RU2087039C1 - Assembly of information board screen - Google Patents

Abstract

FIELD: electronic equipment. SUBSTANCE: device has substrate with copper-nickel wiring and light emitting crystals. Printed circuit is covered with multiple-lens cover which is made from color or colorless plastic. Surface of cover between lenses is covered with contrast-making cover. Device provides color or black-white illumination, is suited for seamless joints and may be used in design of information boards such as running headers or screens. EFFECT: increased efficiency, increased reliability. 7 cl, 5 dwg

Description

 The invention relates to electronic equipment, in particular, to a display module of a bulletin board and may find application in semiconductor technology in the design and manufacture of screen modules with high ergonomic characteristics and reliability.

 Increasing information content in public places is currently achieved with the help of information boards such as creeping lines and screens, performed, as a rule, using gas discharge elements and incandescent lamps. However, such information boards have low reliability and durability. The creation of information boards using discrete LEDs poses the problem of switching them into a single system, controlling it, and selecting LEDs for different brightness and maintainability of such systems. In addition, such information displays have low ergonomic characteristics. The most promising for creating information boards are monolithic semiconductor screen modules.

 A known module of the screen information board containing crystals of light emitters located in the spherical recesses of the substrate with a circuit of which is located above the corresponding crystal of the light emitter [1] The disadvantage of this solution is the possibility of mutual illumination of the elements of the screen module, as well as a small viewing angle, determined by the distance of the crystals of light emitters from the lenses of the cap. Another technical solution [2] describes a screen module containing crystals of light emitters on a substrate, a monolithic flat cover with light guides and complex lenses facing the light emitter crystals, intended for use as display screens. Its disadvantage is the small viewing angle, which is determined by the constructive construction and features of the lens construction form.

 The closest technical solution to the invention is the information board screen module containing a substrate with a wiring diagram, connecting leads connected to a wiring diagram, crystals of light emitters in their places of installation on a wiring diagram and connected by conductors to the corresponding buses of the wiring diagram, a cover with rails pins, an array of optical fibers between the substrate and the lid, lenses made of optically transparent plastic embedded in the lid and located above the radiation crystals light bodies. The substrate has positioning holes for the guide pins of the cover [3] The disadvantage of such a module of the information display screen is low tightness, difficulty in assembly, a sufficiently large thickness and the absence of seamless docking with other modules, due to the design solution, as well as a low viewing angle and the inability to effectively mix colors with a multi-color version of the module due to the lack of dispersant in the lens material and the distance from them crystals of light emitters.

 The aim of the invention is to increase ergonomic characteristics and reliability by improving the design of the screen module.

 The goal is achieved by the fact that the lid is made in one piece with optical fibers and lenses of optically transparent plastic, into which up to 5% of the dispersant is introduced, on the front side of the lid there is a contrast-forming coating between the lenses, a groove filled with a sealing compound is made along the periphery of the back of the lid, and the distance between the lenses is twice the distance between the extreme lens and the proximal side face of the cover, while the height of the light guide (H) is selected from the ratio: 1.5 • h <H <4 • h, where h is the height of the crystals of the emitters eta.

 In addition, the goal is achieved by the fact that the tires and pads of the wiring diagram are made of copper with a nickel coating, while at the places of installation of the crystals of the light emitters, at least one recess of arbitrary shape is made in depth greater than the thickness of the nickel layer, the back side of the substrate is coated with copper-nickel a layer with the exception of the exit points of the connecting terminals, while in the places of the output of the connecting terminals and guide pins from the positional holes of the substrate, a sealant is applied on its back side the compound, and the crystals of the light emitters are fixed on the contact pads using conductive glue.

 In addition, the lenses are made truncated parallel to the side faces of the cover, normally to its front side at a distance exceeding 3/4 of the radius of the circle bounding the lenses from the front side of the cover; within the boundaries of each lens there are crystals of light emitters with different colors of the light flux; a dye is introduced into the optically transparent plastic, corresponding to the color of the light flux of the crystals of the light emitters; yellow dye is introduced into optically transparent plastic; conductive glue is applied to the joints of the conductors with the busbars and the connecting leads with the contact pads of the wiring diagram.

