KR101154123B1 - Line-scan lighting equipment - Google Patents

Abstract

PURPOSE: A line scan lighting device is provided to obtain uniform illuminance by supplying currents to the central, left, and right sides of a bus bar. CONSTITUTION: A back light housing(100) includes a camera and a lighting device. A PCB(130) is installed on the upper side of the back light housing. An LED lamp(131) is mounted on the PCB. A cover(200) covers the upper side of the back light housing. A power supply unit(150) supplies power to the PCB.

Description

LINE SCAN LIGHTING EQUIPMENT {LINE-SCAN LIGHTING EQUIPMENT}

The present invention relates to a line scan lighting device capable of securing a homogeneous uniformity and securing heat dissipation of high efficiency by changing the structure of the lighting applied to the line scanning device by implementing high brightness and smooth supply of power, and specifically, After forming grooves on both sides of the upper surface of the backlight housing and inserting a bus bar (BUS BAR) made of copper, the bus bar (BUS BAR) is used by soldering the PCB where the LEDs are arranged and the above-described bus bar. It is possible to supply high current uniformly to the PCB board side, but uniform current is supplied to the center part of the bus bar and the left and right sides of the arranged bus bar, so that the illuminance of each LED mounted on the PCB board can be made uniform and high brightness. The accuracy of the subject under test can be ensured by ensuring high quality images in the camera which can be located on the upper side of the line scan illumination device. It relates to a line scanning to scan the illumination device is possible.

As one of the methods for inspecting each substrate, light guide plate, glass plate, etc. applied to a display panel using an LCD or LED, the camera is photographed using the camera, and then the photographed image is examined. It is well known that techniques for determining whether a subject is defective are being implemented in various fields and parts.

The subject may be a flat panel display panel, a glass plate, or the like as described above, and the presence or absence of defects such as stains or scratches of the subject is detected through imaging.

As described above, an apparatus for inspecting a subject includes a lighting apparatus for projecting a subject, a camera for photographing an image produced by light transmitted after the light emitted from the apparatus passes through the subject, and the It may be configured as a control unit including a reading unit for receiving the image data picked up from the camera, to read the presence or absence of defects.

In the above configuration, the inspection accuracy of the subject may vary according to the irradiation efficiency of the lighting apparatus that transmits light to the subject, for example, uniformity in the power supply unit supplying power to the LED light source provided in the lighting apparatus. Whether or not to secure a high brightness and homogeneity of the light irradiated from the LED light source can be determined by the supply of a current.

Conventionally, the lighting device 1 having the LED light source includes a plurality of PCB substrates 130 on which the LED lamps 131 are mounted, arranged in a straight line, for supplying power to each PCB substrate 130. The power line was connected using a cable 2 (see FIG. 1).

Such a power supply method is referred to as a cable jumper connection method, so that the soldering (soldering) connection to the both sides of each PCB substrate 130 from the cable (2) connected from the main power supply to be configured sequentially.

In order to solder and connect the cable 2 for supplying the power supplied from the main power supply to the PCB board 130 and the PCB board 130, the cover of the cable 2 is peeled off and then the PCB board 130 is contacted. In the complicated process of soldering the part and the heating of the LED lamp 131, the covering part of the cable 2 has been damaged.

In addition, since the diameter of the cable 2 should be increased in order to increase the amount of power supplied through the cable 2, there is a problem that the size of the lighting device as a whole becomes large.

In addition, the current alternately energizes the cable 2 and the PCB substrate 130, so that a large current may not be supplied as the resistance value gradually increases, and due to an uneven current supply of the LED lamp 131 Since the illuminance difference is caused, the illuminance difference of the light passing through the subject is different for each region, and the imaging data of the camera has no choice but to receive inaccurate data. Therefore, the inspection result of the subject becomes unreliable. There is this.

Accordingly, the present invention is to solve the above problems, to form a groove long on both sides of the upper side of the backlight housing for supplying power to the backlight illumination device for the line scan, the copper bus bar (Bus-) as the groove After inserting the bar), the bus-bar and the LED lamp are soldered to the mounted PCB substrate, so that a large current supply is uniformly supplied over the entire PCB substrate so that the uniformity of the irradiation brightness irradiated from the LED lamp is achieved. The purpose of the present invention is to maintain the high brightness and to improve the accuracy of test results.

In addition, the present invention enables the design of the bus bar and the design of the groove corresponding thereto for the effective current supply required according to the number and overall length of the LEDs mounted on the PCB substrate, so that the backlight housing Another purpose is to ensure that the overall length does not increase.

