KR101486311B1 - Light guiding panel based backlight apparatus capable of buffering thermal expansion of light guiding panel - Google Patents

Abstract

A backlight device having a structure capable of elastically buffering thermal expansion of a large light pipe is disclosed. The light source frame accommodates the light source module closely disposed along at least one side of the light guide plate and the edge portion of the light guide plate, and can move without being fixed, in addition to the expansion and contraction movement in the planar direction of the light guide plate. The frame body includes a guide portion for supporting the edge of the light guide plate and guiding the slide portion as a part of the light source frame so as to be able to move back and forth in the plane direction of the light guide plate, Spring support. The spring is inserted between one side of the light source frame and the spring support portion so as to elastically press the light source frame toward one side of the light guide plate so that the light source module is brought into close contact with one side face of the light guide plate regardless of the thermal expansion or heat shrinkage of the light guide plate. To be maintained. In the state where the slide portion of the light source frame is inserted and confined in the guide portion, the light source frame is held so as not to push the upper surface of the edge of the light guide plate. The light source frame, the light source module, and the light guide plate can be separated from the frame main body only by removing the spring without disassembling the frame main body.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a backlight device capable of buffering thermal expansion of a light guide plate,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a backlight device, and more particularly, to a backlight device capable of preventing thermal expansion of a large light pipe by buffering the light pipe,

The backlight device using the light guide plate has been produced up to the size of 6000 x 2000 mm in width and size, as the commercial size of the light guide plate produced in accordance with the trend of enlargement of the advertisement panel.

The edge type backlight device is generally made of a structure in which a light source module is disposed on at least one side of a light guide plate and an edge portion of the light source module and the light guide plate is wrapped and held in a frame of a picture frame. In constructing the edge type backlight device, the following two requirements need to be satisfied. First, the lamp of the light source module must adhere to the side (light incident surface) of the light guide plate. Otherwise, a part of the light generated from the lamp leaks out of the light guide plate, resulting in deterioration in light efficiency. Second, it is preferable that the light source module is installed so as to be in direct contact with a frame made of metal (for example, aluminum). The light source module is mainly composed of a light emitting diode (LED) mounted on a printed circuit board (PCB). In a light source module in operation, a lot of heat is generated. The heat needs to be diverted to the outside quickly. Otherwise, not only does the light efficiency of the LED deteriorate, but also the lifetime of the LED is shortened. Therefore, the frame is made of a metal having a high heat-dissipation rate, such as aluminum, and the light source module needs to be arranged in direct contact with the frame to maximize the heat transfer rate to the frame. As a result, the light source module must be disposed in close contact with both the inner wall of the receiving groove provided in the frame and the light incident surface of the light guide plate. In order to stably maintain such an arrangement, generally, the light guide plate is fixed to the frame by bolts or the like, or holding means is provided on the frame to strongly hold the light guide plate so that the light guide plate can not move freely.

The present inventor has found no problem when the backlight device having such a structure has a large temperature change during the year or a large change in temperature during the year when the temperature change is not large, but the size of the light guide plate is large (particularly, Is more than 2 ~ 3m.) Especially, when the installation environment of the advertisement panel has a large temperature change during the year, it has experienced an unexpected problem. That is, when a backlight device employing a large light guide plate is exposed to a high temperature for a long time, the light guide plate is deformed such as warping or warping, and damage occurs at a portion where the light guide plate hits the frame.

The inventors of the present invention have noted that this problem is frequent especially when the temperature of the installation place of the advertisement panel rises very high. In the case of Korea, the temperature of a place exposed directly to the sun during the summer months is close to 40 degrees. Considering the heat generated by the light source module being driven, the temperature of the light guide plate will rise to a much higher temperature than the ambient temperature. In cold weather, the outdoor temperature goes down to -20 ~ 30 ℃. The installation environment of the outdoor advertising panel is at least 60 ° C over the year. It has also been noted that the above-mentioned problems frequently occur in advertising panels installed in outdoor areas where the temperature difference is large throughout the year.

The light guide plate is made of an acrylic resin plate material (typically, polymethyl methacrylate (PMMA)) excellent in transparency and light transmittance. The PMMA plate for the light guide plate and the aluminum frame differ greatly in thermal expansion coefficient. The linear expansion coefficient of aluminum is 2.303 × 10 ^-5 /, while the coefficient of linear expansion of PMMA plate is large (5 ~ 10) × 10 ^-5 /. For reference, the coefficient of linear expansion of most metals other than aluminum, which can be used as a frame material, is smaller than the coefficient of linear expansion of aluminum (the coefficient of linear expansion of iron is 1.23 x 10 ^-5 / degree). The linear expansion coefficient is about two to five times larger than that of aluminum for the PMMA plate. For an isotropic solid, the volume expansion coefficient is about three times the linear expansion coefficient.

The inventors of the present invention have been unable to take account of the difference in the coefficient of thermal expansion when determining the size of the light guide plate (PMMA plate) to be accommodated in the storage space of the frame and the storage space thereof when the advertisement panel is manufactured, I found out that it was the cause. That is, when the size of the light guide plate is large and the temperature around the advertising panel is high, the light guide panel material expands at a much larger rate than the frame due to the difference in thermal expansion coefficient. As a result, the size of the light guide plate in the horizontal direction becomes larger than the size of the receiving groove of the frame. Since the metal frame is much stronger in mechanical strength than the light guide panel material, the light guide panel material pushes the side wall of the receiving groove of the frame but does not overcome the buckling force of the frame and deforms such as warping or twisting. In severe cases, the light guide plate is damaged.

At a very low temperature, on the contrary, the size of the light guide plate is reduced to a larger extent relative to the frame, thereby increasing the spacing between the frame and the light guide plate. As a result, in the case of an advertising panel which is not suitably sized at the time of manufacture, the light guide plate may be detached from the storage space.