 In FIG. 1 is a cross-sectional side view of an information board screen module; in FIG. 2.3 the place of installation of the crystal of the light emitter in the case of a nickel coating on the entire surface of the wiring diagram; figure 4 is a side view of the 16-segment module screen information board; figure 5 is a plan view from the side of the cover of the 16-segment module of the screen of the information board.

 The side element of the screen module contains: a cover 1, lenses 2, a contrast-forming coating 3, a substrate with a wiring diagram 4, a connecting terminal 5, a sealing compound 6, a guide pin 7, a light guide 8, a nickel coating 9 on a copper layer 10 that form a conductive layer the bus, the installation site of the crystal of the light emitter 11, conductive adhesive 12, the crystal of the light emitter with the upper and lower ohmic contacts 13, a metal conductor 14, flaring of the guide pin 15, a nickel-copper coating 16.

 The installation location of the crystal of the light emitter comprises: a substrate 4, a nickel coating 9 on the copper layer 10, a conductive adhesive 12, a crystal of the light emitter 13, a metal conductor 14, the lower and upper ohmic contacts 16 and 17.

 The 16-segment information board screen module contains: a cover 1, lenses 2, a contrast-forming coating 3, a substrate with a wiring diagram 4, a connecting terminal 5, a sealing compound 6.

 The luminous intensity and color of the luminous elements of the modules of the screens of the information board are determined by the corresponding color of the covers, the type and number of crystals of the light emitters located under the lens of each element.

 Module screen information board works as follows.

 When applying to the connecting terminal 5 and the connecting terminal connected to the copper pad 11, on which the crystal of the light emitter 13 is mounted, a voltage that ensures current flow through the pn junction in the forward direction, the crystal of the light emitter 13 starts to emit light. The emitted light enters the area of the cover 1 with the lens 2 and is evenly scattered there by the dispersant, providing a uniformly luminous surface of the lens 2. In case of placement of crystals of light emitters 13 with different colors of emitted light on the substrate 4 under the lens 2, the dispersant in the volume of the lens 2 provides effective color mixing over the volume of the lens 22 and uniform illumination of the surface of the lens 2 of one of the mixed colors. Varying the color of the glow of the segment is carried out by changing the magnitudes of the currents flowing through the crystals of the light emitters 13 in the forward direction.

The invention improves the ergonomic characteristics and reliability of the display module of the information panel due to the monolithic construction of the cover 1 with lenses 2 and optical fibers 8, as well as the contrast-forming coating 3 on its front side between the lenses, since the image contrast between the luminous and non-luminous segments formed by the lenses 2 , against the background of the contrast-forming coating 3 provides a clear reading of information up to 160 ^o viewing angle. The addition of the dispersant cap material to 5%, as well as the limitation of the height of the optical fiber 8 with respect to the height of the crystals of light emitters 13, provides uniform illumination on the surface of the lenses 2. An increase in the percentage of dispersant above this value reduces the brightness of the luminous segments while maintaining the magnitude of the current flowing through the crystals of the light emitters 13. Exceeding the distance between the lenses 2 twice the distance between the extreme lens 2 and the side face of the cover 1 provides a seamless docking modes leu information display screen horizontally and vertically, which allows the formation of a bulletin board in the form of running lines and screens. The application of the sealing compound 6 in the groove of the lid 1 after it is docked with the substrate 4 having the same geometric dimensions, ensures the tightness of the structure, which prevents the degradation of the crystals of the light emitters 13, leading to a decrease in light intensity and the appearance of different brightness of the luminous segments.

 The substrate 4 with the wiring diagram on copper-nickel tires, with pads and places for installing crystals 11, is made in such a way that the copper-nickel coating occupies the maximum area within the boundaries of the lenses 2, with the exception of the gaps between the tires providing the wiring diagram.

