trigger sensor having a predetermined shape. In the back, the fresh outside air is introduced into the switchboard so that various electrical components installed in the switchboard are minimized from being damaged by salt.

Korea has three sides on the sea, and there are three metropolitan cities and big and small cities on the coast, such as Busan, Incheon, and Ulsan. In coastal cities facing the sea, the salty winds are enormous due to the corrosion of switchboards, street lamps, steel structures, electrical devices, electronic devices, and mechanical devices.

In particular, outdoor switchboards installed by the sea are frequently replaced with parts due to salt damage. Nevertheless, switchboards have only 4 ~ 5 years of service life.

In order to reduce corrosion due to such salts, the salt prevention paint is coated on the outside of the switchboard, but the parts inside the switchboard cannot be painted.

On the other hand, no device has been developed to detect the concentration of salinity contained in the air, so it is impossible to know how much salt is contained in the air adjacent to the beach. If the parts are provided in large quantities, the corrosion caused by the base proceeds faster, and the salt damage is enormous each year.

The present invention has been made to solve such a conventional problem, by detecting the salinity contained in the air in the switchboard, buildings, warehouses, etc. when the salinity above a certain value is detected, opening the intake and exhaust ducts and the outside fresh air By passing through the system, it can be sucked into the inside of a switchboard, building, or warehouse to quickly discharge salt-containing air to the outside, as well as to notify the manager through an alarm if necessary. In addition, it can significantly extend the lifespan by protecting various electrical products, electronics, and mechanical devices used or stored in buildings, warehouses, etc. inside the switchboard from salt damage, and various electrical installations installed in the switchboard. Significantly reduce replacement and maintenance costs by preventing frequent replacement of parts To provide an intake and exhaust control device of the salinity of the detector and the switchboard using the same which can decrease the air it is an object.

In order to achieve the above object, the air salt concentration detector of the present invention comprises: a high voltage generator for generating a high voltage required for driving a salt sensor for detecting a salt concentration having a predetermined shape and configuration; A salt sensor for detecting salt concentration when the salt concentration in the air is higher than a predetermined concentration (X ppm) in a state where a high voltage generated from the high voltage generator is supplied; And a signal amplifier for amplifying and outputting a discharge signal when a discharge signal is generated in the salinity concentration detection trigger sensor.

The high voltage generator may include a boost transformer for boosting a commercial voltage of 220V to a predetermined voltage (Vs); Triple condenser and several bridge-coupled diodes are configured in three stages, and a triple voltage booster which boosts a predetermined voltage output from the secondary coil of the boost transformer by a multiple of 3 times and supplies it to the trigger sensor for salinity detection. It is characterized by consisting of;

The voltage output from the boosting transformer secondary coil of the high voltage generator is 400 to 480 V, and the final voltage output from the triple voltage boosting unit is 1,300 to 1,800 V.

The salt sensor for detecting the salt concentration may include a tube of non-conductor or synthetic resin material having a rectangular air passage hole and having threads at both inner ends thereof; A pair of needle gap adjusting nuts screwed to the threads of the tube in a state where the trigger detection needles are provided, respectively, to adjust the gap of the needles; The high voltage generator is coupled to the tube in a shape in which both ends thereof maintain a predetermined distance together with the needle gap adjusting nuts while being fixedly installed in a shape having a needle shape having a predetermined diameter and length and penetrating the center point of the needle gap adjusting nut. And a pair of trigger detection needles that discharge when the salt concentration in the air is higher than a predetermined concentration (X ppm) in a state where a high voltage generated in the air is supplied.

At this time, the interval between the thread formed in the tube and the needle gap adjusting nut of the non-conductor or synthetic resin material is characterized in that the needle gap adjusting nut is formed to move 1mm when one rotation.

In addition, the diameter of the tube is 10mm to 20mm, the diameter of the needle for trigger detection is characterized in that 1 to 2mm.

In addition, the discharge generated between the trigger detection needle is to be made when the salt concentration in the air is 20 ppm at a predetermined concentration (X ppm) in a state separated from 0.7 cm to 1.3 cm at an atmospheric pressure of 1 atm. It features.

