KR102253660B1 - Testing apparatus of UV lamp - Google Patents

Abstract

The present invention relates to an ultraviolet lamp testing apparatus, and to an ultraviolet lamp testing apparatus that performs both a light emission test of an ultraviolet lamp and a functional test for each ultraviolet wavelength in one test chamber.

Description

Testing apparatus of UV lamp

The present invention relates to an ultraviolet lamp testing apparatus, and to an ultraviolet lamp testing apparatus that performs both a light emission test of an ultraviolet lamp and a functional test for each ultraviolet wavelength in one test chamber.

In general, ultraviolet ray lamps are largely classified into UV-A, UV-B, and UV-C depending on the wavelength of the emitted light.

Among them, UV-A has a wavelength of 320 to 400 nm and is used for suntan and insect attraction, and UV-B has a wavelength of 280 to 320 nm and is mainly used for medical purposes such as skin diseases or teeth whitening. UV-C is the shortest wavelength and is used for disinfection and sterilization purposes.

These ultraviolet lamps have properties that are harmful to the human body except for porphyrin reaction decomposition and sterilization in the about 405 nm band, and their use is limited. In addition, products that satisfy standardized regulations need to be distributed.

Nevertheless, since standard standard tests are performed only in several countries including the United States, most of them follow the manufacturer's own regulations, and there is a problem that the already prepared standard standard tests are also carried out in each test apparatus for each performance.

Korean Patent Registration No. 10-1949424 Republic of Korea Patent Publication No. 10-2004-0001116

The present invention is to solve the above-described problems, and provides an ultraviolet lamp test apparatus that performs both a light emission test of an ultraviolet lamp relative to power consumption and a functional test of a test object by irradiation by ultraviolet wavelength in one test chamber. I want to.

To this end, the present invention provides an ultraviolet lamp testing apparatus for testing the performance of an ultraviolet lamp, comprising: a test chamber having a darkroom so that light does not pass therethrough; A partition wall partitioning the dark room into a first test room and a second test room, and having a slit penetrating therethrough; A slit adjuster installed on the partition wall and configured to reciprocate to block or open the slit according to the size of the ultraviolet lamp to adjust the size of the slit; An ultraviolet sensor installed in the first test room and configured to test luminous efficiency by receiving ultraviolet rays emitted through the slit; A lamp jig installed in the second test room and in which the ultraviolet lamp corresponding to a performance test object is detachably assembled; A test object injector installed in the second test room and on which the test object is placed so as to test the effect of ultraviolet irradiation of the ultraviolet lamp; A lamp mover connected to the lamp jig and inserting the ultraviolet lamp into the slit and the test object injector, respectively; And a blocking shutter that is installed between the lamp jig and the test object injector inside the second test room, and blocks light from leaking to the test object injector while the ultraviolet lamp is testing luminous efficiency through the slit. It is characterized.

In this case, the test chambers are connected to each of the second test chambers, and a first storage chamber in which a test object against UV-A ultraviolet rays is stored; A second storage room in which the test object against UV-B ultraviolet rays is stored; And a third storage room in which the test object against UV-C ultraviolet rays is stored.

In addition, the slit adjuster includes an upper adjuster provided at an upper portion of the slit of the partition wall and a lower adjuster provided at a lower portion of the slit, wherein the upper adjuster and the lower adjuster are vertically drawn out or drawn in toward the slit, respectively. Ridepanwa; A guide for guiding the vertical reciprocation of the slide plate; A sliding driver for reciprocating the slide plate; And a controller for controlling the sliding driver according to the size value of the ultraviolet lamp.

In addition, it is preferable that the ultraviolet detector is a type of detector that receives all of UV-A, UV-B, and UV-C to test the luminous efficiency.

In addition, it is preferable that the ultraviolet sensor is installed on an imaginary axis coinciding with a center point in the height and width direction of the slit so as to face the slit.

In addition, the lamp jig is preferably a jig of a type that opens or closes in a set size with a grip portion in contact with the UV lamp so as to grip UV lamps of different sizes.

In addition, the test body injector includes a rotary table; At least one fixing table disposed on the rotation table, each of which the test object is seated; And a rotation driver connected to the center of rotation of the rotation table, and injecting the test object placed on the fixing table into a test position by rotating the rotation table.

In addition, it is preferable that the lamp mover is an articulated robot that moves the lamp jig equipped with the ultraviolet lamp to a direct upper part of the test object placed on the fixing table of the rotary table.

