JP4301177B2 - Liquid crystal display - Google Patents

Description

  The present invention relates to a liquid crystal display device in which light emitted from a light source element is guided to a liquid crystal display side by a member constituting an optical waveguide so that display by a liquid crystal display can be performed. It is suitable for use.

  FIG. 7 shows a cross-sectional view of a liquid crystal display device used in a vehicle display instrument disclosed in Patent Document 1. As shown in this figure, the conventional liquid crystal display device includes a liquid crystal display J1, an optical member J2 such as an optical sheet and a diffusion sheet disposed on the back surface of the liquid crystal display J1, and a light emitting diode ( LED circuit composed of J3 (hereinafter referred to as LED) and a switching element for turning on and off the LED J3, an LED drive circuit unit for controlling the on / off timing of the LED J3 by the LED circuit, and a liquid crystal display A wiring board J4 on which a liquid crystal driving circuit unit used for driving J1 is formed, a light guide plate J5 that constitutes an optical waveguide that guides light emitted from the LED J3, and a reflector that directs light to the surface side of the light guide plate J5 J6 is included.

  In the liquid crystal display device configured as described above, on / off timing of energization of the LED by the LED circuit is controlled by the LED drive circuit unit, and light is emitted from the LED J3 based thereon. After this light is incident from the end surface of the light guide plate J5, the light is guided to the surface of the light guide plate J5 by the reflecting plate J6 provided on the back surface of the light guide plate J5, and the liquid crystal disposed on the surface side of the light guide plate J5. The display device J1 is irradiated with light. Thereby, light is illuminated from the back side of the liquid crystal display J1 driven by the liquid crystal drive circuit unit, and display on the liquid crystal display J1 is performed.

  In this liquid crystal display device, an LED circuit used for driving the LED J3, for example, a switching element in the LED circuit, generates heat when performing liquid crystal display. If the heat generated by the drive circuit is transmitted to the vicinity of the LED circuit and the parts, it will be affected. For example, the light guide plate J5 or the like is made of an acrylic plate or the like and is not high in heat durability. Therefore, there is a problem that the light guide plate J5 is deformed when heat generated by the LED circuit is transmitted. Further, when a portion where an advanced circuit is used, such as the liquid crystal display J1, is affected by heat, there arises a problem that correct drawing cannot be performed.

For this reason, the wiring board J4 on which the LED circuit is formed is composed of a metal heat sink, and this heat sink is structured to extend to the back side of the liquid crystal display device (the back side of the light guide plate). The heat radiating plate is made to function as a cooling module so that heat is radiated from the back surface of the liquid crystal display device.
JP 2004-279262 A

  However, in the above conventional liquid crystal display device, a heat radiating plate as a heat radiating member is directly joined to the drive circuit. For this reason, even if the heat sink is extended to a position far from the drive circuit, since the heat resistance of the heat sink is high, heat is dissipated even while heat is transmitted through the heat sink, and heat is applied to the components near the drive circuit. The above problem cannot be solved sufficiently. In addition, since a plate-like member called a heat radiating plate is used, heat is radiated in a wide range, and the vicinity of the drive circuit is likely to become hot.

  Therefore, the present inventors joined a heat transfer member excellent in transferring heat like a heat pipe to the drive circuit, and joined a heat dissipation member excellent in heat dissipation to this heat transfer member, The present inventors have devised a structure in which heat dissipation is performed at a position far from the drive circuit by separating the heat dissipation member from the drive circuit and being connected via the heat transfer member. With such a structure, the heat generated in the drive circuit is transmitted to the heat radiating member without being radiated so much by the heat pipe. For this reason, heat can be dissipated too much during the transfer of heat from the drive circuit to the heat dissipation member, and components that are vulnerable to heat such as a light guide plate arranged in the vicinity of the drive circuit or a liquid crystal drive circuit in the wiring board. It is possible to prevent the influence of heat from being transmitted, for example, the light guide plate is deformed or the liquid crystal display cannot perform correct drawing.