In addition, since the frame and the light guide plate are in close contact with each other with the light source module therebetween, it is difficult to transport the large light guide plate. That is, when the light guide plate is tilted to one side during the transportation of the backlight device, when the light source module exerts excessive pressure on the light source module, the fluorescent material of the LED is damaged and discoloration occurs in the LED light. If the applied pressure is too high, the LED may be damaged. To solve this problem, it is necessary to introduce a cushioning function which keeps the LED closely attached to the light guide plate and prevents the excessive pressure from being applied to the LED.

On the other hand, if the light source module or the light guide plate is damaged or broken during transportation or use of the assembled advertising panel, the failed parts must be replaced. In the conventional advertising panel, it is difficult to separate only the light source module or the light guide plate when the frame is assembled. If it is possible to separate only the failed light source module or the damaged light guide plate from the frame without partial or total disassembly of the assembled frame, the maintenance time of the advertisement panel can be greatly reduced.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems of the prior art, and it is an object of the present invention to provide a light source module in which a light source module is always kept in close contact with a side surface of a light guide plate by dynamically buffering a difference in thermal expansion between a frame and a large light guide plate, And it is an object of the present invention to provide a light guide plate backlight device having a structure that prevents excessive pressure from being applied to the light source module and prevents deformation such as warping or twisting of a thermally expanded light guide plate tightly tightened to a frame.

Further, the present invention has a structure capable of disassembling the light source module and / or the light guide plate from the assembled frame without disassembling the assembled frame, so that the replacement of the light source module and / or the light guide plate damaged during transportation or use Another object of the present invention is to provide a light guide plate backlight device having a structure that can be easily carried out.

According to an aspect of the present invention, there is provided a light guide plate comprising: a planar light guide plate; A light source module closely disposed along at least one side of the light guide plate; A light source frame disposed inside the light source module and the light guide plate and movably attached to the light guide plate in a planar direction without being fixed by itself; A light guide plate support portion for supporting a periphery of a bottom surface of the light guide plate; A guiding part for guiding the slider part to move back and forth in a plane direction of the light guide plate while being slidably restrained by being inserted into the slider part as a part of the light source frame; And a spring support portion fixedly disposed between the light source frame and the light source frame, the spring support portion providing a spring receiving space having a variable spacing in a plane direction of the light guide plate, the variable interval being such that the slide portion always contacts the guide portion A frame body which is an interval that is variable within a range in which it is held in an interlaced and slidably restrained state; And a spring supporting portion inserted between the one side of the light source frame and the spring supporting portion in a compressed state to elastically press the light source frame toward the side of the light guide plate using the spring supporting portion as a stepping plate, Wherein the light source module has a spring that keeps the light source module in close contact with at least one side surface of the light guide plate regardless of whether the size of the light source module changes in the plane direction according to the size of the light source module, The upper side of the light source frame presses the upper surface of the edge of the light guide plate so as to prevent the light guide plate from being detached while the light source frame is held in a slidably restrained state while being inserted into the guide portion, When taken out between the supports, And the frame, the light source module, and the light guide plate are trapped in the frame body due to the elastic force of the spring, so that the frame can be separated upward from the frame body.

The backlight device may further comprise a hinge having an elastic force and a cover frame pivotally connected to the frame body by the hinge and providing a downward force from the upper side of the frame body by the elastic force of the hinge desirable.

One example of the spring includes a bent portion formed of a metal plate and having a V-shaped, U-shaped or W-shaped cross-section, and a staple portion bent in a planar direction of the light guide plate at one side of the bent portion The bent portion is a leaf spring inserted between the light source frame and the spring support portion, and the straddling portion is provided so as to cover the upper surface of the light source frame.

The light source frame and the bending portion of the spring abut each other to provide concave and convex portions, which are engaged with each other so that the spring can not easily escape out.

The guide portion is provided in the form of a groove having an opening opened toward a plane direction of the light guide plate.

It is preferable that the depth g of the groove of the guide portion is not smaller than a depth capable of accommodating a change in the maximum size due to thermal expansion according to a predetermined temperature change of the light guide plate.

The length h of the light source frame in the plane direction of the light guide plate is preferably smaller than the distance s between the upper end of the inlet of the guide unit and the spring support unit.

Another example of the spring is a coil spring. Wherein the light source frame includes a light source accommodating part for accommodating and supporting the light source module in a first accommodating space provided only by a surface facing the light guide plate and the other surface being closed; And a second receiving space which is integrally connected to the lower side of the light source accommodating part and which is open at one side only to open in a direction opposite to the light source accommodating part, And a spring receiving portion provided with a through hole in a surface of the second accommodation space facing the light guide plate (hereinafter referred to as a 'spring support surface') and being inserted and slidably restrained in the guide portion. Wherein the spring support portion is screwed on the light guide plate side surface of the guide portion through the through hole provided in the spring support surface and the head portion is integrally provided at the upper end of the screw column, It is a nearby bolt. Wherein the coil spring is inserted between the head portion of the bolt and the spring supporting surface of the movable spring receiving portion while being extruded to the screw column of the bolt in a compressed state so that the head portion of the bolt, An elastic force directed toward the light guide plate is applied to the spring supporting surface to push the light source frame integrally coupled to the spring receiving portion toward the light guide plate.

According to the light guide plate backlight device of the present invention, the light guide plate is housed in the frame so as not to be detached from the front and rear but is not fixed, so that the light guide plate can move sideways freely in the frame. In addition to these structural features, since the elastic member is disposed between the side surface of the light guide plate and the frame, even if there is a difference in magnitude of the thermal expansion coefficient between the frame and the large light guide plate due to a large temperature change, The resilient member interposed between them resiliently absorbs such a magnitude variation difference. As a result, even if the light guide plate expands more than the frame due to the high ambient temperature, the light guide plate does not deform or break, such as warping or twisting due to tight tightening on the frame. Instead, the light source module is always in close contact with the side surface of the light guide plate and the frame .