 Since the reflection coefficient of the nickel coating exceeds this value for a copper coating, this ensures an increase in the light flux reflected from the substrate 4 and collected by the lenses 2. In addition, the presence of a nickel layer 9 on copper busbars 10 and contact pads provides a more reliable and high-quality microwelded connection of metal conductors 14. The absence of a nickel coating 9 at the installation sites of the crystals of light emitters 11 is due to the insufficient stability of the contact system: nickel - conductive adhesive, which leads to uncontrolled the increase in transition resistance, especially when exposed to elevated temperatures, which, ultimately, eliminates the possibility of the appearance of different brightness elements information board screen module. The copper-nickel coating on the back of the substrate 4 is an effective heat sink of the power emitted by the crystals of the light emitters 13, allows to reduce the different brightness of the luminous segments, all other things being equal and by increasing the current flowing through the crystals of the light emitters 13, to increase the luminous flux and the brightness of the luminous segments .

 The implementation of the substrate 4 with the wiring diagram on the front side and the heat sink on the back side in some cases does not provide complete switching of the wiring diagram, which requires the introduction of additional jumpers from metal conductors 14. The solution to this problem is the implementation of the substrate 4 with a two-sided wiring diagram and maximum metallization on the back side to ensure heat dissipation of the dissipated power of the crystals of the light emitters 13.

 The manufacture of substrates 4 with copper seats 11 for installing crystals of light emitters 13, with a nickel coating 9 on conductive buses 10, contact pads and places of attachment of metal conductors by local galvanic deposition of nickel is not always possible due to the topological requirements for the wiring diagram of the substrate 4. Formation of the scheme wiring after applying a continuous nickel coating 9 requires two photolithographs: to create a wiring diagram and removing nickel coating 9 to m -stand layer 10 in the place of installation of light emitters 11 crystals 13. Moreover, holding the second photolithography greatly complicates the process of creating the substrate 4 due to the criticality of the process. The wiring diagram is formed in the process of one photolithography by simultaneously creating at the installation site 11 for crystals of light emitters 13 in a copper-nickel coating from one to several recesses of arbitrary shape, in depth exceeding the thickness of the nickel coating 9 up to the boundary of the copper layer 10 with the substrate 4. This embodiment of the installation sites 11 for crystals of light emitters 13 provides reliable heat dissipation and the absence of a direct voltage drop increment due to the contacting of the conductive layer glue 12 with a copper layer 10.

 The first thickening of the connecting leads 5 on the front side of the substrate 4 ensures reliable contact with its contact pads when pressing the leads, and the second thickening in the volume of the substrate 4 has mechanical adhesion: connecting terminal 5 is the substrate 4. The sealing compound 6 at the exit points of the connecting leads 5 and guide pins 7 on the back of the substrate 4 serves to confidently seal the display module of the display module.

 Truncation of the lenses 2 parallel to the side faces of the cover 1 is aimed at the optimal perception of the displayed information and a more dense filling of the information field of the screen module, in comparison with the lenses 2 made in a spherical design. At the same time, square lenses 2 in plan do not provide uniform illumination in the corners with respect to its central part.

 The execution of information boards for streets or large public premises requires screen modules with high brightness of luminous segments. In this case, on the substrate 4, within the boundaries of each lens 2, there are several crystals of light emitters 13 connected in series, in parallel or in groups in series-parallel, depending on the wiring diagram of the substrate 4.

 With the monochromatic design of the modules of the screen of the information board, crystals of light emitters 13 with red, green, orange, yellow or blue color of the glow can be used. The color saturation, and therefore the perception of information is enhanced by the execution of the cover 1 of the corresponding color due to the introduction of dye when it is performed.

 Multicolor modules of the information board screen are obtained by uniformly positioning on the substrate 4, within the boundaries of each lens, 2 crystals of light emitters 13 with different colors of the light flux to uniformly illuminate the back side of the lens 2 with the light flux, which ensures a uniform color over the entire surface of the front side of the lenses 2. So, the use of crystals of light emitters 13 with red and green color streams allows you to get the whole gamut of colors in the range from red to green. The cover 1 in this case is cloudy with the addition of a white dispersant, but it is preferable to color it yellow, which increases the intensity of the transmission of yellow and orange colors, without weakening noticeably red and green colors.

