KR101398519B1 - Solar module measuring instrument - Google Patents

Abstract

A probe device for a solar module measurement device is a measurement probe device used for measuring the output attributes of a solar module to measure the normal operation status of the solar module. The probe device is shifted up and down by an elastic member when the probe device touches an output terminal of the solar module to ensure a contact force to be even while preventing the contact point of the output terminal of the solar module and the probe device to prevent a spark from occurring in the contacting process, thereby extending the life of the solar module and reduce the measurement errors.

Description

[0001] Solar Module Measuring Instrument [0002]

More particularly, the present invention relates to a probe apparatus used for measuring a power generation characteristic of a solar module in order to determine whether the solar module is operating normally or not, When the probe is directly in contact with any position of the line, it is contacted with a certain pressure to prevent breakage of the output terminal. It is equipped with a lighting device to precisely measure in dark places. It removes foreign matter by spouting gas, And more particularly, to a probe device of a photovoltaic module measuring apparatus which increases the service life of a contacted portion while reducing the occurrence of the probe.

Photovoltaic modules are generally called solar cells. They are installed on a large scale to construct large-scale power plants or operate electric lamps and household appliances developed using small-scale photovoltaic modules.

The solar module generates electricity by using sunlight emitted by the sun, so it can not generate electricity if it is cloudy, snowy, rainy, or does not have sunlight at night, and the surface of the solar module is contaminated If contaminated, normal operation may not be possible.

In addition, since the solar module generally has a structural characteristic that is likely to be damaged by impact, vibration, or earthquake, it is necessary to check, measure or check the normal operation status from time to time.

When a large-scale installed solar module such as a solar power plant is checked for normal operation, a spark or the like may occur in a position (portion) where the probe or the probe (probe) It can be easily worn or damaged by repetition, and at the same time, measurement error may occur or sparks may cause damage to the surroundings.

Therefore, the probe device is one of the most important components in the photovoltaic module measurement system.

According to one embodiment of the prior art, Korean Patent Registration No. 10-0452847 (October, 2004) entitled "Charge / discharge test probe for secondary battery ".

According to this conventional technique, the measuring probe is composed of the fixed body and the plunger body, and the plunger body, which has been worn out for a long time, is easily replaced, thereby improving the contact performance.

However, the prior art relates to a technique of easily replacing a worn body, and there remains a problem that sparks that may be generated at the time of measurement and foreign matters that may be buried in the measured terminals can not be removed.

Therefore, it is necessary to develop a technology that minimizes the probe wear of the probe device of the photovoltaic module measuring device while removing foreign matter from the measurement point and preventing sparking during measurement.

Korean Registered Patent No. 10-0452847 (filed on October 5, 2004), entitled "Charge / discharge test probe for secondary battery"

SUMMARY OF THE INVENTION It is an object of the present invention to provide a probe device of a solar module measuring device capable of accurately measuring whether a solar module is normally operating without errors.

Further, the present invention provides a probe device of a photovoltaic module measuring device which precisely measures a voltage and a current output from a solar module, because the probe contacts the measured terminal with a constant pressure and removes foreign substances or contaminants in the surroundings That is the purpose.

It is another object of the present invention to provide a probe device of a solar module measuring device which prevents abrasion and breakage of a contact by preventing a spark from being generated because a gas is spouted by selection during a measurement of a probe in contact with a measured terminal, to be.

It is another object of the present invention to provide a probe device for a solar module measuring device which makes it possible to precisely measure even in a dark place by illuminating a measurement site by selecting the probe in contact with the terminal to be measured.

According to another aspect of the present invention, there is provided a probe apparatus for a solar module measurement device, the probe apparatus comprising: a probe having an inner portion penetrating in a vertical direction, a pair of outer stoppers formed in an outer direction, A cylindrical outer plunger 110 attached with an elastic spring 114 for providing an elastic force to the space between the stoppers 112 and flowing up and down by the elastic spring 114; A circular rod-shaped inner plunger 120 fixedly installed in the longitudinal direction of the outer plunger 110 and vertically flowing together with the outer plunger 110; And a pair of latching protrusions 132 protruding inwardly from the outer plunger 110 and spaced apart from the outer plunger 110 by a predetermined distance are formed in the outer plunger 110 so as to surround the outer surface of the outer plunger 110, The upper end of the inner plunger 120 is inserted into the insertion groove 134 formed by piercing the center portion of the upper surface of the inner plunger 120, A body portion 130 protruding from a lower end of the outer plunger 110 through an opening; . ≪ / RTI >

Further includes a contact portion 200 protruding downward from a lower end of the outer plunger 110 and extended from the inner plunger 120 to be electrically connected to the output terminal of the solar module 300 can do.