Even in such an installation environment with a large seasonal temperature change, the light guide plate backlight device of the present invention has no deformation of the light guide plate, and the light source module always maintains a state of being in close contact with the side face of the light guide plate, There is no reduction in the divergence efficiency of the generated heat of the light source module.

Further, since the light source module and the light guide plate can be separated from each other without disassembling the frame body, maintenance and repair of the backlight unit are very convenient.

FIG. 1 is a plan view showing an appearance of an assembled state of a light guide plate-based backlight device according to first and second preferred embodiments of the present invention,
FIG. 2 is a sectional view of the light guide plate of the large light guide plate-based backlight device according to the first preferred embodiment of the present invention using the leaf spring as thermal expansion buffering means along a cutting line AA in a state of thermal expansion,
3 is a sectional view taken along a cutting line AA in a state in which the light guide plate of the backlight device of Fig. 2 is heat-shrunk,
4 is a sectional view of the backlight device of FIG. 2 taken along the cutting line AA in a state where the leaf spring is removed and the cover frame is opened,
5 is a sectional view taken along the cutting line BB in a state that the light guide plate of the large light guide plate-based backlight device according to the second preferred embodiment of the present invention, which uses the coil spring as thermal expansion buffering means,
Fig. 6 is a sectional view taken along the cutting line BB in a state where the light guide plate of the backlight device of Fig. 5 is in a heat contracted state,
Fig. 7 is a cross-sectional view of the backlight device of Fig. 5 taken along the cutting line BB with the cover frame opened. Fig.

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

Fig. 1 shows a backlight device 100, 200 according to a first embodiment and a second embodiment of the present invention to be described below. The characteristics of the backlight devices 100 and 200 are not in the external shape but are in the internal structure of the frame reflecting the buffering means and its installation structure capable of buffering the thermal expansion of the light guide plate. Therefore, FIG. 1 shows a general outline of the external shapes of the backlight devices 100 and 200 of the first embodiment and the second embodiment.

(1) First Embodiment

The backlight device 100 according to the first embodiment is shown in Figs. 2 to 4 in its structure. The backlight device 100 is characterized in that a leaf spring 170 is used as a means for buffering thermal expansion of the light guide plate 120. [ 2 and 3 are sectional views taken along a cutting line AA of FIG. 1 in a state that the light guide plate 120 is thermally expanded and heat-shrunk, respectively. FIG. 4 is a plan view of the backlight unit 100, Sectional view taken along the cutting line AA in a state in which the light guide plate 120 is moved to the right side by opening the light guide plate 140. Fig.

The backlight device 100 includes a light guide plate 120 for scattering light input to at least one side surface of the light guide plate 120 and scattering light scattering elements disposed at a bottom surface of the light guide plate 120, A light source module 160 disposed between at least one side of the light guide plate 120 and the inside of the frame 110, a light source frame 150, and a spring 170. The frame 110 includes a frame body 130 and a cover frame 140. The cover frame 140 is coupled to the frame body 130 in such a manner that it can be opened and closed while being pivotal relative to the frame body 130. [ The light source module 160 is accommodated in the light source frame 150 and the spring 170 is supported by the spring support portion 133 and pushes the light source frame 150 toward the one side of the light guide plate 120, (160) is kept in close contact with the one side surface of the light guide plate (120).

The light source module 160 is composed of a strip-shaped printed circuit board 164 and a plurality of LEDs 162 mounted in a line thereon. The printed circuit board 164 is provided with a driving circuit for providing a voltage necessary for driving the plurality of LEDs 162 and a wire jack (not shown) for receiving driving power from an external DC power source (e.g., a converter (not shown) . The driving circuit is formed by grouping all the LEDs 162 by a predetermined number (for example, eight), connecting the LEDs 162 in the same group in series, connecting groups and groups in parallel, As well. It goes without saying that other types of lamps which may come out in the future instead of the LEDs 162 may be used as the lamps of the light source module 160.

The light guide plate 120 is made of an acrylic resin plate in the same manner as in the conventional art, and light scattering elements that are known or may be developed in the future are formed on the bottom surface, for example, fine grooves, V-cuts, printed ink dots and the like. The present invention is not limited to the size of the light guide plate 120 because it is presented as a solution in the case of a large size in which thermal expansion of the light guide plate 120 becomes a problem.

The frame 110, that is, the frame body 130 and the cover frame 140 can be made by injection using, for example, aluminum having good thermal conductivity and strength. In this case, all of the components constituting the frame body 130 are connected by a single body. The same applies to the cover frame 140. Further, the frame 110 is configured to resemble the light guide plate 120. (Hereinafter, collectively referred to as a polygon) other than a rectangle, a polygon of a different kind, a circle or a similar circle, and the like. In the illustrated embodiment, the light guide plate 120 and the frame 110 are formed in a square shape. The cover frame 140 is coupled to the frame body 130 so that it can be opened and closed in a pivoting manner. The cover frame 140 can be brought into a closed state (see FIG. 2 or 3) or an open state (see FIG. 4) by an external force. The cover frame 140 covers at least a part of the upper portion of the frame body 130 so that the frame body 130 and the cover frame 140 are in the shape of a rectangular picture frame and the edge portions of the rectangular plate- From both upper and lower sides. In the opened state, the upper part of the frame body 130 is opened so that the spring 170 can be pulled out. Thus, without dismantling the frame body 130 itself, the light guide plate 120, the light source frame 150, The frame 160 can be separated from the frame 110 (details will be described later).