On the other hand, the intake and exhaust control device of the switchgear using the salt concentration detector in the air of the present invention for achieving the above object, the salinity detection signal output from the signal amplifier to the output portion of the salt concentration detector having the above configuration is determined A detection signal generator for converting the frequency into a TTL signal; A digital controller for controlling the driving of the intake and exhaust ducts provided in the switchboard in response to the output signal of the detection signal generator; A power supply for supplying a power supply voltage of ± 15V and 5V to each part; And an intake and exhaust duct driving unit which is operated in response to the output signal of the digital controller and circulates air in the switchboard with external air.

At this time, the predetermined frequency of the TTL salinity detection signal output from the detection signal generator is characterized in that the 1KHz band.

In addition, when the salinity detection signal of a predetermined concentration (X ppm) or more is output from the salinity concentration detector in the air, an alarm for notifying an administrator near a switchboard or a switchboard manager of a remote site is provided. It is characterized by further comprising a wireless alarm signal transmitter.

As described above, according to the salt concentration detector in the air of the present invention and the switchgear control device of the switchboard using the same, when the salinity contained in the air is detected in a switchboard, a building, a warehouse, or the like, when a salinity above a predetermined value is detected, By opening the exhaust duct and passing fresh air outside, it can be sucked into the inside of switchboard, building or warehouse to quickly discharge salty air to the outside. By notifying managers through various equipments, it is possible to prolong the lifespan by protecting various electrical products, electronic products, machinery, etc. used or stored in various electrical-related parts, buildings, warehouses, etc. inside switchboards from salt damage, Frequent replacement of various electrical components installed in switchboards, etc. Not to be very useful inventions, etc. that can significantly improve the reliability of the management and, of course switchboards that can dramatically reduce your replacement and maintenance costs.

1 is a block diagram of a salt concentration detector in the air of the present invention.
2 is a specific circuit diagram of a high voltage generator of the air salt concentration detector of the present invention.
Figure 3 is a longitudinal sectional and side cross-sectional view of the trigger sensor for detecting the salt concentration in the air salt concentration detector of the present invention.
Figure 4 is a block diagram of the intake, exhaust control device of the switchgear using a salt concentration detector in the air of the present invention.
5 is a general discharge characteristic curve diagram at 1 atm according to the present invention.
6 is a graph of discharge voltage at 1 atm associated with the present invention.
7 is a discharge voltage graph when the salinity concentration in the air according to the present invention is 20 ppm.

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

Figure 1 shows a block diagram of a salt concentration detector in the air of the present invention, Figure 2 shows a specific circuit diagram of a high voltage generator of the salt concentration detector in the air of the present invention, Figure 3 is a salt concentration in the air of the present invention The longitudinal cross-sectional and side cross-sectional views of the trigger sensor for detecting salt concentration in the detector are shown.

In addition, Figure 4 shows a block diagram of a device for controlling the intake and exhaust of the switchgear using a salt concentration detector in the air of the present invention, Figure 5 shows a general discharge characteristic curve at 1 atm according to the present invention, 6 is a graph showing a discharge voltage at 1 atm according to the present invention, and FIG. 7 is a graph of a discharge voltage when the salinity concentration in air is 20 ppm according to the present invention.

According to this, the salt concentration detector 1 in the air of the present invention,

A high voltage generator 11 for generating a high voltage required for driving the salt concentration detection trigger sensor 12 having a predetermined shape and configuration;

A trigger sensor 12 for detecting salt concentration when the salt concentration in the air is equal to or higher than a predetermined concentration (X ppm) in a state in which the high voltage generated by the high voltage generator 11 is supplied;

And a signal amplifier 13 for amplifying and outputting a discharge signal when the discharge signal is generated in the salinity concentration detection trigger sensor 12.