The contact portion 200 has at least one receiving groove 222a and a receiving groove 222b formed therein spaced apart from each other by a predetermined distance and is formed at an upper end portion of the lower end of the inner plunger 120 in a left- And one or more mold grooves 224a and 224b into which the one or more extension pins 210a and 210b bent in the downward direction are inserted are formed in the receiving grooves 222a and 222b, The elastic members 226a and 226b are connected at one end to the upper plates 225a and 225b and the other ends of the elastic members 226a and 226b are connected to the upper plates 225a and 225b. And second probe tips 240a and 240b connected to the bottom plates 227a and 227b and protruding downward to contact the output terminals of the solar module 300 have.

The mold 220 having the mold grooves 224a and 224b is provided with light emitting diodes 230a and 230b at the left end and right end portions of the lower surface thereof, And the rib portion 292 may be formed to pass through in the vertical direction.

The receiving grooves 222a and 222b are electrically connected to the batteries 250a and 250b and the second probe tips 240a and 240b contact the output terminals of the solar module 300 and the elastic members 226a, The power supply units 223a and 223b are operated while being in contact with the upper plates 225a and 225b connected to the power supply units 226a and 226b and the power supply units 223a and 223b are pressed, (230a, 230b) are electrically connected to emit light.

And a connector 260 which is a passage through which the outside air is injected through the outer plunger 110 and the inner plunger 120. The inner plunger 120 is inserted into the inner plunger 120 through the connector 260 And an air passage portion 290 is formed at a lower end of the air passage portion 290 so that the air moves downward and the air passage portion 290 is connected to the second air passage portion 292.

According to the present invention having the above-described configuration, when the probe device of the photovoltaic module measuring instrument is in contact with the output terminal (measured terminal) of the photovoltaic module, the resilient member always contacts with a constant pressure, It is advantageous to prevent the breakage of the part.

In addition, the present invention as described above has an advantage of improving the reliability of the measurement result by accurately contacting the part to be measured, because the measurement part is illuminated by the light emitting diode provided in the probe device and selectively driven.

In addition, the present invention as described above can prevent a measurement error by removing foreign matter or contaminants around the probe unit by ejecting compressed air or nitrogen gas at a measurement site where the probe unit is in contact with the probe unit, Since the flame is not generated, it is possible to prevent the shortening of the service life due to the melting of the contact point of the probe and the portion to be measured, and to prevent the peripheral damage caused by the spark flame.

Meanwhile, since the present invention as described above prevents the spark due to the contact contact during the measurement, the shock voltage caused by the spark does not affect the photovoltaic module measuring instrument and operates normally so that the reliability of the measured value is further improved .

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a structure of a probe apparatus of a photovoltaic module measuring apparatus according to a first embodiment of the present invention,
FIGS. 2 and 3 are views showing the structure of a probe apparatus of a photovoltaic module measuring apparatus according to a second embodiment of the present invention,
FIG. 4 is a plan view of a probe apparatus of a photovoltaic module measuring apparatus according to a second embodiment of the present invention, FIG.
5 is an enlarged view of a contact portion of a probe apparatus of a solar cell module measuring apparatus according to a second embodiment of the present invention,
6 is a view showing a structure of a probe apparatus of a photovoltaic module measuring apparatus according to a third embodiment of the present invention,
And
7 is an enlarged view of a contact portion of a probe apparatus of a photovoltaic module measuring apparatus according to a third embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

A probe device of a solar module measuring device according to an embodiment of the present invention is an apparatus for measuring a voltage or current of an electric power generated by a solar module to determine whether the solar module operates normally or not , Is a device suitable for measuring solar module failure and normal operation in a solar power plant that uses commercialized electricity generated by large-scale installation of solar modules.

In the following description, it is assumed that the probe device of the photovoltaic module measuring device is in contact with the output terminal of the photovoltaic module. In order to facilitate understanding, it is very natural Do.