In addition, the blocking shutter may include a blackout blocking light between the lamp jig and the test object injector in the interior space of the second test room; A weight installed at the lower end of the blackout; And it is installed on the upper end of the black film, it is preferable to include; a winder for moving the black film up and down.

In addition, a first light quantity sensor installed in the space between the partition wall and the blocking shutter of the second test room; And a second light amount sensor installed in a space outside the blocking shutter of the second test room to detect the amount of leakage light at each location inside the second test room.

The present invention as described above divides the dark room inside the test chamber into a first test room and a second test room, and moves an ultraviolet lamp to a test position between them, so that a luminescence test and a functional test for each ultraviolet wavelength are successively performed. Therefore, multiple performance tests are all performed under the same conditions in one test chamber.

1 is a diagram showing a test chamber of an ultraviolet lamp testing apparatus according to the present invention.
2 is a block diagram showing an ultraviolet lamp testing apparatus according to the present invention.
3 is a front view showing the slit adjuster of the present invention.
4 is a front view showing the lamp jig of the present invention.
5 is a front view showing the test body injector of the present invention.
6 is a plan view showing the rotary table of the present invention.
7 is a diagram illustrating an operating state of the lamp mover according to the present invention.

Hereinafter, a UV lamp testing apparatus according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, the ultraviolet lamp testing apparatus 100 according to the present invention performs a test on the ultraviolet lamp in the test chamber 110 in which a dark room is formed to block the inflow of light corresponding to noise from the outside. Done.

The performance test of an ultraviolet lamp largely includes a'luminescence test' that measures luminous efficiency versus power consumption and a'functional test' that tests the effect of ultraviolet irradiation. Functional tests include tanning, medical and sterilization/disinfection effects by wavelength band.

Specifically, UV-A has a wavelength of 320 to 400 nm and tests for attracting sunburn or insects depending on its use, and UV-B has a wavelength of 280 to 320 nm and performs medical tests such as skin diseases or teeth whitening, and UV-C Performs disinfection and sterilization tests with the shortest wavelength.

In addition, one side of the test chamber 110 includes a first storage room (SP1) to a third storage room (SP3) to store the test object for each wavelength band. The first storage room (SP1) to the third storage room (SP3) are installed connected to the test chamber 110, respectively, so that storage and test are interlocked.

For example, in the first storage room (SP1), UV-A is used to store tanning or insect-inducing specimens for wavelength testing, in the second storage room (SP2), medical-related test specimens are stored, and in the third storage room (SP3), a culture dish, etc. Sterilization or sterilization test specimens are stored.

On the entrance side of the test chamber 110, the entrance side of each of the first storage room (SP1) to the third storage room (SP3), and the entrance side between these storage rooms and the test chamber 110, an entrance (DR) for test preparation is installed, respectively. Each doorway (DR) is closed during the test to maintain the darkroom.

As shown in Figure 2, the present invention is a partition wall 120 installed in the dark room in the above-described test chamber 110, the slit regulator 130, the ultraviolet sensor 140, the lamp jig 150, the test body injector 160, A lamp mover 170, a blocking shutter 180, a first light amount sensor 191, and a second light amount sensor 192 are included.

In addition, although not shown, as components basically necessary for the performance test, a controller, a DB for recording the test results, and a management server providing the test progress status may be further included, and the controller may be integrally mounted on the management server. .

At this time, the test chamber 110 has a dark room so that light does not pass therein. The darkroom is constructed by painting the interior wall in black, covering the blackout, or assembling a black plate into a chamber shape.

The test chamber 110 is divided into a first test room 110-1 and a second test room 110-2 by a partition wall 120. An ultraviolet sensor 140 is installed in the first test room 110-1, and a lamp jig 150 and a lamp mover 170 are installed in the second test room 110-2.

In addition, a test sample inserter 160 is installed at one side of the second test chamber 110-2, and a blocking shutter 180 blocks light leakage between the two sides between the lamp jig 150 and the test object inserter 160. For example, through the slit 121, light is prevented from leaking to the test object injector 160 waiting for the functional test during the light emission test.

Accordingly, the test chamber 110 is configured in a long housing shape to secure a space required for the test in the dark room therein, and the first storage room SP1 to the third storage room SP3 are on one side of each side. Is connected to

The first storage room (SP1) to the third storage room (SP3) may store UV-A, UV-B and UV-C subjects as an embodiment, and the first storage room (SP1) to the third storage room (SP3) Each can maintain the required temperature, humidity and pressure.