The present invention for solving the above problems,

In order to inspect the surface of the subject, a backlight housing 100 that forms a camera and an illumination device is provided, and a plurality of PCB substrates 130 on which an LED lamp 131 is mounted are installed on an upper surface side of the backlight housing 100. In the line scan illumination device having a cover 200 for covering and fixing the top of the backlight housing 100, and having a power supply unit 150 for supplying power to the PCB substrate 130,

After forming the grooves 110 on both sides of the upper surface of the backlight housing 100 and inserting a bus bar 120 made of copper, the LED lamps 131 are mounted and arranged on each PCB substrate ( 130 and the bus bar BUS BAR are configured to allow uniform high current supply to the PCB substrate 130, and a power line 151 connected to one surface of the backlight housing is connected to the power supply 150. And a cable 10 branched from the terminal unit 170 is disposed through the guide groove 180 extending to one surface of the backlight housing and guided upwardly at an end side to form the backlight housing 100. The upper side hole 101 is connected to both side bus bar (BUS BAR) 120 and soldered, and a plurality of heat dissipation holes 140 are formed along the longitudinal direction of the backlight housing 100 to form the backlight housing 100. Equipped on one side It provides the line scan the illumination device, characterized in that for forming such heat exchange by the air blowing fan 160.

According to the present invention, the bus bar (Bus-Bar) made of copper material is inserted into the groove formed on the upper surface of the backlight housing in order to supply power to the backlight illumination device for the line scan, the bus bar (Bus-Bar) Power supply by soldering connection between PCB and each PCB board, it is possible to supply power of uniformly large current to the whole PCB board, and uniformly high brightness of light irradiated from LED lamp to irradiate the object Since it is possible to maintain a uniform homogeneity, it is possible to expect the effect of increasing the accuracy of the test results due to the accurate information transfer of the imaging data obtained from the camera.

In addition, the present invention, since a uniform current is supplied to the center portion and the left and right sides of the bus bar (BUS BAR) arranged to enable a uniform large current supply to the PCB substrate side, the illumination of each LED lamp mounted on the PCB substrate is uniform, High brightness can be achieved while consistently satisfying the homogeneous conditions, so that a high-quality image can be secured to a camera that can be positioned on the upper side of the line scan illumination device, and thus an accurate inspection of the inspected object can be expected. .

In addition, the present invention, even if the power consumption is increased, such as the design of a long PCB substrate arrangement, there is no change in the size of the width of the overall backlight housing, with the effect of obtaining a backlight housing having a smart and simple width without changing the overall size Therefore, the effect of enabling a considerable power supply even in the same sized backlight housing can be expected.

1 and 2 are views showing an example applied to the conventional line scan illumination device
Figure 3 is a schematic plan view of the line scan illumination device in the state the present invention is applied
Figure 4 is a perspective view of the form showing a separate configuration of the present invention
5 is a perspective view showing a state in which the combined configuration of Figure 4 combined

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

As described above, the present invention provides a line scan lighting apparatus capable of securing a uniform homogeneity and securing high efficiency heat dissipation due to high brightness and smooth supply of power by changing the structure of lighting applied to the line scanning apparatus.

To this end, in the line scan illumination device, grooves 110 are formed on both sides of the top surface of the backlight housing 100, and a bus bar 120 having a copper material is inserted, and then an LED lamp 131 is mounted. Each of the PCB substrate 130 and the bus bar 120 that are processed and arranged are soldered to configure a uniform high current supply to the PCB substrate 130, and before and after the backlight housing 100. Each of the heat radiation holes 140 are formed on the surface.

As shown in FIG. 4, the backlight housing 100 generally has a rectangular box shape, and each PCB substrate 130 on which an LED lamp 131 is mounted is provided at an upper side of the backlight housing 100. The guide groove 180 is formed to extend in the longitudinal direction to one surface of the cover groove, and includes a cover 190 covering the guide groove 180, and the cable 10 is positioned toward the guide groove 180 to provide a backlight housing. After flowing into the inside (100) and flowed out through the long hole 101 of the upper side was to be connected to the bus-bar 120 in each direction.

In addition, one set of the blower fan 160 is spaced apart from one surface of the backlight housing 100, that is, the center proper portion of one surface side where the guide groove 180 is provided as shown in the drawing, and is connected from the power supply unit 150 therebetween. The power line 151 is connected, but the power line is coupled to the terminal unit 170 so as to be connected to the cable 10.

In addition, the groove 110 is formed to extend in the longitudinal direction to both inner sides of the top of the backlight housing 100.

Bus-bars 120 are respectively inserted into and fixed to the grooves 110, and each PCB substrate 130 is soldered to each other from the side of the bus-bar 120.

Here, the power consumption amount varies depending on the length of the PCB substrate 130 and the size or number of the LED lamps 131 to be mounted. In view of this, the height of the bus bar 120 may vary, The groove 110 preferably has a depth corresponding thereto.

Therefore, the thickness of the cable is increased according to the length of the PCB substrate 130 and the size or number of the LED lamps 131 to be mounted as in the prior art, resulting in the inconvenience of requiring a backlight housing 100 having a larger size. The problems caused by the increase in the size of the ship and equipment can be solved.

On the other hand, the power line 151 connected from the power supply unit 150 is bound to the terminal unit 170 and then branched to the cable 10 arranged along the guide groove 180 on both sides, the bus-bar ( One end of the Bus-Bar 120 and the cable 10 are connected.

Therefore, the current supplied from the power supply unit 150 through the bus-bar (120) (Bus-Bar) (120), the uniform current as a whole through the connection portion soldered to each PCB substrate 130 side as described above To be energized.