The output terminal or the measuring point for outputting the electricity generated by the solar module is constituted by the exposed state for inspection or measurement, so that it is contaminated with the foreign substance. In order to check or measure the electric characteristic of the solar module, It is common to apply a large force in order to reduce the contact resistance by the foreign matter.

Further, since the end portion of the probe apparatus which is in contact with the measured point is relatively sharp compared with the other portion, a large load is applied to a small area of a designated point (a specific portion, a measured terminal or an output terminal) of the measured point to be damaged.

Also, since the measurement point of the photovoltaic module may be disposed at a location where the illumination is not well performed by other peripheral devices or components, measurement errors due to erroneous contact may occur when the probe is inspected or measured.

On the other hand, sparking can occur when other devices contact the electric part. Especially, when the characteristics of large-capacity electricity generated from a photovoltaic module such as a solar power plant is measured, It can malfunction.

Therefore, the probing device of the photovoltaic module measuring device may not be in contact with the output terminal of the photovoltaic module due to the damage of the contact portion (spark) or the like, and the reliability of the inspection may be deteriorated.

Hereinafter, the solar cell module measuring probe device of the present invention constitutes an elastic member which maintains the contact pressure of the contact portion in contact with the output terminal of the solar cell module constantly, and when the measuring device contacts the output terminal of the solar cell module, The diode is emitted and compressed air or nitrogen gas is injected (ejected) to remove foreign matter or contaminants adhering to the output terminal of the solar module, thereby preventing sparks from occurring, thereby improving the reliability of the inspection.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a structure of a probe apparatus of a photovoltaic module measuring instrument according to a first embodiment of the present invention; FIG.

The probe apparatus 100 of the photovoltaic module measuring apparatus according to the first embodiment of the present invention includes an outer plunger 110, an inner plunger 120, and a body portion 130.

The first embodiment is a configuration in which the first probe tip 121 of the solar cell module measuring probe device 100 is in direct contact with the corresponding terminal or output terminal of the solar cell module 300.

Since the configurations of the first embodiment and the second embodiment differ depending on whether or not the contact section 200 is provided, the remaining configuration of the first embodiment will be described in detail in the configuration of the second embodiment so as not to be duplicated.

FIGS. 2 and 3 are views showing a structure of a probe apparatus of a solar module measuring apparatus according to a second embodiment of the present invention, and FIG. 4 is a view showing a probe apparatus of a solar module measuring apparatus according to a second embodiment of the present invention And FIG. 5 is an enlarged view of a contact portion of the probe apparatus of the photovoltaic module measuring apparatus according to the second embodiment of the present invention.

The probe apparatus 100 of the photovoltaic module measuring apparatus according to the second embodiment of the present invention includes an outer plunger 110, an inner plunger 120, a body portion 130, and a contact portion 200.

The contact portion 200 is coupled to the probe tip 121 in a generally known manner, including a screw connection, and thus will not be described in detail and will not be shown in detail in the drawings.

The outer plunger 110 has a cylindrical shape and its interior passes vertically.

The inner plunger 120 is installed in the outer plunger 110 in a circular rod shape while being maintained in a state of being spaced apart from each other by uniform intervals in the longitudinal direction of the upper plunger 110 and fixed to the outer plunger 110 And is vertically moved or flowed together with the outer plunger 110.

The inner plunger 120 has an upper portion extending through the upper opening of the outer plunger 110 and a portion of the lower portion or a portion of the first probe tip 121 extending from the lower end of the outer plunger 110, (Lower end) of the outer plunger 110 through the lower end opening of the outer plunger 110 and is connected to the contact portion 200. [

The outer plunger 110 is provided with a pair of outer stoppers 112 protruding outwardly at an outer portion thereof and an elastic spring 114 for providing an elastic force between the outer stoppers 112.

Thus, the outer plunger 110 moves or flows up and down in the range of about 10 millimeters (mm) by the resilient spring 114.

A reed switch 116 for inputting a command signal or a touch signal for controlling the start of measurement of a voltage and a current is provided at an upper end of the outer plunger 110. [

The inner plunger 120 is fixed to the portion of the outer plunger 110 located at the lower end opening portion of the outer plunger 110 by the inner stopper 122, 110).