In addition, a table or a storage box TA for storage is provided in the first storage room SP1 to the third storage room SP3, so that the test object used for the functional test of the ultraviolet lamp LP can be stored.

The partition wall 120 divides the dark room in the test chamber 110 into a first test room 110-1 and a second test room 110-2. When partitioning, the partition wall 120 is installed so that light generated during the test in one room does not undesirably leak to another room.

As an embodiment, the partition wall 120 has a set thickness, and the surface is painted black, a black cloth or pad is attached, or a wall made of black material is applied to itself, and the entire test room is covered except for the slit 121. Block and divide

In the first test room 110-1, a luminescence test is performed to check the luminous efficiency of the ultraviolet lamp LP against power consumption, and in the second test room 110-2, a functional test for each band of the ultraviolet lamp LP is performed. Done.

At this time, the ultraviolet lamp LP is installed in the second test chamber 110-2. Accordingly, a slit 121 is formed through the partition wall 120 so as to receive light from the light receiving unit of the ultraviolet sensor 140 installed in the first test chamber 110-1. The slit 121 is set larger than the emission area of the ultraviolet lamp LP to be inspected.

The slit adjuster 130 is installed on the partition wall 120 and moves reciprocally to block or open the slit 121 according to the size of the ultraviolet lamp LP to adjust the size of the slit 121 and use the straightness of light. It makes it possible to provide an optimal measurement environment.

When the ultraviolet sensor 140 of the first test room 110-1 looks at the ultraviolet lamp LP, the slit ( 121) must match the size of the light emitting surface of the ultraviolet lamp (LP) or be somewhat larger.

The standard standard test target ultraviolet lamp (LP) is limited to within a predetermined maximum size, but within that limit, the size of the slit 121 needs to be adjusted according to the ultraviolet lamp (LP) because the ultraviolet lamp (LP) can have various sizes. There is.

During adjustment, the height of the slit 121 is adjusted to have a margin of 1 to 2 cm above and below the light emitting surface of the ultraviolet lamp LP, and the width of the slit 121 is adjusted to the left and right sides of the light emitting surface of the ultraviolet lamp LP, respectively. It can be adjusted to have a margin of 2~3cm.

Therefore, the light (noise) reflected from the rear of the ultraviolet lamp (LP), from the floor or ceiling, etc., is blocked from leaking to the first laboratory (110-1), but passes through the slit (121) after being emitted from the ultraviolet lamp (LP). Only one light is received by the ultraviolet sensor 140.

To this end, the slit adjuster 130 includes an upper adjuster and a lower adjuster respectively at the upper and lower portions of the slit 121 of the partition wall 120. If necessary, a left adjuster and a right adjuster may be included in a state in which the maximum width is secured according to the ultraviolet lamp LP.

In addition, the slit adjuster 130 is installed on the front or rear of the partition wall 120 to open and close the opening of the slit 121, but as shown, the slit 121 inside the partition wall 120 having a predetermined thickness. It can be installed to be drawn in or withdrawn toward.

In an embodiment, each slit adjuster 130 is a slide plate 131 vertically drawn out or drawn in toward the slit 121, a moving guide 132 and a slide plate guiding the vertical reciprocation of the slide plate 131 It includes a sliding driver 133 for reciprocating movement (131). In addition, it may include a controller (not shown) that controls the sliding driver 133 according to the size of the ultraviolet lamp LP mounted for the test.

At this time, while the upper and lower controllers are in operation, it is desirable to wait for the operation of the left and right controllers to prevent collisions. In some cases, there is a slight gap between the left and up and down controllers or between the right and up and down controllers. There may be, but even in this case, there is an effect according to the adjustment of the slit 121.

The ultraviolet detector 140 is for inspecting the luminous efficiency of the ultraviolet lamp LP, and is installed in the first test chamber 110-1 partitioned by the partition wall 120. Therefore, the luminous efficiency is tested by receiving the ultraviolet rays emitted through the slit 121.

These ultraviolet detectors 140 are installed spaced apart from each other by a predetermined distance or more based on the partition wall 120. The separation distance may vary according to the standard specification of the ultraviolet lamp (LP) to be tested, and is installed at a distance of 3 to 4m on average.

In addition, the ultraviolet sensor 140 is preferably installed on a virtual axis (C-L) coinciding with the center point of the height and width direction of the slit 121 so as to look at the slit 121. Through this, the light-receiving unit of the ultraviolet sensor 140 faces the center of the ultraviolet lamp LP.