 To increase the stability of the transition resistances in the places of welding of metal conductors 14 to the tires and places of contact of the connecting leads 5 with the contact pads of the substrate 4 from its front side, conductive adhesive 12 is applied to these places.

 The execution of the screen modules of a sufficiently large size with a monolithic cover 1 presents certain difficulties in view of the possible deformation of the cover 1 during its manufacture. Even a slight deformation leads to the appearance of different brightness of the luminous segments along the field of the module of the screen of the information board. In this case, on the substrate 4 there are several lids 1 made in the form of separate multi-lens segments. In this case, the sealing compound 6, in addition to the peripheral side faces of the covers 1 and the exit points of the connecting leads 5 from the substrate 4, is applied to the joints of the segments of the covers 1. Under the influence of the capillary effect, the sealing compound 6 penetrates the joints to the groove on the back of the covers 1, where the capillary effect is terminated, which prevents the sealing compound 6 from entering the substrate 4.

 The implementation of the cover 1 in the form of separate multi-lens segments significantly simplifies the repairability of such modules of the screen information panel.

 Known technical solutions aimed at improving the ergonomic characteristics and reliability of the display modules of the information board screen by the indicated means were not found when searching the patent fund and literary sources.

 Therefore, the claimed module of the screen information board meets the criterion of "novelty."

 Comparison of the present invention not only with the prototype, but also with other technical solutions in this technical field, did not reveal technical solutions that are similar in terms of the features distinctive in the claimed solution that exhibit similar properties, which allows us to conclude that the proposed information module screen module meets the criterion of "substantial differences. "

Claims (7)

 1. The screen module of the information board, containing a substrate with a wiring diagram, equipped with connecting leads installed on the contact pads of the wiring diagram, light receiver crystals connected by conductors to the corresponding buses of the wiring diagram, a cover with guide pins located respectively to position holes in the substrate, an optical matrix optical fibers placed between the substrate and the cover, as well as lenses made of optically transparent plastic integrated in the cover, characterized in that the cover made integrally with optical fibers and lenses from optically transparent plastic, into which up to 5% of the dispersant is introduced, a contrast-forming coating is applied on the front side of the cover, a groove is made around the periphery of the back of the cover, filled with a sealing compound, and the distance between the lenses is two times the distance between the extreme the lens and the proximal side face of the cover, while the height of the light guide H is selected from the ratio of 1.5h <H <4h, where h is the height of the crystals of the light emitters.  2. The module according to claim 1, characterized in that the busbars and pads of the wiring diagram are made of copper with a nickel coating, while at the places of installation of the crystals of the light emitters, at least one recess of arbitrary shape is made in depth greater than the thickness of the nickel layer, the back side of the substrate covered with a copper-nickel layer, with the exception of the exit points of the connecting leads, while in the places where the connecting leads and guide pins exit from the positional holes of the substrate, the back side is sealed the compound, and the crystals of the light emitters are fixed on the contact pads using conductive glue.  3. The module according to claim 1, characterized in that the lenses are truncated parallel to the side faces of the cover, normally to its front side at a distance exceeding three quarters of the radius of the circle bounding the lenses from the front side of the cover.  4. The module according to claim 1, characterized in that, within the boundaries of each lens, crystals of light emitters with different colors of the light flux are installed.  5. The module according to claim 1, characterized in that a dye is introduced into the optically transparent plastic, corresponding to the color of the color flow of the crystals of the light emitters.  6. The module according to claim 1, characterized in that a yellow dye is introduced into the optically transparent plastic.  7. The module according to claim 1, characterized in that conductive glue is applied to the junction of the conductors with the busbars and the connecting leads with the contact pads of the wiring diagram.

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