The light source frame 150 is a bar type having a left side only, a left side and a closed upper side, and is extended at least as long as the length of the light source module 160. The light source module 160 is accommodated in the light source frame 150 such that the LEDs 162 are directed toward the open end of the light guide plate 120 and the side surface of the light guide plate 120 is closely contacted with the light source module 160, Is also housed in the light source frame 150. The light source frame 150 is preferably made of a metal having good thermal conductivity. The lower surface of the light source frame 150 is a sliding portion 152 that moves into and retracts into a groove-shaped guide portion 132 (to be described later) of the frame body 130. The light source frame 150 is installed in a non-stationary manner so as to move in the horizontal direction (y-axis direction in FIG. 3) accompanying the expansion and contraction of the light guide plate 120 in the horizontal direction. However, while the sliding portion 152 is inserted into the guide portion 132, the light source frame 150 is restrained by the guide portion 132 and is not free to move in the vertical direction (z-axis direction in FIG. 3).

A spring 170 is inserted between the right side of the light source frame 150 and the spring support 133 (to be described later) of the frame 110. The spring 170 is not limited to a structure or a material so long as one side of the spring 170 can be supported by the spring support portion 133 and the other side can push the light source frame 150 toward the light guide plate 120 (in the -y direction). For example, as shown in Fig. 4, a V-shaped to U-shaped bent portion 172 for providing an elastic force, a protruding portion 174 provided in a part of the bent portion 172, And a locking portion 176 which is bent in a planar direction of the light guide plate at one upper end of the light source frame 150 to limit the insertion depth of the spring 170 while pressing the light source frame 150 over the upper surface of the light source frame 150, And may be in the form of an elongated metal plate spring 170. In this case, it is preferable that the right-side outer surface of the light source frame 150 is provided with a toothed spring latching portion 154 corresponding to the shape of the protruding portion 174. Conversely, the spring 170 may be provided with a concave portion and the light source frame 150 may be provided with a convex portion. As a result, the projecting portion 174 of the spring 170 and the spring engagement portion 154 of the light source frame 150 are engaged with each other, so that the spring 170 can not easily escape out. Although not shown, the bent portion 172 and the spring supporting portion 133 may be provided with recesses and protrusions to be engaged with each other.

The metal plate spring 170 has a complex function. First, the light source module 160 is always kept in close contact with the side surface of the light guide plate 120 while the light guide plate 120 absorbs thermal expansion by the bent portion 172 and the projection portion 174 constituting the U- Thereby providing a function of an elastic pressing portion that provides an elastic force to the elastic pressing portion. Secondly, the wedge function is provided to prevent the light source frame 150 from being detached by the latching part 176 and to hold the light guide plate 120 so as not to be detached. Third, the heat source module 160 provides a heat transfer function for transferring heat generated from the light source module 160 to the frame body 130 quickly. Fourthly, the light guide plate 120, the light source module 160, and the light source frame 150 can be easily fixed and installed in the frame body 130, and at the same time, It provides a simple assembly decomposer function that allows you to disassemble it.

The frame body 130 includes a main body base 131, a guide portion 132, a spring support portion 133, a light guide plate support portion 134, and the first hinge support portion 135 described above. The main body base 131 is formed so that its cross-sectional shape shares one support wall 138 on both sides thereof, so as to provide necessary and sufficient strength while preventing the distortion such as warpage and warping, The square cavities consist of adjacent tube shapes. On the upper surface of the left rectangular tube portion 137-1 of the main body base 131, a light guide plate receiving portion 134 protrudes from above the both side walls. The upper surfaces of the two light guide plate receiving portions 134 are formed as horizontal portions having the same height, and the edge portions of the light guide plate 120 are supported thereon.

On the upper surface of the right rectangular pipe 137-2 of the main body base 131, a guide portion 132 is provided. The guide part 132 is provided in a groove shape in which the slide part 152 of the light source frame 150 can move back and forth in the horizontal direction (y-axis direction) which is the planar direction of the light guide plate 120. The guide part 132 serves to guide the light source frame 150, which is forced to move along with the expansion and contraction of the light guide plate 120 in the horizontal direction, to stably move in the horizontal direction of the light guide plate 120. The depth g of the groove of the guide portion 132 is set so as to be capable of accommodating the maximum size change due to the thermal expansion that can be expected under the installation condition of the light guide plate 120, It is desirable that the depth of the main portion 152 is maintained to be maintained in a state where the main portion 152 is inserted into the groove of the guide portion 132). In order to prevent a state where the entrance portion of the guide portion 132 touches the light source module 160 to pressurize even if the sliding portion 152 of the light source frame 150 reaches the bottom of the groove of the guide portion 132, The depth g of the groove of the guide part 132 is made not to be larger than the height f from the upper surface of the light source module 160 to the upper end of the entrance part of the light source frame 150 desirable.

The frame body 130 also has a first hinge support portion 135 and a cover frame support portion 136. The first hinge support portion 135 is provided to extend from the right side of the right rectangular pipe 137-2 of the frame body 130 to the right side (in the y-axis direction). The cover frame receiving portion 136 is provided in a shape protruding in the y-axis direction from the right side surface of the spring supporting portion 133.

The spring support portion 133 protrudes upward at least from the upper surface of the right rectangular tube portion 137-2 of the main body base 131 to the right side surface of the light source frame 150 As shown in Fig. 2, when the spring 170 is inserted between the spring support portion 133 and the light source frame 150, a predetermined gap (not shown) is formed between the light source frame 150 and the spring support portion 133 d is secured. 3, even if the light guide plate 120 expands relatively more due to the difference in the thermal expansion coefficient between the light guide plate 120 and the frame 110, By compressing (at this time, the interval d narrows to d '), it resiliently absorbs the expansion.

In order to elastically buffer the thermal expansion of the light guide plate 120, as the interval d increases to the maximum expected temperature of the installation environment of the backlight unit 100, the side surface of the expanded light guide plate 120 presses the spring 170 It is desirable that the spring 170 be set at least at a greater interval than the interval leading to the elastic limit. Then, at the maximum expected temperature, the light source frame 150 is pushed to the right to reduce the angle of the spring 170, and the spring 170 functions as a thermal expansion buffering means. The elasticity of the thermal expansion using the spring 170 prevents the light guide plate 120 from being tightly tightened to the frame 110, such as being bent or twisted, such as deformation or breakage.