  FIG. 8 shows a cross-sectional view of the liquid crystal display device having such a structure. As shown in this figure, a light guide plate 5 constituting an optical waveguide is disposed on the back surface of a liquid crystal panel 1 serving as a liquid crystal display via optical components 2 to 4 such as a light diffusion sheet. A reflector combined case 6 that guides light to leak from the back side of the light guide plate 5 to the front side is disposed on the back side. An LED 8 serving as a light source is disposed at a position facing the side edge 5 a of the light guide plate 5, and is configured by a switching element for turning on and off the LED 8 so as to be directly connected to the LED 8. The LED circuit 9 corresponding to the driving circuit is provided.

  Further, on the back surface of the reflector combined case 6, the liquid crystal display control by the liquid crystal panel 1, that is, the liquid crystal driving circuit unit for driving the liquid crystal display, the on / off timing of the energization to the LED 8 by the LED circuit 9, and the like are controlled. A wiring board 7 on which an LED drive circuit section is formed is provided.

  In such a structure, the heat pipe 10c serving as a heat transfer member is directly connected to the LED circuit 8 serving as the drive circuit, and the heat pipe 10c extends, for example, to the back side of the wiring board 7, and the back side of the wiring board 7 is provided. The heat radiating member 10d is connected to the heat pipe 10c.

  According to such a structure, the heat radiating member 10d is separated from the LED circuit 8 serving as the drive circuit, and the heat generated in the LED circuit 8 through the heat pipe 10c having a small area and excellent in transferring heat. Is transmitted to the heat radiating member 10d. Therefore, heat is not radiated so much in the path from the LED circuit 8 to the heat radiating member 10d, and the heat radiating member 10d mainly radiates heat. For this reason, it is possible to prevent parts near the LED circuit 8 from being affected by heat.

  However, when such a structure was studied, it was confirmed that further problems could occur.

  Specifically, the heat pipe 10c has a shape that is horizontally extended from the LED circuit 8 and then bent upward. This is done in order to arrange the heat dissipating member 10d as high as possible in consideration of the influence of the surrounding air, which has become hot due to heat radiation by the heat dissipating member 10d, and escapes upward due to thermal convection. ing.

  For this reason, the water 12 contained in the heat pipe 10c (generally, about 10% of the volume of the hollow portion is contained in the heat pipe 10c) is heated when the heat pipe 10c becomes a heat transfer path. Thus, the water moves upward along the path of the heat pipe 10c, and when cooled, becomes water 12 again and is stored in the lower position.

  However, when the liquid crystal display device is exposed below the freezing point of water, for example, when the liquid crystal display device is used for a vehicle and the vehicle is exposed to below zero, the water 12 in the heat pipe 10c is frozen. become. Since the water 12 becomes ice in order from the top, when the water 12 at the lower position of the heat pipe 10c becomes ice, the water 12 at the upper position has already become ice, and the volume when the water 12 becomes ice. The expansion is applied to the heat pipe 10c as stress. For this reason, when such stress is repeatedly performed, problems such as cracks in the heat pipe 10c occur.

  Here, as shown in FIG. 7, the LED J3 is directly formed on the wiring board J4 on which the drive circuit is formed as a form in which the LED J3 is incorporated in the drive circuit. In some cases, the drive circuit may be separated. In this case, since the LED J3 is also a heat source that generates heat, the LED J3 is also emitted from the LED J3 by mounting the LED J3 on the metal substrate and connecting the heat sink to the metal substrate. Heat is released. For this reason, the same can be said with respect to such a configuration.

  In view of the above points, the present invention provides a liquid crystal display having a structure in which, when a heat pipe is used as a heat transfer member that connects a drive circuit and a heat radiating member, the heat pipe is not damaged by stress when water in the heat pipe freezes. An object is to provide an apparatus.

In order to achieve the above object, according to the first aspect of the present invention, the wiring board (7) is disposed opposite to the back surface of the optical waveguide (5), and the heat radiating member (10d) is opened to the atmosphere. The heat pipe (7d) is disposed opposite to the wiring board (7) and has a higher heat transfer coefficient than the heat dissipation member (10d), and transmits heat generated by the drive circuit (9) to the heat dissipation member (10d). 10c), and the heat pipe (10c) is arranged from the lower position toward the upper position from the drive circuit (9) toward the heat radiating member (10d), and the drive circuit of the heat pipe (10c) It is bent at an intermediate position (10ca) between the end located on the (9) side and the end located on the heat radiating member (10d) side, and the intermediate position (10ca) is on the drive circuit (9) side. End and heat sink Than an end portion located at (10d) side located downward, it is characterized in that it is storing water (12) to the intermediate position (lOca).