The UV detector 140 is preferably a type of detector that tests luminous efficiency for all of UV-A, UV-B, and UV-C for each wavelength band. To this end, it may be applied that the ultraviolet detector 140 has sensing sensitivity in both A/B/C bands.

With water, each of the A/B/C type UV detectors 140 are separately placed on standby and then sequentially injected as needed, or a cut-off filter may be installed in front of the detector to selectively detect the UV rays.

The lamp jig 150 is installed in the second test room 110-2, and the ultraviolet lamp LP, which is a performance test object, is detachably assembled. Accordingly, the lamp jig 150 is also disposed in the second test chamber 110-2 together with the ultraviolet lamp LP, and the ultraviolet lamp LP is exposed to the first test chamber 110-1 through the slit 121. .

At this time, the lamp jig 150 is preferably a jig of a type in which the grip unit 151 in contact with the ultraviolet lamp LP opens or closes to a set size so as to grip the ultraviolet lamps LP of different sizes. .

The lamp jig 150 is provided with a shock-proof pad on the grip part 151, and as the pair of grip parts 151 are fixed after being moved in the front and rear directions, respectively, according to the size of the UV lamp LP, the UV lamp to be tested ( LP) can be stably fixed.

The UV lamp LP gripped by the lamp jig 150 faces the center of the slit 121, and the slit adjuster 130 is the height of the slit 121 and/or according to the size of the light emitting surface of the UV lamp LP. The reflected light is blocked by adjusting the width.

However, it is preferable to further include a light emission guide 152 protruding and extending so as to surround the ultraviolet lamp LP outside the grip part 151 of the lamp jig 150.

The light emission guide 152 is configured in the shape of a waveguide, and guides the light (ultraviolet) to be emitted only to the test object when it is placed on the test object supplied through the test object injector 160 to be described later.

The test object injector 160 injects the test object for functional tests such as tanning, medical treatment, and sterilization by an ultraviolet lamp (LP) after or before the luminescence test is completed. The test object is selected for each wavelength band of the ultraviolet lamp (LP) to be tested.

As shown in FIG. 5, the test object injector 160 includes a rotary table 161 and at least one fixing table 162 and a rotary table 161 on which the test object is seated, each of which is disposed on the rotary table 161. It includes a rotation driver 163 to rotate. In addition, if necessary, it may further include an elevator 164 for elevating the above components.

The rotary table 161 is preferably made of a disk shape.

The fixing table 162 is disposed on the upper surface of the rotary table 161 at regular intervals along the circumferential direction. The fixing table 162 may be provided with a groove or a jig in which the test object is seated at an inner center based on the protruding outer rim.

In addition, the fixing table 162 has a plurality (162-1, 162-2, 162-) to store the test object for each ultraviolet wavelength band (UV-A/B/C) or to perform multiple tests for the same wavelength band. 3) Can be provided.

The rotation driver 163 is connected to the rotation center of the bottom surface of the rotation table 161. For example, the rotation driver 163 is an electric motor, and the rotation shaft of the electric motor is connected to the center of the bottom of the rotation table 161.

Therefore, by rotating the rotary table 161, the test object placed on the fixing table 162 is put into the test position. The test position is a position rotated toward the lamp jig 150, and in that state, a functional test is performed by bringing the ultraviolet lamp LP fixed to the lamp jig 150 close to each other.

As shown in FIG. 6, during the test of the same wavelength band for the function test, different target objects to be compared are placed on the fixing table 162 on the rotary table 161, respectively, or the test objects for testing of different wavelength bands are respectively placed. You can raise it and let the test proceed with one stop.

The lamp mover 170 is connected to the lamp jig 150 and inserts the ultraviolet lamp LP into the slit 121 and the test object injector 160, respectively. The lamp mover 170 is connected to one side of the lamp jig 150. For example, it is connected to the bottom or the rear so as not to block the light emission of the ultraviolet lamp LP.

As shown in FIG. 7, the lamp mover 170 moves the lamp jig 150 equipped with an ultraviolet lamp (LP) to the directly upper part of the test object placed on the fixing table 162 of the rotary table 161. It is preferable that it is a 3-axis driven articulated robot.

That is, the lamp mover 170 allows the light emitting surface of the ultraviolet lamp LP to face the slit 121 or rotate to the opposite side to face the opposite side. After that, the ultraviolet lamp (LP) is rotated to face the upper surface of the test object injector 160 through the bending rotation of the joint.

At this time, the ultraviolet lamp (LP) is positioned directly above the test object placed on the test object injector 160 at regular intervals, or the light emitting guide 132 is in close contact with the rim of the fixing table 162 to only the selected fixing table 162. Light can be irradiated only on the placed test object.