Since the thermal expansion coefficient between the light guide plate 120 and the frame 110 greatly differs as described in the related art, it is necessary to reflect this point when the backlight device 100 is actually manufactured. The actual production environment temperature is usually lower than the highest expected temperature in the installation environment of the backlight device (e.g. Standard PMMA, which is a material of the light guide plate 120, can withstand temperatures of about 65 ° C to maintain thermal stability and up to about 100 of thermally stabilized PMMA. And down to -75 ° C. The expected temperature of the installation environment of the backlight device 100 can be set in the range of -75 to 100 占 폚. It is assumed that the light guide plate 120 undergoes thermal expansion and heat shrinkage within this temperature range. In consideration of this point, it is stable that the maximum expected temperature of the installation environment of the backlight device 100 is assumed to be 65 to 100 占 폚. Under this assumption, in the case of the first embodiment, the distance between the light source frame 150 and the spring support portion 133 it is preferable to set the minimum value and the maximum value of d. If necessary, the shape of the spring 170 to be employed may be made not to be a V-shaped (or U-shaped) shape but to be a wedge-shaped or two-tied type of two, will be.

The gap s between the upper end of the inlet of the guide portion 132 and the spring support portion 133 is a state before the spring 170 reaches the critical compression state The thickness d 'of the spring 170 and the height h in the y-axis direction of the light source frame 150 at a predetermined temperature, for example, a state compressed to about 90% or less as compared with the critical compression state) (I.e., s < h + d '). The sliding portion 152 of the light source frame 150 is inserted into the groove of the guide portion 132 even if the spring 170 is compressed to a maximum of 90% as compared with the critical compression state due to the expansion of the light guide plate 120, And it will not be able to escape in the direction. In order to allow the light source frame 150 to be pulled upward (in the z-axis direction) after the spring 170 is compressed by the artificial force to the critical compression state, the height h in the y-axis direction is preferably smaller than the distance s between the upper end of the inlet portion of the guide portion 132 and the spring support portion 133. [

4, the cover frame 140 is pivoted in the closed state, and then the spring 170 interposed between the light source frame 150 and the spring support portion 133 is forcibly pulled out have. The light source frame 150 and the light source module 160 housed therein can also be pulled out in a state in which the light guide plate 120 is slightly pushed to the left. Further, the light guide plate 120 can also be disassembled from the frame body 130. Such a disassembling operation of the component parts is advantageous in that the frame body 130 can be assembled without being disassembled. Here, the polygonal frame body 130 is formed by arranging the frame bars in a polygonal frame, and then assembling the frames at the connection edges of the frame bars with the brackets 114 and 116, And 116 are removed to disassemble the frame bars constituting the frame body 130. Re-housed components to be repaired or replaced can be easily assembled in the reverse order of disassembly. Problems such as failure, damage, breakage, etc. of the light source module 160 or the light guide plate 120 may occur during manufacture, transportation, and use of the backlight device 100. The inspection or replacement of the problematic parts can be performed without disassembly of the frame 130. [ This is a feature that makes maintenance and maintenance (of course, assembly) of the backlight device 100 very convenient.

The cover frame 140 covers the edge portion of the light guide plate 120 and the frame body 130 including the light source module 160, the light source frame 150 and the spring 170 so that the front face of the backlight device 100 The appearance of the frame 110 is represented. In addition, the cover frame 140 cooperates with the frame body 130 to form a stable frame structure and protect the light guide plate 120. Further, it is possible to provide a place where the rubber stoppers 117 and 118 can be disposed in the gap with the frame body 130, thereby preventing moisture from flowing into the frame 110 from the outside into the light source module 160, It does. The cover frame 140 also indirectly restrains the light source frame 150 directly or through the light guide plate cover 122 so as to prevent the light source frame 150 from being engaged with the light guide plate 120 when the cover frame 140 is in the closed state with respect to the frame body 130 .

The cover frame 140 has a structure in which the cover body 142, the second hinge support portion 144, the light guide panel cover holder 146, and the frame body pressing portion 147 are integrated. The cover body 142 has a horizontal portion which covers the light guide plate 120 and presses the light guide plate cover 122 which functions as a protective cover thereof and a vertical portion which is substantially perpendicular to the horizontal portion. Here, it is preferable that the light guide plate cover 122 is made of transparent synthetic resin such as polycarbonate resin or polyethyleneterephthalate resin. The second hinge support portion 144 is extended to support one arm portion of the hinge 112 from the lower end of the vertical portion of the cover body 142 to the upper left chamber. The second hinge support 144 pivotally engages the frame body 130 via the hinge 112. The light guide plate cover holder 146 is vertically provided on the bottom surface of the horizontal portion of the cover body 142 with a predetermined gap therebetween so as to support the edge portion of the light guide plate cover 122 therebetween. The frame body pressing part 147 is provided in a shape protruding downward from the lower light guide panel cover holder 146. [ Since the cover body 142 is preferably formed in a tube shape resistant to deformation such as warpage or warping, the frame body pressing portion 147 and the second hinge support portion 144 are connected to each other. The cover frame 122 also serves to support the edge portion of the light guide plate cover 122 by pressing it. To this end, the upper portion of the cover body 142 is horizontally extended to the left so as to cover and press the edge portion of the light guide panel cover 122. When the advertisement film (not shown) is placed on the light guide plate cover 122, it also presses and supports the advertisement film. The installation of the light guide panel cover 122 may be omitted.