At this time, the high voltage generator 11,

A boost transformer 111 for boosting a commercial voltage of 220V to a predetermined voltage (Vs);

Several condensers C1-C9 and several bridge-coupled diodes D1-D12 are coupled in three stages, and the salt level is increased by three times the predetermined voltage output from the secondary coil of the boost transformer 111. It is characterized in that consisting of; three times the voltage boosting unit 112, which is supplied to the concentration detection trigger sensor 12.

In addition, the voltage output from the boost coil 111 secondary coil of the high voltage generator 11 is 400 ~ 480V, the final voltage output from the triple voltage booster 112 is characterized in that 1300 ~ 1800V do.

In addition, the salinity concentration detection trigger sensor 12,

A tube 121 made of a non-conductor or synthetic resin material having a rectangular air passage hole 121a and having threads 121b at both inner ends thereof;

A pair of needle gap adjusting nuts 122 are screwed to the thread 121b of the tube 121 in a state where the trigger detection needles 123 are provided, respectively, so that the gap between the trigger detection needles 123 can be adjusted. )Wow;

The non-conductor has a needle shape having a predetermined diameter and length and is fixed to penetrate the center point of the needle gap adjusting nut 122 so that both ends thereof together with the needle gap adjusting nuts 122 maintain a predetermined gap. Alternatively, a pair of trigger detection needles 123 which are discharged when the salt concentration in the air is higher than a predetermined concentration (X ppm) in a state in which the high voltage generated by the high voltage generator 11 is coupled to the tube 121 of the synthetic resin material and is supplied. It is characterized by consisting of;

At this time, the interval between the thread 121b formed on the tube 121 of the non-conductor or the synthetic resin material and the needle gap adjusting nut 122 is formed so that 1 mm is moved when the needle gap adjusting nut 122 rotates once. do.

In addition, the diameter of the tube 121 is 10mm ~ 20mm, the diameter of the trigger detection needle 123 is characterized in that 1 ~ 2mm.

In addition, the discharge generated between the trigger detection needle 123 is made when the salt concentration in the air is 20 ppm at a predetermined concentration (X ppm) in a state spaced from 0.7 cm to 1.3 cm at an average atmospheric pressure of 1 atm. It is characterized by the loss.

On the other hand, the suction and exhaust control device of the switchboard using the salt concentration detector in the air of the present invention,

At the output of the salt concentration detector 1 having the above-described configuration,

A detection signal generator 2 for converting the salinity detection signal output from the signal amplifier 13 into a TTL signal of a predetermined frequency;

A digital controller (3) for controlling the driving of the intake and exhaust ducts (51) (61) provided in the switchboard in response to the output signal of the detection signal generator (2);

A power supply 4 for supplying power supply voltages of ± 15V and 5V to each part;

And an intake and exhaust duct drive unit (5) (6) which is operated in response to the output signal of the digital controller (3) to circulate air in the switchboard with external air.

At this time, the predetermined frequency of the TTL salinity detection signal output from the detection signal generator 2 is characterized in that the 1KHz band.

In addition, when the salinity detection signal of the concentration (X ppm) or more determined by the salinity concentration detector (1) in the air is output to the output terminal of the digital controller (3) (7) for notifying the manager around the switchboard or It is characterized in that it is further provided with a wired or wireless alarm signal transmitter 8 for informing the remote switchboard manager.

Referring to the effects of the salt concentration detector in the air of the present invention having such a configuration and the intake, exhaust control device of the switchgear using the same.

First, in the present invention, the salinity concentration detector 1 in the air is composed mainly of the high voltage generator 11, the salinity detection trigger sensor 12, and the signal amplifier 13 as main technical components.

In this case, the high voltage generator 11 includes a boost transformer 111 and a triple voltage booster 112 as shown in FIG. 2, and the high voltage required for driving the salt concentration detection trigger sensor 12 having a predetermined shape and configuration. It will perform a function that generates.

Among the components of the high voltage generator 11, the boost transformer 111 performs a function of boosting a commercial voltage of 220V to a predetermined voltage (Vs; for example, 400 to 480V), and the triple voltage booster ( 112 has a configuration in which several capacitors C1-C9 and several bridge-coupled diodes D1-D12 are coupled in three stages, and the predetermined voltage output from the secondary coil of the boost transformer 111 is tripled. The pressure is increased (for example, 1,300 to 1,800V) to perform a function of supplying the salinity concentration detection trigger sensor 12.