  In this way, the storage location of the water (12) stored in the heat pipe (10c) is not the tip position of the heat pipe (10c) but the intermediate position (10ca). For this reason, even if the heat pipe (10c) is used as the heat transfer member connecting the drive circuit (9) and the heat radiating member (10d), the heat pipe is caused by the stress when the water (12) in the heat pipe (10c) freezes. () 10c) can be structured so as not to break.

  For example, as shown in claim 3, the heat pipe (10c) is inclined on both sides of the intermediate position (10ca) with respect to the horizontal direction and the vertical direction, and protrudes downward at the intermediate position (10ca). By doing so, it is possible to realize the invention described in claim 1.

  The invention described in claim 2 is characterized by having the same structure as that of claim 1 in the case where the heat generated by the light source (8) is dissipated by the heat dissipating member (10d).

  According to such a configuration, even when the light source (8) and the drive circuit (9) are separated, the same effect as in the first aspect can be obtained.

  In the invention according to claim 4, the heat pipe (10c) is arranged from the lower position toward the upper position from the drive circuit (9) toward the heat radiating member (10d), and the heat pipe (10c). Are bent at the first and second intermediate positions (10ca, 10cb) between the end located on the drive circuit (9) side and the end located on the heat radiating member (10d) side. The second intermediate position (10ca, 10cb) is located below the end located on the drive circuit (9) side and the end located on the heat dissipation member (10d) side, and the first, Water (12) is stored between the second intermediate positions (10ca, 10cb).

  Thus, between the first and second intermediate positions (10ca, 10cb) is located below the end located on the drive circuit (9) side and the end located on the heat dissipation member (10d) side. By making the shape and storing water between the first and second intermediate positions (10ca, 10cb), an effect similar to that of the first aspect can be obtained.

  The invention according to claim 5 is characterized in that it has a structure similar to that of claim 4 when the heat generated by the light source (8) is dissipated by the heat dissipating member (10d).

  According to such a configuration, even when the light source (8) and the drive circuit (9) are separated, the same effect as in the fourth aspect can be obtained.

  In addition, the code | symbol in the bracket | parenthesis of each said means shows the correspondence with the specific means as described in embodiment mentioned later.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following embodiments, the same or equivalent parts are denoted by the same reference numerals in the drawings.

(First embodiment)
In the present embodiment, the present invention is applied to a liquid crystal display device in a display installed in an instrument panel of a vehicle. For example, examples of the display device include instruments such as a speedometer and a tachometer, a display device of a navigation device, and the like, and a liquid crystal display device displays a part or all of various displays performed on the display device.

  FIG. 1 is an exploded perspective view of a main part of the liquid crystal display device of the present embodiment, and FIG. 2 is a perspective view of the liquid crystal display device of the present embodiment. FIG. 3 is a cross-sectional view of a main part of the liquid crystal display device according to the present embodiment, and corresponds to a cross section when the main parts shown in FIG. 1 are assembled.

  As shown in FIG. 1, the liquid crystal display device includes a liquid crystal panel 1, optical sheets 2 and 3, a diffusion sheet 4, a light guide plate 5, a reflector combined case 6, a wiring board 7, an LED 8, an LED circuit 9, and a cooling module 10. Etc.

  The liquid crystal panel 1 employs a well-known TFT liquid crystal. As shown in FIG. 3, the optical sheets 2 and 3, the diffusion sheet 4, the light guide plate 5, the reflector combined case 6, and the wiring substrate 7 are sequentially stacked on the back surface (rear position) of the liquid crystal panel 1. As shown in FIG. 2, all of these are built in and held in a cover 11 that forms the outer shape of the liquid crystal display device.

  The optical sheets 2 and 3 do not reflect and transmit light incident on the sheet surface perpendicularly from the back surface side (the lower side in FIG. 1) of the sheet surface, and do not transmit light incident from a specific direction. The light passes through the sheet surface while being refracted in a direction perpendicular to the surface. Two optical sheets called optical sheets 2 and 3 are laminated, and the two optical sheets 2 and 3 are arranged so that the specific direction is different by 90 degrees.