As described above, the light emission guide 132 is provided with the lamp jig 150 and may have a tubular shape (waveguide) surrounding the gripped ultraviolet lamp LP. Materials can be used.

The blocking shutter 180 prevents the case of light leakage through the slit 121 to the test object placed on the test object injector 160 during the test of the luminous efficiency through the slit 121 to be irradiated with ultraviolet rays in advance or vice versa before the functional test.

To this end, the blocking shutter 180 is installed between the lamp jig 150 and the test object injector 160 inside the second test room 110-2, and blocks light (ultraviolet rays) so that light does not leak between them. .

In an embodiment, the blocking shutter 180 includes a blackout 181 blocking light between the lamp jig 150 and the test object injector 160 in the interior space of the second test room 110-2, and the lower end of the blackout 181. It includes a weight 182 installed in and a take-up machine 183 installed on the upper end of the black film 181, and moves the black film 181 up and down.

The black film 181 may be made of a cloth material to facilitate winding, and the weight 182 is provided at the lower end of the black film 181 to prevent shaking of the black film 181 as it is in close contact with the floor surface by the load.

The take-up machine 183 includes a take-up drum and a take-up motor to loosen and descend the dark film 181. Therefore, during the inspection of the luminous efficiency of the ultraviolet lamp LP through the slit 121, the ultraviolet rays do not reach the test object in the functional test in advance.

On the other hand, when the blackout film 181 is rolled up with the take-up machine 183, the lamp mover 170 can provide a passage for moving the ultraviolet lamp LP gripped by the lamp jig 150 to the test object input unit 160. .

At this time, since the luminous efficiency test through the slit 121 is completed or stopped, temporarily turning off the ultraviolet lamp LP does not affect the test. In addition, the slit 121 may be completely closed through the slit adjuster 130.

However, in FIG. 2, although the winder 183 is installed on the outer upper surface of the test chamber 110 as an example, the winder 183 is also installed on the inner ceiling surface of the test chamber 110. Light leakage into the test chamber 110 can be prevented by excluding a leakage portion for connection with the 181 at the source.

Meanwhile, the first light intensity sensor 191 detects light emission or leakage in the area where the light emission test is performed in the second test room 110-2, and the second light intensity sensor 192 detects light in the area where the function test is performed. It detects light emission or leakage.

To this end, the first light quantity sensor 191 is installed at a position where the UV lamp LP and the lamp jig 150 on one side are installed based on the blocking shutter 180, and the second light quantity sensor 192 is the test body input unit 160 ) Is installed in the installed location.

That is, the first light amount sensor 191 is installed in the space between the partition wall 120 and the blocking shutter 180 of the second test room 110-2, and the second light amount sensor 192 is installed in the second test room 110- 2) It is installed in the space outside the middle blocking shutter 180.

Accordingly, it is possible to check whether a light emission test is in progress in the first test room 110-1 or whether there is leakage from the second test room 110-2 by the first light sensor 191. In addition, it is possible to check whether a functional test is in progress in the second test room 110-2 or whether there is a leakage from the first test room 110-1 with the second light sensor 192.

In the above, specific embodiments of the present invention have been described above. However, the spirit and scope of the present invention are not limited to these specific embodiments, but various modifications and variations are possible within the scope of not changing the gist of the present invention. You will understand when you grow up.

Therefore, the embodiments described above are provided to completely inform the scope of the invention to those of ordinary skill in the technical field to which the present invention belongs, and should be understood as illustrative and non-limiting in all respects, The invention is only defined by the scope of the claims.

110: test chamber
120: compartment wall
121: slit
130: slit adjuster
140: UV detector
150: lamp jig
160: test body injector
170: lamp mover
180: blocking shutter
191: first light quantity sensor
192: second light intensity sensor

Claims (10)