That is, in the triple voltage booster 112, the capacitor C1 is supplied through the diode D1 for a half period of positive (+) of the predetermined voltage Vs output from the secondary coil of the boost transformer 111. The voltage is charged up to Vs (= Vc1), and during the negative half period, the capacitor C3 is charged up to 2Vs (Vs + Vc1 = Vc3), which is the voltage supplied through the diode D3.

The capacitor C4 is charged to 3Vs (Vs + Vc3 = Vc4), which is the voltage supplied through the diode D5, during the next positive half cycle, and the diode C6 is dioded during the negative half cycle. It is charged up to 5Vs (Vs + Vc1 + Vc4 = Vc6), which is the voltage supplied through D7.

In addition, during the next positive half period, the capacitor C7 is charged to 8 Vs (Vs + Vc3 + Vc6 = Vc7), which is the voltage supplied through the diode D9, and the capacitor C9 during the negative half period. Is charged up to 13Vs (Vs + Vc1 + Vc4 + Vc7 = Vs + Vs + 3Vs + 8Vs), which is the voltage supplied through the diode D11.

The capacitor C2 is charged to Vs, which is a voltage supplied through the diode D2, during the positive half of the predetermined voltage Vs, and the capacitor C3 is charged to the diode D4 during the negative half period. Is charged up to 2Vs, and the capacitor C5 is charged up to 3Vs, the voltage supplied through the diode D6, during the next half cycle. Capacitor C6 is charged to Vs + Vs + 3V = 5Vs via diode D8.

In addition, the capacitor C8 is charged to Vs + 2Vs + 5Vs = 8Vs through the diode D10 during the next positive half cycle, and the capacitor C9 turns the diode D12 on the negative half cycle. It charges up to Vs + Vs + 3Vs + 8Vs = 13Vs.

Thus, the principle of boosting the voltage up to about 3 times is the same as above, but the amount of boosting may vary according to the capacity of the actual capacitors.

On the other hand, the salinity concentration detection sensor 12 is provided with a tube 121 of a non-conductor or synthetic resin material, a pair of needle gap adjusting nut 122 and a pair of trigger detection needle 123 as shown in FIG. In the state where the high voltage generated by the high voltage generator 11 is supplied, the discharge operation is performed when the salt concentration in the air is equal to or higher than a predetermined concentration (X ppm).

At this time, the non-conductor or synthetic resin tube 121 of the salinity concentration detection sensor 12 components of the diameter of 10㎜ ~ 20㎜, high heat resistance of 260 ° and withstand voltage of 16 ~ 24 [kV / mm] high A tube having a characteristic has a rectangular air passage hole (121a) in the middle portion and a threaded portion 121b at both inner ends thereof.

The pair of needle gap adjusting nuts 122 are screwed to the thread 121b of the tube 121 in a state where the pair of needle gap adjusting nuts 122 are provided with the trigger detection needles 123 penetrating through the center thereof, respectively, and thus the trigger detection needles 123. ) So that the interval between the trigger detection needle 123, which will be described later, is spaced from 0.7 cm to 1.3 cm at an average atmospheric pressure of 1 cm to determine the concentration of salt in the air (X ppm). It is preferable to discharge between the trigger detection needles 123 at 20 ppm.

At this time, the interval of the thread 121b formed on the tube 121 and the needle gap adjusting nut 122 of the non-conductor or synthetic resin material is molded so that 1mm is moved when the needle gap adjusting nut 122 rotates one pair, The gap between the trigger detection needles 123 can be adjusted accurately.

In addition, the pair of trigger detection needle 123 is a needle shape having a diameter of 1 ~ 2mm for fixing the needle spacing in a state that is fixedly installed to penetrate the center point of the needle spacing adjusting nut 122 Both ends of the nut 122 are coupled to the non-conductor or synthetic resin tube 121 in a shape that maintains a predetermined interval, and the salt concentration in the air is supplied in the state where the high voltage generated by the high voltage generator 11 is supplied. It should be discharged when it is over (X ppm).