  The diffusion sheet 4 transmits light incident from the back surface side (lower side in FIG. 1) of the diffusion sheet 4 to the front surface side (upper side in FIG. 1) while diffusing, and is uniform from the entire surface of the diffusion sheet 4. The light with uniform brightness is emitted toward the liquid crystal panel 1.

  The light guide plate 5 is a member constituting a transparent optical waveguide made of acrylic or the like. The light guide plate 5 guides light incident from the side edge 5a to the inside and emits it as illumination light from the surface 5b of the light guide plate. In the present embodiment, light is incident from only one of the four side edges 5a. However, in implementing the present invention, the light may be incident from other opposing surfaces.

  The reflector combined case 6 functions as a reflector having a portion constituting the reflector. The reflector combined case 6 is disposed in close contact with the back surface 5c of the light guide plate 5, and out of the light incident from the side edge 5a, light that leaks from the back surface 5c of the light guide plate 5 is guided by the light guide plate 5. It is reflected on the surface 5b side. The reflection plate in the reflection plate combined case 6 can improve the luminance of illumination light to the liquid crystal panel 1.

  The reflector combined case 6 also functions as a case for housing the optical sheets 2 and 3, the diffusion sheet 4, and the light guide plate 5. The LED circuit 9 and the cooling module 10 are fixed to one side surface of the reflector combined case 6. 4 is an enlarged view of the LED 8, the LED circuit 9, and the cooling module 10 in FIG. 2. As shown in this figure, the screw (FIG. 4) is threaded through the screw holes 9a and 10a provided in the LED circuit 9 and the cooling module 10. (Not shown) and fixed to one side surface of the reflector combined case 6 with screws.

  The wiring board 7 is provided with various circuits for driving the liquid crystal driving device, and is disposed on the back surface (rear position) of the reflector-use case 6. Specifically, the wiring board 7 includes a liquid crystal driving circuit unit used for driving the liquid crystal panel 1, an LED driving circuit unit for controlling on / off timing of energization of the LED 8 by the LED circuit 9, and the like. It has been.

  The LEDs 8 are arranged to face the side edges 5a of the light guide plate 5, and are arranged in a plurality in a direction perpendicular to the light guide plate 5 (up and down direction), and in a plurality in the direction perpendicular to the paper surface of FIG. Has been placed. The LED 8 is surface-mounted on the portion of the LED circuit 9 that faces the side edge 5 a of the light guide plate 5. The LED 8 employs a vertical light emitting diode that emits light in a direction perpendicular to the mounting surface on the wiring board 7.

  The LED circuit 9 is provided with a semiconductor switching element that performs on / off switching of energization to the LED 8. Each LED 8 is incorporated in a desired portion of the LED circuit 9 so that energization can be controlled by the semiconductor switching element of the LED circuit 9.

  The semiconductor switching element provided in the LED circuit 9 is controlled by an LED drive circuit unit provided in the wiring board 7. The LED circuit 9 is formed on, for example, an insulating film formed on a rectangular aluminum substrate, and is fixed to the reflector combined case 6 with screws through screw holes 9a formed on both sides in the longitudinal direction of the aluminum substrate. . In this way, by fixing the LED circuit 9 to the reflecting plate combined case 6, each LED 8 is arranged to face the side edge 5a of the light guide plate 5 as described above.

  The cooling module 10 includes a plate 10b, a heat pipe 10c attached to the plate 10b, and heat radiating fins 10d connected to the plate 10b via the heat pipe 10c.

  The plate 10b has the shape of the LED circuit 9, specifically, the same shape as the aluminum substrate on which the LED circuit 9 is formed, and is provided with screw holes 10a on both sides in the longitudinal direction. The plate 10b is made of aluminum, for example, and serves as a member for fixing the heat pipe 10c and the heat radiation fin 10d to the LED circuit 9.