The frame body 130 and the cover frame 140 can be assembled in the following order: (i) a cross section of the frame body 130 and the cover frame 140 shown in FIG. 2 or 3, A long frame bar having a structure is cast using aluminum; (ii) the frame bar is cut into two lengths each for a horizontal frame and a vertical frame, which hold the edge portions of the four side surfaces of the light guide plate 120, respectively, to an appropriate length; (iii) four frame bars for the frame body 130 are arranged in a rectangular frame, and then joined at four corners by brackets 114 and 116 to assemble a rectangular frame body frame; (Iv) A method of fastening both arms of the hinge 112 to the first hinge support 135 and the second hinge support 144, Four frame bars are coupled to the frame bars for the four frame bodies 130 one by one to complete the assembly of the frame 110. [ Of course, the coupling using the hinge 112 may be performed prior to the step (iii). The frame 110 in which the frame body 130 is covered with the cover frame 140 is shaped like a bar having a substantially rectangular shape.

Since the frame body 130 and the cover frame 140 are coupled to each other by the hinge 112, the cover frame 140 can be opened and closed while pivotally moving with respect to the frame body 130. It is preferable that the hinge 112 is made of a torsion spring type elastic hinge having a cross-sectional shape extending in both directions from the central nose portion to both arms. One arm of the resilient hinge 112 engages the first hinge support 135 of the frame body 130 and the other arm engages the second hinge support 144 of the cover frame 140. The first hinge support portion 135 includes a support portion that contacts the one arm of the hinge 112 and extends to support the arm and an engagement portion to which the one end of the hinge 112 is inserted. The second hinge support portion 144 also has a support portion for contacting and supporting the other arm of the hinge 112 and an other end portion of the hinge 112 located at the end portion of the support portion And a latching portion. The closed state of the cover frame 140 can be maintained as long as no external force is applied by the elastic force provided by the elastic hinge 112. That is, the cover frame 140 has a hinge 112 coupled to the first and second hinge supports 135 and 144 as a pivot axis, The cover frame 140 maintains the closed state as shown in FIG. 2 or 3 while the angle of the cover 140 is about 120-150 degrees. When an external force is applied to the cover frame 140, the angle of the arms of the hinge 112 is reduced to about 30-60 degrees, and the cover is opened as shown in FIG.

When the backlight device 100 is installed outdoors, it is necessary to prevent the rain from penetrating into the inside. For this purpose, a waterproof rubber stopper (117, 118) closes a gap between the frame body (130) and the cover frame (140).

In the backlight device 100 having such a configuration, the light source frame 150 has a function of fixing the light guide plate 120 to the frame body 130 and a function of the spring 170, (120). By this action of the light source frame, it is possible to fix the light guide plate 120 to the frame body 130 without using bolts or other coercive fixing means, thereby improving the durability and efficiency of the product.

In addition, the light source module 160 maintains a state in which it is always in close contact with the side surface of the light guide plate 120 by the elastic force provided by the spring 170. In this state, the light source frame 150 is in direct contact with the light source module 160, the guide portion 132 of the frame body 130 and the main body base 131, and at the same time, the spring support portion 133, Lt; / RTI &gt; The heat generated by the light source module 160 is quickly transmitted to the frame body 130 and is diverted to the outside air because the remaining components except for the light source module 160 are all metal having excellent thermal conductivity. Since the air has a slow heat transfer rate, it may be considered to further employ a means to compensate for this disadvantage. 2, it is preferable to provide a thermally conductive material having excellent thermal conductivity between the light source module 160 and the light source frame 150 in order to more quickly transmit the heat of the light source module 160 to the frame body 130. [ A thermal grease 190 may be charged. Further, although not shown, the thermally conductive grease 190 may be further charged between the light source module 160 and the frame body 130, or between the light source frame 150 and the frame body 130. The light efficiency of the LED 162 can be improved and the life span can be expected due to rapid heat dissipation through the thermally conductive grease 190 that transfers heat faster than air.

(2) Second Embodiment

5 to 7 show the configuration and operation of the backlight device 200 according to the second embodiment of the present invention. The second embodiment is characterized in that the coil spring 270 is used as a light guide plate thermal expansion buffering means, whereas the first embodiment is characterized in that the spring 170 is used as the light guide plate thermal expansion buffering means. 5 and 6 are sectional views taken along a cutting line BB in FIG. 1 in an assembled state of the backlight device 200. FIG. 5 shows a state in which the light guide plate 120 is contracted (or when the coil spring 270 is expanded) 6 shows the expansion of the light guide plate 120 (or compression of the coil spring 270).

The frame 210 of the second embodiment surrounding the periphery of the light guide plate 120 has the frame body 230, the cover frame 240, the hinge 112, the light source frame 250, and the elastic member 270 , 272). At one end of the frame body 230 and the cover frame 240, third and fourth hinge supports 235 and 244 are provided and a hinge 112 is provided thereon. The frame body 230 and the cover frame 240 are coupled to each other so as to be openable and closable while being rotated by the hinge 112. The frame 210 is divided into four frames. The frame bars are combined with brackets 214, 216, 218, and 219 at four corners of a rectangular frame to form a rectangular frame.

The frame body 230 is provided in a tubular shape (for example, a shape in which at least one tube is connected as shown) to prevent warping or distortion on the flat main body base portion 231, The third hinge support portion 235 is formed. A part of the side wall of the tube of the frame body 230 is bent upward to form a light guide plate receiving portion 234 on which the edge portion of the light guide plate 120 is placed and the lower side thereof is integrally bent And forms a guide portion 232 for guiding the forward and backward movement of the light source frame 250 into the inside thereof. A bolt fastening hole 233 is provided at the center portion of the guide portion 232.

The light source frame 250 is also bent upward to form the light source accommodating portion 254 and the lower side of the light source frame 250 is integrally bent to form the spring receiving portion 252. The light source module 160 is housed in the upper light source accommodating portion 254. It is preferable that the light source module 160 is filled with the thermally conductive grease 190. The upper light source accommodating portion 254 is higher in height than the light guide plate receiving portion 234 by the thickness of the light guide plate 120 so that the edge of the light guide plate 120 is inserted between the upper horizontal portions thereof. A waterproof vane 256 for preventing flooding is horizontally protruded from the back surface of the light source accommodating portion 254.