In the ultraviolet lamp test apparatus for testing the performance of an ultraviolet lamp (LP),
A test chamber 110 having a darkroom so that light does not pass therethrough;
A partition wall 120 that divides the dark room into a first test room 110-1 and a second test room 110-2, and has a slit 121 having a size set to pass ultraviolet rays through;
The slit 121 is installed on the partition wall 120 and moves the slide plate 131 reciprocally to close or open the slit 121 with a sliding actuator 133 according to the size of the ultraviolet lamp LP. A slit adjuster 130 for adjusting the size of the opening;
It is installed at a certain height from the bottom of the first test room 110-1, and after being emitted from the ultraviolet lamp LP mounted in the second test room 110-2, the ultraviolet rays passing through the slit 121 are An ultraviolet sensor 140 having a light-receiving part for receiving light and testing the luminous efficiency of the ultraviolet lamp LP;
A lamp jig 150 installed in the second test room 110-2 and to which the ultraviolet lamp LP is detachably assembled;
A table provided spaced apart from the lamp jig 150 in the second test room 110-2 and on which the test object is placed so as to test the effect of the ultraviolet rays emitted from the ultraviolet lamp LP on the test object A test body injector 160 having 161;
Includes an articulated robot connected to the lamp jig 150 on which the ultraviolet lamp (LP) is mounted, and moves the ultraviolet lamp (LP) to face the slit 121 during a light emission test, or a functional test A lamp mover 170 for moving the ultraviolet lamp LP so as to face the test object placed on the table 161; And
In the second test room (110-2), a blackout film 181 is provided between the lamp mover 170 and the test object injector 160 to partition the space, and the blackout film 181 is unfolded during the light emission test. And a blocking shutter 180 that blocks the ultraviolet rays emitted from the ultraviolet lamp (LP) from reaching the test object placed on the table (161). The method of claim 1,
The test chamber 110,
A first storage room (SP1) in which a test object against UV-A ultraviolet rays is stored;
A second storage room (SP2) in which the test object against UV-B ultraviolet rays is stored; And
Further including; a third storage room (SP3) in which the test object against UV-C ultraviolet rays is stored,
The first storage room (SP1), the second storage room (SP2), and the third storage room (SP3) are installed connected to different directions of the second test room (110-2) through the entrance (DR), respectively, the first Ultraviolet lamp testing apparatus, characterized in that it is possible to move the test objects stored in the storage room (SP1), the second storage room (SP2) and the third storage room (SP3) to the second test room (110-2). The method of claim 1,
The slit adjuster 130,
Including an upper adjuster provided on the upper portion of the slit 121 of the partition wall 120 and a lower adjuster provided under the slit 121,
The upper adjuster and the lower adjuster, respectively,
A slide plate 131 vertically drawn out or drawn in toward the slit 121;
A moving guide 132 for guiding the vertical reciprocation of the slide plate 131;
A sliding driver 133 for reciprocating the slide plate 131; And
And a controller for controlling the sliding driver 133 according to the size value of the ultraviolet lamp LP. The method of claim 1,
The ultraviolet sensor 140,
Ultraviolet lamp testing apparatus, characterized in that it is a type of detector that tests the luminous efficiency by receiving all of UV-A, UV-B and UV-C. The method of claim 4,
The ultraviolet sensor 140,
Ultraviolet lamp testing apparatus, characterized in that it is installed on a virtual axis (C_L) coinciding with the center point of the height and width direction of the slit 121 so as to face the slit 121. The method of claim 1,
The lamp jig 150,
An ultraviolet lamp testing apparatus, characterized in that the grip part 151 in contact with the ultraviolet lamp LP is a jig of a type that opens or closes to a set size so as to grip the ultraviolet lamps LP of different sizes. The method of claim 1,
The test body injector 160,
A rotary table 161;
At least one fixing table (162) disposed on the rotation table (161), each of which the test object is seated; And
And a rotation driver 163 connected to the rotation center of the rotation table 161 and for rotating the rotation table 161 to insert the test object placed on the fixing table 162 into a test position. Lamp testing device. The method of claim 7,
The lamp mover 170,
An ultraviolet lamp testing apparatus, characterized in that it is an articulated robot that moves the lamp jig 150 on which the ultraviolet lamp (LP) is mounted to the direct upper part of the test object placed on the fixing table 162 of the rotary table 161. The method of claim 1,
The blocking shutter 180,
A blackout film 181 blocking light between the lamp jig 150 and the test object injector 160 in the inner space of the second test room 110-2;
A weight 182 installed at the lower end of the blackout 181; And
An ultraviolet lamp testing apparatus comprising: a winder 183 installed on the upper end of the blackout 181 and moving the blackout 181 up and down. The method of claim 1,
A first light quantity sensor 191 installed in the space between the partition wall 120 and the blocking shutter 180 of the second test room 110-2; And
Further comprising a second light amount sensor 192 installed in a space outside the blocking shutter 180 of the second test room 110-2,
Ultraviolet lamp testing apparatus, characterized in that detecting the amount of light leakage at each location inside the second test chamber (110-2).

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