That is, since the current charged through the bus-bar is always energized with a uniform current, the same current flow is supplied to each PCB substrate 130 through the bus-bar. Illumination of light emitted from the LED lamp 131 mounted on the PCB substrate 130 may be irradiated with uniform illumination over the entire length of the backlight housing 100.

The light irradiated by the uniform illuminance is projected on the subject to be supplied, and then the image is captured by the camera located at the other side, and the obtained data is transmitted to the control unit (not shown). May be calculated and displayed through a separate display unit.

Therefore, since light with uniform illuminance is projected over the entire subject, accuracy of the test result of the subject is satisfactory.

Meanwhile, as described above, the bus bar 120 is inserted into the grooves 110 formed on the left and right sides of the top surface of the backlight housing 100 to be soldered and connected to the PCB substrate 130. The LED lamp 131 can suppress the occurrence of coating and oxidation caused by heat generation.

In addition, the cable 10 for supplying power to one end of the bus bar 120 from the power supply unit 150 accommodated inside the backlight housing 100 is formed only to one end of the bus bar 120. Therefore, the space utilization inside the backlight housing 100 is increased, thereby reducing the overall size of the backlight housing 100 significantly.

When the light is irradiated through the LED lamp 131 provided on the upper side of the backlight housing 100, the temperature is increased by the amount of heat generated, so as shown in Figure 4 has a blow fan 160 on one surface The outside air supplied by the blower fan 160 is introduced into the backlight housing 100 to be discharged through the heat dissipation hole 140 formed long along the longitudinal direction, so that heat exchange is performed.

Reference numeral 200 is a cover to cover the upper side of the backlight housing 100. The upper surface of the cover 200 is made of a glass material so that the light emitted from the LED lamp 131 can be transmitted.

A line scan illumination device corresponding to one of the line scan devices when inspecting the supplied object by using a line scan device when a subject (not shown in the drawing) is supplied using the present invention having the above-described configuration. When the power is supplied to the backlight housing 100 at the same time and the power supply unit 150 for the control (ON), the current from the power supply unit 150 is formed on the upper surface of both sides of the top of the backlight housing 100 ( A uniform current is energized to the bus bar (Bus-Bar) disposed through the 110 and to each PCB substrate 130 that is soldered and connected to each other.

The same LED lamps 131 are mounted on the PCB substrates 130, respectively, and two rows of the same LED lamps 131 are disposed in the backlight housing 100 in the longitudinal direction as shown in FIG. 4.

Meanwhile, as described above, since the current supplied through the bus-bar supplies a uniform current to the entire PCB substrate 130, the illumination of the LED lamp 131 of each PCB substrate 130 is also overall. It has uniform illuminance and examines the subject side.

According to the light refraction and transmittance of the LED lamp 131 irradiated to the subject as described above to obtain the image by imaging the light transmitted to the camera (not shown) existing on the side opposite to the backlight housing 100, the control unit The operation is processed through the operator to display the test results of the subject through a separate display unit, so that the operator can determine whether the subject passed.

Therefore, the inspected object is inspected by high brightness irradiation with uniform illuminance, thereby obtaining an accurate captured image and increasing inspection accuracy, thereby obtaining a relatively accurate inspection result regardless of the operator's skill in the work. Even if the heat generation phenomenon of the LED lamp 131 installed in the backlight housing 100 occurs, the bus bar 120 is not damaged or oxidized, and the service life of the overall internal structure of the backlight housing 100 is remarkable. Will rise.

10; cable
100; Backlight housing 101; Longevity
110; Groove 120; Bus-bar
130; PCB substrate 131; LED lamp
140; Heat sink 150; Power supply
151; Power line 160; Air blowing
170; Terminal portion 180; Guide groove
190; cover

Claims (1)

In order to inspect the surface of the subject, a backlight housing 100 that forms a camera and an illumination device is provided, and a plurality of PCB substrates 130 on which an LED lamp 131 is mounted are installed on an upper surface side of the backlight housing 100. In the line scan illumination device having a cover 200 for covering and fixing the top of the backlight housing 100, and having a power supply unit 150 for supplying power to the PCB substrate 130,
After forming the grooves 110 on both sides of the upper surface of the backlight housing 100 and inserting a bus bar 120 made of copper, the LED lamps 131 are mounted and arranged on each PCB substrate ( 130 and the bus bar BUS BAR are configured to allow uniform high current supply to the PCB substrate 130, and a power line 151 connected to one surface of the backlight housing is connected to the power supply 150. And a cable 10 branched from the terminal unit 170 is disposed through the guide groove 180 extending to one surface of the backlight housing and guided upwardly at an end side to form the backlight housing 100. The upper side hole 101 is connected to both side bus bar (BUS BAR) 120 and soldered, and a plurality of heat dissipation holes 140 are formed along the longitudinal direction of the backlight housing 100 to form the backlight housing 100. Equipped on one side Line scanning the illumination device, characterized in that for forming such heat exchange by the air blowing fan 160.

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