The spring receiving portion 252 is also provided with a bolt through hole 258 at a position corresponding to the bolt fastening hole 233. A thread is formed in the bolt fastening hole 233, but no thread is formed in the bolt through hole 258. A spring supporting bolt 272 is inserted into the coil spring 270 and passes through the bolt through hole 258 and is fastened to the bolt fastening hole 233 in the spring receiving portion 252. The coil spring 270 is restrained by the head of the bolt 272 and the bottom of the spring receiving portion 252.

The cover frame 240 includes a fourth hinge support portion 244 provided at the lower end thereof, a cover portion 242 extended in a tubular shape at a predetermined height and bent at a substantially right angle and extending in the horizontal direction, And a cover holder 246 which provides a horizontally opened receiving groove. The cover holder 246 accommodates and supports the edge portion of the light guide plate cover 122 into the cover holder 246.

When the cover frame 240 is closed to the frame body 230, the waterproof rubber stoppers 215 and 217 are disposed for every gap from the outside to the light source module 160 in order to prevent water from penetrating from the outside .

The backlight device 200 according to the second embodiment having such a configuration also absorbs the coil spring 270 when the thermally expanded light guide plate 120 is enlarged in the horizontal direction. More specifically, since the bolt 272 is fastened and fixed to the bolt fastening hole 233, a predetermined length is always maintained from the bottom of the spring receiving portion 252 to the head of the bolt 272, The length that can be stretched to the maximum is also limited to that length. The size of the light guide plate 120 to be maximally contracted is estimated in advance so that the coil spring 270 is in a maximally extended state when it is in such a contracted state. 5, the light source module 160 maintains a close contact state with the side surface of the light guide plate 120 even when the light guide plate 120 is fully contracted.

When the temperature of the periphery where the backlight device 200 is installed is increased, the light guide plate 120 thermally expands and the size thereof increases in the horizontal direction. As a result, the light source module 160 is pushed back and the light source frame 250 is also pushed back and the spring receiving portion 252 is also pushed backward (in the direction of the arrow in FIG. 6). However, since the bolt 272 is fixed, the coil spring 270 sandwiched between the head of the bolt 272 and the bottom of the spring receiving portion 252 is compressed as shown in FIG. As a result, even when the light guide plate 120 is thermally expanded, the light source module 160 is kept in a state of being in close contact with the side surface of the light guide plate 120 by the force provided by the compressed coil spring 270.

The light source frame 250 is inserted into the guide portion 232 provided in the frame body 230 so that a part of the light source frame 250 is received in the horizontal direction in accordance with the heat shrinkage and thermal expansion of the light guide plate 120, As shown in Fig. In order to prevent the spring receiving portion 252 of the light source frame 250 from being peeled off from the guide portion 232, it is necessary to consider an expected temperature range of -75 to 100 DEG C in the installation environment of the above- . In other words, the maximum guide distance at which the guide portion 232 can guide the light source frame 250 needs to be deeper than the difference between the maximum expected thermal expanded length and the maximum expected heat shrinked length. It is also preferable to determine the maximum extension and length of the coil spring 270, the length of the spring receiving portion 252, and the like in consideration of the expected temperature range. The height from the bottom of the guide portion 232 to the head of the bolt 272 is set to a maximum size that prevents the spring receiving portion 252 inserted into the guide portion 232 from escaping even when the coil spring 270 is fully compressed .

The second embodiment also has a major technical feature in common with the first embodiment. That is, the coil spring 270 can be removed by separating the bolt 272 from the guide portion 232 while the cover frame 240 is pivoted. The spring receiving portion 252 can be removed from the guide portion 232 and the light source frame 250 and the light guide plate 120 can be separated from the frame 210. [ Disassembly of the frame 210 is not required for such a separation operation. The coil spring 270 and the bolt 272 provide the simple assembling decomposer function as in the first embodiment as well as the spring 270 and the bolt 272, A wedge function for preventing the light source frame 250 and the light guide plate 120 from being separated from the frame body 230 and a heat function of the light source module 160 transmitted from the light source frame 250 to the frame body 230 And even delivering heat transfer functions.

In the description of the second embodiment described above, it should be understood that what is not described in the second embodiment without being inconsistent with the second embodiment of the description of the first embodiment is omitted in order to avoid redundant description.

It is needless to say that, in the above two embodiments, the spring 170 or the coil spring 270 is merely a representative example of a means for elastically absorbing and buffering thermal expansion, and other types of elastic means may be used instead.

In addition, with reference to the arrangement positions of the spring 170 and the coil spring 270, although the drawing is shown as being disposed on the side where the light source module 160 is disposed, It does not have to be installed only on the side. In the case of a large light guide plate having a length of several meters or more in all the lengths, the thermal expansion in all four directions must be large enough to be installed on all four sides of the light guide plate. On the other hand, It may be provided only on one side or both sides of the longitudinal side, that is, on the left and right sides.

According to the above-described two embodiments, even if the size of the light guide plate 120 in the horizontal direction expands or contracts according to the change of the ambient temperature, it is possible to use the elastic means such as the spring 170 or the coil spring 270, The light source module 160 can be kept in a state of being in close contact with the side wall of the light guide plate 120 at all times. Since the size of the space for accommodating the light guide plate 120 of the frames 110 and 210 is also determined in accordance with the maximum variation width of the ambient temperature as described above, the thermally expanded light guide plate 120 may be bent or twisted There is no problem that the light guiding plate 120, which is prevented and thermally contracted, is detached from the frames 110 and 210 or loosened from the light source module 160.

The backlight device of the present invention can be widely applied when a backlight device is constituted by using a light guide plate made of a large PMMA plate having a severe degree of thermal expansion. Such a backlight device can be used as a large advertising panel by placing a desired film (not shown) on a light guide plate.