The reed switch 116 may input a command signal to cause a voltage or a current to be measured after the first probe tip 121 or the contact portion 200 contacts the output terminal of the solar module 300. [

The body part 130 surrounds the outer surface of the outer plunger 110 and forms a pair of engagement protrusions 132 protruding inwardly while being spaced apart from the outer plunger 110 by a uniform and uniform interval. So that the outer stopper 112 of the lancer 110 is supported by the catching jaw 132. [

At this time, the lower end of the elastic spring 114 is supported by the outer stopper 112 formed below the pair of outer stoppers 112, and the upper end of the elastic spring 114 is formed above the pair of outer stoppers 112 And is supported by the outer stopper 112.

Therefore, the outer plunger 110 can be vertically moved or flowed in the above-described 10 mm range in the vertical direction within the body portion 130.

The upper end of the inner plunger 120 is inserted into the insertion groove 134 through which the central portion of the upper surface of the body 130 is inserted and the lower end of the outer plunger 110 is extended through the opening of the lower surface Respectively.

The upper end of the inner plunger 120 passing through the insertion groove 134 measures the voltage and current of the electric power generated and output by the solar module in a state of being electrically connected to the solar module measuring device or the test equipment You can proceed with testing.

A threaded portion is formed at the outer lower end of the body portion 130 and a corresponding threaded support rib 140 screwed with the thread is screwed.

The supporting rib 140 screwed to the lower end of the body part 130 allows the operator to easily contact the solar cell module measuring probe device 100 with the output terminal of the solar cell module 300 with a small force, Thereby protecting the operator's hands.

The contact portion 200 is a detachable module that is extended from the first probe tip 121 formed at the lower end of the inner plunger 120 in a generally visible manner and contacts the output terminal of the solar module 300. [ to be.

The contact portion 200 includes a pair of extension pins 210a and 210b, a mold 220, upper plates 225a and 225b, elastic members 226a and 226b, lower plates 227a and 227b, and a second probe tip 240a , 240b.

The pair of extension pins 210a and 210b extend from the lower end of the inner plunger 120 in the direction perpendicular to the left and right sides, respectively, and then are bent in the downward direction.

The mold 220 is a rectangular insulator having two receiving grooves 222a and 222b spaced apart from each other by a predetermined distance and a mold groove 2224a for inserting a pair of extending pins 210a and 210b at an upper end thereof. , 224b are formed.

Inside the receiving grooves 222a and 222b are formed horizontal top plates 225a and 225b provided at the ends of the extension pins 210a and 210b and elastic members 226a and 226b connected at one end to the top plates 225a and 225b, 226b, and bottom plates 227a, 227b connected to the other end portions of the elastic members 226a, 226b.

The mold 220 is provided with light emitting diodes 230a and 230b at the left end and the right end of the lower surface, respectively, as shown in the accompanying drawings.

The second probe tips 240a and 240b are formed to protrude downward from the end surfaces of the bottom plates 227a and 227b and the second probe tips 240a and 240b are directly contacted with the output terminal of the solar module 300 .

The extension pins 210a and 210b, the upper plates 225a and 225b, the elastic members 226a and 226b, the lower plates 227a and 227b and the probe tips 240a and 240b are electrically connected to the inner plunger 120, So as to be extended.

It is preferable that conductive portions 223a and 223b made of metal are provided in the shape of a plate on the upper end surface of the receiving grooves 222a and 222b and each of the conductive portions 223a and 223b is composed of two electrodes.

Each electrode of the conductive parts 223a and 223b is electrically connected to the batteries 250a and 250b through electric wires and the batteries 250a and 250b are electrically connected to the light emitting diodes 230a and 230b through electric wires. That is, when the respective electrodes of the conductive parts 223a and 223b are electrically connected, each of the light emitting diodes 230a and 230b can be set to the ON state.

The elastic members 226a and 226b are in the form of a coil spring which generates an elastic force in the vertical or vertical direction and is easy to shrink.

The elastic members 226a and 226b move vertically when the contact portion 200 touches the output terminal of the solar cell module measuring probe apparatus 100 to keep the contact pressure constant to keep the measurement result value constant At the same time, to prevent abrasion and breakage of the second probe tips 240a and 240b and the output terminals of the solar module 300.

That is, the second probe tips 240a and 240b maintain the contact pressure constant in two steps by the elastic spring 114 and the elastic member elastic members 226a and 226b, and prevent wear and damage.