In addition, the signal amplifier 13, when the discharge signal is generated in the salt concentration detection trigger sensor 12, amplifies it to a predetermined level to detect the signal of the intake and exhaust control device of the switchboard using a salt concentration detector in the air to be described later It performs the function to deliver to the generator (2).

At this time, of the resistors R1 and R2 provided between the output terminal of the salt concentration detection trigger sensor 12 and the input terminal of the signal amplifier 13, the resistor R1 is for current limiting and the resistor R2 is triggered. Resistor for signal detection.

On the other hand, the intake / exhaust control device of the switchboard using the salt concentration detector 1 in the air of the present invention, the detection signal generator (2) in the output portion of the salt concentration detector 1 having the above configuration as shown in FIG. And a digital controller (3), intake / exhaust ducts (51) (61), power supply (4), and intake / exhaust duct drive units (5) (6) to detect salts contained in the air in the switchboard and the like. When salinity above the value is detected, the intake / exhaust duct is opened and the fresh air is allowed to pass through to the inside of the switchboard to quickly discharge the salt-containing air to the outside. It is a technical component.

At this time, the detection signal generator 2 converts the salinity detection signal output from the signal amplifier 13 into a TTL signal of a predetermined frequency (for example, 1 KHz band) so that the digital controller 3 can recognize it accurately. Will be performed.

In addition, the digital controller 3 performs a function of controlling the driving of the intake and exhaust ducts 51 and 61 provided in the switchboard in response to the above-described output signal of the detection signal generator 2, and the power supply. The supply unit 4 supplies a power supply voltage of ± 15V and 5V to each part.

In addition, the intake / exhaust duct driver 5 or 6 operates the intake / exhaust ducts 51 and 61 in response to the output signal of the digital controller 3 to circulate the air in the switchboard with the outside air. Will be performed.

In addition, in the present invention, the output terminal of the digital controller 3 is further provided with an alarm 7 or a wired / wireless alarm signal transmitter 8 as necessary, so that the concentration determined by the salt concentration detector 1 in the air ( If the salinity detection signal of 20 ppm or more, which is X ppm), is outputted by the manager around the switchboard, the alarm (7) can be used to accurately know. Accurately recognize the salinity detection signal transmitted and take the necessary action quickly.

On the other hand, Figure 5 shows a general discharge characteristic curve diagram at 1 atm according to the present invention, a graph of the discharge start voltage occurring at 1 [cm] per barometric pressure when using a large curvature needle according to paschen's law, from the right The reference data indicates that the discharge start voltage decreases as the air pressure increases to the left of the discharge voltage at a distance of 1 cm from 0 [FT] .The reason for the difference in the discharge start voltage per barometric pressure from the experiment is that the old needle is used in the graph. This is because the needle was used in the actual experiment.

In addition, Figure 6 shows a discharge voltage graph at 1 atm related to the present invention, which is an average discharge characteristic result of 200 discharge experiments, and the distance of the needle at 0.7 atm. The graph shows the result of checking the maximum voltage of the discharge.

In addition, Figure 7 shows a discharge voltage graph when the salt concentration in the air of the present invention is 20 ppm, in this case is the average discharge characteristics results of 100 discharge experiments, which contains 20 ppm of salt As a result of the discharge characteristics when air was introduced into the trigger sensor for salinity detection, the discharge occurred at about 1.1cm, and the discharge voltage was about 860 [V] on average. Experimental results confirm the difference in the characteristics.

As described above, according to the present invention, when the salinity contained in the air in the switchboard is detected at a predetermined value or more, the intake and exhaust ducts 51 and 61 are automatically operated to quickly remove the air containing the salinity remaining inside the switchboard. In addition, it can be discharged to the outside and can be notified to the manager through an alarm if necessary, so that various electrical products inside the switchboard, various electrical products, electronic products, machinery, etc. used or stored in buildings It can protect the equipment from salt damage and extend its lifespan significantly. It also prevents the frequent replacement of various electrical components installed in the switchboards, and can greatly reduce the replacement and maintenance costs. It can greatly improve the reliability.