100, 200: backlight device 110, 210: frame
112: hinges 120: light guide plate
122: light guiding plate cover 130, 230: frame body
132, 232: guide portion 133: spring support portion
140, 240: cover frame 150, 250: light source frame
152: sliding part 160: light source module
162: LED 164: printed circuit board
170, 270: spring 190: thermoconductive grease
252: spring receiving portion 254: light receiving portion
272: Bolt

Claims (13)

A planar light guide plate which can be moved without being fixed;
A light source module closely disposed along at least one side of the light guide plate;
A light source frame disposed inside the light source module and the light guide plate and movably attached to the light guide plate in a planar direction without being fixed by itself;
A light guide plate support portion for supporting a periphery of a bottom surface of the light guide plate; A guiding part for guiding the slider part to move back and forth in a plane direction of the light guide plate while being slidably restrained by being inserted into the slider part as a part of the light source frame; And a spring support portion fixedly disposed between the light source frame and the light source frame, the spring support portion providing a spring receiving space having a variable spacing in a plane direction of the light guide plate, the variable interval being such that the slide portion always contacts the guide portion A frame body which is an interval that is variable within a range in which it is held in an interlaced and slidably restrained state; And
The light source frame is inserted into the spring accommodation space between the one side of the light source frame and the spring support portion in a compressed state to elastically press the light source frame toward the side of the light guide plate using the spring support as a stepping plate, And a spring for keeping the light source module in close contact with at least one side surface of the light guide plate regardless of a change in size in the planar direction along the light guide plate,
The upper side of the light source frame presses the upper surface of the edge of the light guide plate so that the light guide plate is not detached from the upper side of the light guide plate while the slide member of the light source frame is inserted into the guide portion and is held in a slidably restrained state by the elastic force of the spring Give,
When the spring is pulled out from one side of the light source frame and the spring support portion, the light source frame, the light source module, and the light guide plate are trapped in the frame body by the elastic force of the spring, And the light guiding plate is separated from the light guiding plate. The hinge of claim 1, further comprising a cover frame pivotally coupled to the frame body by the hinge and providing a downward force on the upper side of the frame body by an elastic force of the hinge Wherein the light guide plate is made of a transparent material. The backlight unit of claim 2, wherein the cover frame restrains the light source frame from coming out of engagement with the light guide plate when the cover frame is in the closed state with respect to the frame body. The light guide plate according to claim 1, wherein the spring is made of a metal plate and has a bent portion bent in a V-shape, a U-shape, or a W-shaped shape, and a staple portion bent in a planar direction of the light- Wherein the bent portion is a leaf spring inserted between the light source frame and the spring support portion, and the straddling portion is provided so as to cover the upper surface of the light source frame. 5. The light guide plate thermal expansion buffer backlight device of claim 4, wherein the light source frame and the bent portion of the spring abut against each other to be engaged with each other to prevent the spring from escaping easily. The light guide plate thermal expansion buffer backlight device according to claim 1, wherein the guide portion is provided in the form of a groove having an inlet opening toward a plane direction of the light guide plate. The light guide plate thermal expansion buffering backlight device according to claim 6, wherein a depth (g) of the groove of the guide portion is not smaller than a depth capable of accommodating a change in a maximum size due to thermal expansion according to a predetermined temperature change of the light guide plate . The light guide plate thermal expansion buffering backlight device according to claim 6, wherein a depth (g) of the groove of the guide portion is not greater than a height (f) from an upper surface of the light source module to an upper end of the sliding portion of the light source frame . The light guide plate thermal expansion buffer backlight device according to claim 6, wherein a length h of the light source frame in the plane direction of the light guide plate is smaller than a distance s between an upper end of the inlet of the guide part and the spring support part. 7. The apparatus of claim 6, wherein a distance s between an upper end of the inlet of the guide portion and the spring support portion is in a state before the spring reaches a critical compression state (a state where compression is maximally compressed and is no longer compressed) (S ') of the light source frame is smaller than the sum of the thickness d' of the spring and the length h in the planar direction of the light guide frame in a state (in which the state is compressed to 90% or less as compared with the critical compression state) &lt; h + d &quot;). &lt; / RTI &gt; 2. The apparatus of claim 1, wherein the spring is a coil spring,
Wherein the light source frame includes a light source accommodating part for accommodating and supporting the light source module in a first accommodating space provided only by a surface facing the light guide plate and the other surface being closed; And a second receiving space which is integrally connected to the lower side of the light source accommodating part and which is open at one side only to open in a direction opposite to the light source accommodating part, And a spring receiving portion provided with a through hole in a surface of the second accommodation space facing the light guide plate (hereinafter referred to as a 'spring support surface') and being inserted and slidably restrained in the guide portion,
Wherein the spring support portion is screwed on the light guide plate side surface of the guide portion through the through hole provided in the spring support surface and the head portion is integrally provided at the upper end of the screw column, It is a nearby bolt,
Wherein the coil spring is inserted between the head portion of the bolt and the spring supporting surface of the movable spring receiving portion while being extruded to the screw column of the bolt in a compressed state so that the head portion of the bolt, Wherein the light source frame pushes the light source frame, which is integrally coupled to the spring receiving portion, toward the light guide plate by applying an elastic force to the spring support surface toward the light guide plate. The light source module as claimed in claim 1, further comprising: a light source module that is charged between at least one of the light source frame and a part of the frame body and the light source module and quickly transfers heat generated in the light source module to at least one of the light source frame and the frame The light guide plate thermal expansion buffer type backlight device according to claim 1, further comprising a thermally conductive grease. The hinge of claim 2, wherein the hinge has a central spool portion and two arm members extending in two directions from the spool portion, wherein the two arm members are fixed to a hinge support portion provided at one side of each of the frame body and the cover frame So as to maintain the cover frame in a closed state with respect to the frame body by an elastic force that causes the two arm members to open at a larger angle.

Images