  The heat pipe 10c functions as a heat transfer member excellent in heat transfer and having a high heat transfer rate, and is constituted by a pipe made of copper or copper alloy. In the pipe, 10% of the internal space of the pipe is used as a refrigerant. A volume 12 of water 12 is accommodated. For this reason, when the heat generated by the LED circuit 9 is transmitted to the heat pipe 10c via the plate 10b, exhaust heat is performed using the latent heat of evaporation and condensation of the water 12 accommodated in the heat pipe 10c. It has become. Since heat can be diffused by the heat pipe 10c without radiating much heat, a large amount of heat can be transported with a small temperature difference between the LED circuit 9 serving as a heat source and the radiation fin 10d.

  The heat pipe 10c has a structure in which one end is fixed to the plate 10b by welding or the like and bent upward at the intermediate position 10ca so that the other end extends toward the back surface of the liquid crystal display device. Yes. And the radiation fin 10d is being fixed to the other end side located above.

  The heat dissipating fins 10d function as heat dissipating members, and have a structure in which heat dissipating efficiency is improved by integrating a plurality of fins. Each of the plurality of fins constituting the heat radiating fin 10d is formed with a through hole (not shown), and the heat pipe 10c is in contact with all of the plurality of fins through each through hole. .

  In addition, the radiation fin 10d has a plurality of fins arranged in parallel. The plurality of fins are parallel to the top and bottom direction so that the surrounding air heated by heat radiation can be easily removed from the uppermost position of the heat radiating fins 10d, that is, air convection is easily performed. Yes. The mounting height of the heat dissipating fins 10d is equal to or higher than other members, specifically, the light guide plate 5 and the wiring board 7 that do not want to transmit heat. With such an arrangement, the heat dissipation efficiency of the heat dissipating fins 10d is increased, and the heated ambient air is less likely to move in the direction of the light guide plate 5 or the wiring board 7.

  The liquid crystal display device having such a configuration is tilted with respect to the vertical direction as shown in FIGS. Therefore, at least a part of the intermediate position 10ca, which is the bending point, of the heat pipe 10c provided in the liquid crystal display device is located at the lowest position, and both sides thereof, that is, one end and the other end of the heat pipe 10c are both intermediate positions. It becomes a structure which is located above 10ca. Therefore, in a situation where the display on the liquid crystal display device is not performed (a situation where the LED circuit 9 is not driven), the water 12 built in the heat pipe 10c is stored in the intermediate position 10ca. become.

  Next, the operation of the liquid crystal display device having the above configuration will be described.

  When the LED 8 is driven by the LED drive circuit unit provided in the LED circuit 9 and the wiring board 7, the light emitted from the LED 8 enters the side edge 5 a of the light guide plate 5 and is guided into the light guide plate 5. Thereafter, the light is emitted from the surface 5 b of the light guide plate 5 toward the diffusion sheet 4 as illumination light. At this time, the light that is about to leak out from the back surface 5 c of the light guide plate 5 is reflected to the front surface 5 b side by the reflective plate combination case 6.

  The light emitted from the surface 5b of the light guide plate 5 passes through the diffusion sheet 4, the optical sheet 3, and the liquid crystal panel 1, and is emitted from the liquid crystal panel 1 as predetermined display image light. When the liquid crystal panel 1 is driven by the display image light by the liquid crystal drive circuit unit provided on the wiring board 7, display on the liquid crystal panel 1 is performed.

  At this time, the heat generated by the LED circuit 9 is transmitted to the heat pipe 10c, and is transmitted to the heat radiating fin 10d using the heat pipe 10c as a heat transfer member. Specifically, the water 12 stored in the heat pipe 10c is evaporated by the heat transferred to the heat pipe 10c, and the steam moves upward, so that the heat is transferred to the radiating fin 10d side in a short time. Then, heat is radiated by the heat radiating fin 10d.

  Further, when the steam is cooled by the heat radiation from the radiation fins 10d, it is condensed and returned to the water 12, and again moves downward. Then, the water 12 is evaporated again by the heat transferred to the heat pipe 10c, so that it is used for heat dissipation by the same mechanism as described above. In this way, the heat generated by the LED circuit 9 is effectively dissipated.

  On the other hand, when the ambient temperature of the liquid crystal display device falls to below zero, the water 12 in the heat pipe 10c begins to freeze. In such a situation, since the water 12 is stored in the intermediate position 10ca, for example, even if the water 12 freezes from the radiation fin 10d side, a space in the heat pipe 10c is left also on the LED circuit 9 side. As a result, the volume-expanded ice can move to the space as compared with the water 12.