It should be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims.

1: salinity detector in air
11: high voltage generator
111: boosting transformer 112: triple voltage boosting unit
12: Trigger sensor for salinity detection
121: tube
121a: air passage 121b: thread
122: needle spacing nut
123: trigger detection needle
13: signal amplifier
2: detection signal generator
3: digital controller
4: power supply
5, 6: intake and exhaust duct drive unit 51, 61: intake and exhaust duct
7: alarm
8: wired / wireless alarm signal transmitter

Claims (10)

A high voltage generator for generating a high voltage required for driving a trigger sensor for detecting salt concentration having a predetermined shape and configuration;
A salt sensor for detecting salt concentration when the salt concentration in the air is higher than a predetermined concentration (X ppm) in a state where a high voltage generated from the high voltage generator is supplied;
And a signal amplifier for amplifying and outputting a discharge signal when a discharge signal is generated in the salinity concentration detection trigger sensor.
The salt concentration detection sensor,
A tube of non-conductor or synthetic resin material having a rectangular air passage hole and provided with threads at both inner ends thereof;
A pair of needle gap adjusting nuts screwed to the threads of the tube in a state where the trigger detection needles are provided, respectively, to adjust the gap of the needles;
The high voltage generator is coupled to the tube in a shape in which both ends thereof maintain a predetermined distance together with the needle gap adjusting nuts while being fixedly installed in a shape having a needle shape having a predetermined diameter and length and penetrating the center point of the needle gap adjusting nut. And a pair of trigger detection needles that discharge when the salt concentration in air is above a predetermined concentration (X ppm) in a state where a high voltage generated in the air is supplied.
delete delete The method according to claim 1,
The spacing of the threads formed on the tube and the needle gap adjusting nut is formed so that 1 mm is moved when the needle gap adjusting nut rotates once, the salt concentration detector in the air.
The method according to claim 1,
The diameter of the tube is 10mm ~ 20mm, the salt detection detector in the air, characterized in that the diameter of the trigger detection needle is 1 ~ 2mm.
The method according to claim 1,
The discharge generated between the trigger detection needle is made when the salinity in the air is 20 ppm at a predetermined concentration (X ppm) in a state spaced from 0.7 cm to 1.3 cm at an average atmospheric pressure of 1 atm. Air salinity detector.
In the configuration of the intake and exhaust control device of the switchboard using the salt concentration detector of any one of claims 1 and 4 to 6.
At the output of the salinity detector,
A detection signal generator for converting the salinity detection signal output from the signal amplifier into a TTL signal having a predetermined frequency;
A digital controller for controlling the driving of the intake and exhaust ducts provided in the switchboard in response to the output signal of the detection signal generator;
A power supply for supplying a power supply voltage to each part;
Intake and exhaust control device of the switchboard using a salt concentration detector in the air, characterized in that it further installed; air intake, exhaust duct drive unit to operate in response to the output signal of the digital controller to circulate the air in the switchboard with the outside air.
The method of claim 7,
A predetermined frequency of the TTL salinity detection signal output from the detection signal generator is a 1KHz band, the intake, exhaust control device of the switchboard using a salt concentration detector in the air.
The method of claim 7,
The output terminal of the digital controller is provided with a salinity concentration in the air, characterized in that further provided with an alarm to notify the manager around the switchboard when the salinity detection signal of more than a predetermined concentration (X ppm) from the salinity concentration detector in the air Device for controlling intake and exhaust of switchgear using detector.
The method of claim 7,
The output terminal of the digital controller is further provided with a wired or wireless alarm signal transmitter for notifying the switchboard manager of a remote site when the salinity detection signal of a predetermined concentration (X ppm) or more is output from the air salinity concentration detector. Intake and exhaust control device of switchboard using salinity concentration detector in air.

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