When the probe tips 240a and 240b of the contact portion 200 contact the output terminal of the solar module 300, the upper plates 225a and 225b move up and down by the elastic members 226a and 226b, 223a, and 223b, so that the electrodes are electrically connected.

Each of the electrodes constituting each of the conductive parts 223a and 223b is electrically connected to the batteries 250a and 250b and the power of the batteries 250a and 250b is supplied to the light emitting diodes 230a and 230b, 230a, and 230b emit light.

That is, when the second probe tips 240a and 240b contact the output terminal of the solar module 300, the conductive parts 223a and 223b are connected to the upper plates 225a and 225b connected to the elastic members 226a and 226b, And is operated in an on state while being contacted by the switch.

Therefore, when the solar cell module probe device 100 is in contact with the output terminal of the solar cell module 300, the light emitting diodes 230a and 230b are illuminated to illuminate the periphery of the output terminal of the solar cell module 300 with light, To prevent contact.

The second probe tips 240a and 240b of the photovoltaic module probe device 100 are brought into contact with the output terminal of the solar module 300 to detect a voltage or a current measured or measured through the inner plunger 120 (Pass) to the photovoltaic module meter or test equipment.

Then, the photovoltaic module measuring device or the test equipment analyzes the electrical characteristics detected or measured at the output terminal of the photovoltaic module 300 to determine whether the photovoltaic module 300 is operating normally or the surface is contaminated with foreign matter such as fallen leaves, Whether it can not normally develop because it can not receive sunlight normally due to clouds, snow, rain, fog, etc. can be judged.

FIG. 6 is a view showing a structure of a probe apparatus of a solar cell module measuring apparatus according to a third embodiment of the present invention. FIG. 7 is an enlarged view of a probe unit of a solar cell module measuring apparatus according to a third embodiment of the present invention Fig.

The same components as those of the photovoltaic module probe probe apparatus 100 according to the first embodiment of the present invention shown in Fig. 1 or the second embodiment of the present invention shown in Figs. 2 to 5 are not described I will explain China mainly.

The photovoltaic module probe device 100 according to the third embodiment of the present invention can be applied to a case where the second probe tips 240a and 240b of the contact portion 200 contact the output terminal of the photovoltaic module probe device 100 The output terminal is further added with the function of blowing away foreign matter contaminated. It is quite natural that foreign matter can include leaves, pauses, and the like.

To this end, the probe apparatus 100 of the photovoltaic module measuring instrument includes a connector 260, an air compressor 270, a hose 272 and a power supply unit 280.

The connector 260 is internally passed through the outer plunger 110 and the inner plunger 120, and has a first end 262 formed at one end thereof.

The air compressor 270 receives power from the power supply unit 280 and is driven by the corresponding control signal to compress or store the air.

In another embodiment, in the case of discharging compressed nitrogen or inert gas, the configuration of the air compressor 270 and the power supply unit 280 may be replaced by the gas cylinder and the discharge control valve.

Meanwhile, the gas cylinder may be replaced with a one-time compressed air tube, and a one-time gas cylinder or a compressed air tube may be detachably attached to one side of the body portion 130.

The discharge of incandescent gas containing nitrogen gas is to prevent the occurrence of sparks at the measurement contact, thus protecting both sides of the contact, eliminating the foreign substances in the surrounding area, suppressing the measurement error, Can be prevented from being ignited by the spark.

Hereinafter, the compressed air discharge will be described as including discharging of an inert gas containing nitrogen gas, and will not be described redundantly.

The hose 272 is connected to one end of the air compressor 270 to transfer compressed air or nitrogen gas. Hereinafter, the air is an inert gas containing compressed air or nitrogen gas.

A second connection hole 274 is provided at one end of the hose 272 and a second connection hole 274 and a first connection hole 262 of the connector 260 are coupled or fastened.

A first air passage portion 290 is formed at a lower end of the inner plunger 120, and is a passage through which air flows so that the air introduced through the connector 260 moves downward.

The mold 220 of the contact portion 200 is vertically penetrated through the second air passage portion 292 connected to the first air passage portion 290 of the inner plunger 120 at a central portion thereof.

The compressed air of the air compressors 270 flows through the hose 272 into the first air passage portion 290 of the inner plunger 120 and the second air passage portion 292 of the contact portion 200 mold 220 So that the photovoltaic module probe device 100 blows off the foreign matter contaminating the vicinity of the output terminal of the photovoltaic module contacted by the probe device 100, thereby preventing the spark from being generated.