  For this reason, the stress at the time of the water 12 in the heat pipe 10c freezing can be released, thereby preventing the heat pipe 10c from being damaged.

  As described above, according to the liquid crystal display device of the present embodiment, the storage location of the water 12 stored in the heat pipe 10c is not the tip position of the heat pipe 10c but the intermediate position 10ca. For this reason, even if the heat pipe 10c is used as the heat transfer member connecting the LED circuit 9 and the heat radiating fin 10d, the heat pipe 10c is not damaged by the stress when the water 12 in the heat pipe 10c freezes. Can do.

(Second Embodiment)
A second embodiment of the present invention will be described. Since the basic structure of the liquid crystal display device of this embodiment is the same as that of the first embodiment, only the parts different from the first embodiment will be described here. FIG. 5 shows a cross-sectional configuration of the main part of the liquid crystal display device of the present embodiment.

  As shown in FIG. 5, in the liquid crystal display device of the present embodiment, the liquid crystal display device is not configured to be tilted, and in the heat pipe 10 c at an intermediate position 10 cb on the left side of the drawing with respect to the LED circuit 9. The heat pipe 10c is bent. That is, one end of the heat pipe 10c on the LED circuit 9 side is directed upward.

  In the case of such a structure, the water 12 is stored between the bent middle positions 10ca and 10cb of the heat pipe 10c. For this reason, even if the ambient temperature of the liquid crystal display device drops to below zero and the water 12 freezes, there remains a space in which the volume-expanded ice can move as compared to the water 12 as in the first embodiment. . Therefore, the same effect as that of the first embodiment can be obtained.

(Other embodiments)
In each of the above embodiments, the radiation fin 10d corresponding to the heat radiating member and the LED circuit 9 serving as the heat generation source are separated from each other and are connected only via the heat pipe 10c corresponding to the heat transfer member. However, this is merely an example. In addition to the heat pipe 10c, other heat transfer parts (for example, a metal sheet, a carbon sheet attached to an aluminum plate, a conductive resin containing a conductive member, etc.) May be used together. For example, as shown in FIG. 6, an extending portion 10e is provided such that a plate 10b made of aluminum extends to the heat radiating fin 10d similarly to the heat pipe 10c, and the heat pipe 10c is embedded in the extending portion 10e. The extending portion 10e may be configured to be used as a heat transfer member.

  In addition, when using the heat pipe 10c, even if the metal plate 10e used with the heat pipe 10c is a thing with a large heat resistance and excellent heat dissipation, heat dissipation fins that efficiently use the heat pipe 10c as a heat dissipation member Since it is transmitted to the 10d side, even if heat is radiated from the extended portion 10e, the heat radiation amount is small. Therefore, even if the extending part 10e used with the heat pipe 10c is excellent in heat dissipation, the influence of heat can be reduced. In such a case, since the heat pipe 10c is used, the present invention can be applied.

  In the above embodiment, the case where the heat radiation fin 10d is used as a heat radiation member has been described. These can also be used as heat dissipation members. In this case, the heat radiating member and the drive circuit are not physically separated from each other, but the heat pipe 10c allows heat to be transferred in a short time to a position far from the drive circuit in the heat radiating member. Even if the heat dissipation member is not physically separated from the drive circuit, it is possible to suppress the influence of heat generated from the drive circuit.

  In the above-described embodiment, the LED 8 is incorporated in the LED circuit 9 as a form in which the LED 8 is incorporated. The LED 8 is directly formed on the plate 10b on which the LED circuit 9 is patterned. In some cases, the form is separated. In this case, since the LED 8 serving as the light source is also a heat source that generates heat, the LED 8 is also mounted on the metal substrate and the heat pipe 10c is connected to the metal substrate. The heat generated by the LED 8 is released. For this reason, also regarding such a form, the effect similar to the said embodiment can be acquired by setting it as the form which water is stored in the intermediate position of the heat pipe 10c.