The solar cell module measuring probe device 100 of the present invention is generated from the solar module 300 through the contact portion 200, the light emitting diodes 230a and 230b, the first and second air passage portions 290 and 292, A high level of current can be measured without danger.

The embodiments of the present invention described above are not implemented only by the apparatus and / or method, but may be implemented through a program for realizing functions corresponding to the configuration of the embodiment of the present invention, a recording medium on which the program is recorded And such an embodiment can be easily implemented by those skilled in the art from the description of the embodiments described above.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

100: photovoltaic module probe probe device 110: outer plunger
112: outer stopper 114: elastic spring
116: Reed switch 120: Inner plunger
122: inner stopper 130:
132: latching jaw 134: insertion groove
140: Support rib 200:
210a, 210b: extension pin 220: mold
222a, 222b: receiving grooves 223a, 223b:
224a, 224b: mold grooves 225a, 225b: upper plate
226a, 226b: elastic members 227a, 227b:
230a, 230b: light emitting diode 240a, 240b: second probe tip
250a, 250b: Battery 260: Connector
262: first connection port 270: air compressor
272: Hose 274: Second connector
280: power source unit 290: first air passage unit
292: second air passage section 300: solar module

Claims (6)

A probe apparatus for a photovoltaic module measuring instrument,
And a pair of outer stoppers 112 are formed in the outer direction of the inner stopper 112. An elastic spring 114 for applying an elastic force to the space between the outer stoppers 112 is attached to the elastic spring 114, A cylindrical outer plunger 110 which flows upward and downward;
A circular rod-like inner plunger 120 fixed in the longitudinal direction of the upper part of the outer plunger 110 and flowing up and down together with the outer plunger 110; And
A pair of latching protrusions 132 spaced apart from the outer plunger 110 by a predetermined distance and protruding inward are formed to surround the outer surface of the outer plunger 110, The upper end of the inner plunger 120 is inserted through the insertion groove 134 formed by piercing the center of the upper surface of the outer stopper 112 while being supported by the engagement protrusion 132, (130) having a lower end portion of the outer plunger (110) extended and protruded; And a probe unit for measuring the temperature of the photovoltaic module.
The method according to claim 1,
Further includes a contact portion 200 protruding downward from a lower end of the outer plunger 110 and extended from the inner plunger 120 to be electrically connected to the output terminal of the solar module 300 The probe device of the photovoltaic module measuring instrument.
3. The method of claim 2,
The contact portion 200
The receiving grooves 222a and 222b are spaced apart from each other by a predetermined distance and extend in the left and right directions from the lower end of the inner plunger 120 at the upper end, At least one mold groove 224a or 224b into which the formed at least one extension pin 210a or 210b is inserted and at least one of a horizontal plate provided at the end of the extension pin 210a or 210b in the receiving groove 222a or 222b, Elastic members 226a and 226b connected at one end to the upper plates 225a and 225b and lower plates 227a and 226b connected to the other ends of the elastic members 226a and 226b, And second probe tips 240a and 240b connected to the bottom plates 227a and 227b and protruding downward to contact the output terminals of the solar module 300. [ The probe unit of the module meter.
The method of claim 3,
The mold 220 having the mold grooves 224a and 224b is provided with light emitting diodes 230a and 230b at the left end and right end portions of the lower surface thereof, And the projecting portion (292) is formed in a vertical direction.
5. The method of claim 4,
The receiving grooves (222a, 222b)
Are electrically connected to the batteries 250a and 250b
The second probe tips 240a and 240b contact the output terminals of the solar module 300 and the elastic members 226a and 226b and the upper plates 225a and 225b, And the batteries 250a and 250b and the light emitting diodes 230a and 230b are electrically connected and lighted by the conductive parts 223a and 223b being pressed. The probe device of the optical module measuring instrument.
6. The method of claim 5,
And a connector 260 which is a passage through which the outside air is injected through the outer plunger 110 and the inner plunger 120. The inner plunger 120 is inserted into the inner plunger 120 through the connector 260 And an air passage portion 290 is formed at a lower end of the air passage portion 290 so that the air moves downward and the air passage portion 290 is connected to the second air passage portion 292 The probe device of the photovoltaic module measuring instrument.

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