It is a disassembled perspective view of the principal part of the liquid crystal display device in 1st Embodiment of this invention. 1 is a perspective view of a liquid crystal display device according to a first embodiment of the present invention. It is sectional drawing at the time of cut | disconnecting the principal part of the liquid crystal display device shown in FIG. It is an enlarged view of the cooling module in FIG. It is sectional drawing which cut | disconnected the principal part of the liquid crystal display device in 2nd Embodiment of this invention in the up-down direction. It is an enlarged view of the cooling module demonstrated by other embodiment. It is sectional drawing which cut | disconnected the main part of the conventional liquid crystal display device in the up-down direction. It is sectional drawing which cut | disconnected the principal part of the liquid crystal display device which the present inventors examined in the up-down direction.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Liquid crystal panel 2, 3 ... Optical sheet, 4 ... Diffusion sheet, 5 ... Light guide plate, 6 ... Reflector combined case, 7 ... Wiring board, 8 ... LED, 9 ... LED circuit, 10 ... Cooling module, 10b ... Plate, 10c ... Heat pipe, 10ca, 10cb ... Intermediate position, 10d ... Radiation fin, 12 ... Water.

Claims (5)

A liquid crystal display (1) for performing desired display with liquid crystal;
A light source (8) for illuminating the liquid crystal display (1);
An optical waveguide (5) disposed on the back side of the liquid crystal display (1) and emitting light from the light source (8) toward the liquid crystal display (1);
A wiring board (7) provided with a liquid crystal driving circuit unit for driving the liquid crystal display (1);
A drive circuit (9) that performs on-off drive of the light source (8) and serves as a heat source for generating heat;
In a liquid crystal display device comprising a heat radiating member (10d) for radiating heat generated by the drive circuit (9),
The wiring substrate (7) is disposed opposite to the back surface of the optical waveguide (5), and the heat radiating member (10d) is disposed opposite to the wiring substrate (7) through a gap opened to the atmosphere. ,
A heat pipe (10c) is formed of a member having a higher heat transfer coefficient than the heat dissipation member (10d), and transmits heat generated by the drive circuit (9) to the heat dissipation member (10d).
The heat pipe (10c) is arranged from the lower position toward the upper position from the drive circuit (9) toward the heat radiating member (10d), and the drive circuit ( 9) is bent at an intermediate position (10ca) between an end located on the side and an end located on the heat radiating member (10d), and the intermediate position (10ca) is bent at the drive circuit (9). A liquid crystal display device characterized in that water (12) is stored at an intermediate position (10ca) located below an end located on the side and an end located on the heat radiating member (10d) side. . A liquid crystal display (1) for performing desired display with liquid crystal;
A light source (8) serving as a heat source for illuminating the liquid crystal display (1) and generating heat;
An optical waveguide (5) disposed on the back side of the liquid crystal display (1) and emitting light from the light source (8) toward the liquid crystal display (1);
A wiring board (7) provided with a liquid crystal driving circuit unit for driving the liquid crystal display (1);
A drive circuit (9) for performing on-off drive of the light source (8);
In a liquid crystal display device comprising a heat radiating member (10d) for radiating heat generated by the light source (8),
The wiring substrate (7) is disposed opposite to the back surface of the optical waveguide (5), and the heat radiating member (10d) is disposed opposite to the wiring substrate (7) through a gap opened to the atmosphere. ,
A heat pipe (10c) is formed of a member having a higher heat transfer coefficient than the heat dissipation member (10d), and transmits heat generated by the light source (8) to the heat dissipation member (10d).
The heat pipe (10c) is arranged from the lower position toward the upper position from the light source (8) toward the heat radiating member (10d), and the light source (8) of the heat pipe (10c). Is bent at an intermediate position (10ca) between an end located on the side and an end located on the heat radiating member (10d), and the intermediate position (10ca) is located on the light source (8) side. The liquid crystal display device is characterized in that water (12) is stored in the intermediate position (10ca), which is positioned below the end portion and the end portion located on the heat radiating member (10d) side.   The heat pipe (10c) is inclined with respect to the horizontal direction and the vertical direction on both sides of the intermediate position (10ca), and has a shape protruding downward at the intermediate position (10ca). The liquid crystal display device according to claim 1, wherein the liquid crystal display device is a liquid crystal display device. A liquid crystal display (1) for performing desired display with liquid crystal;
A light source (8) for illuminating the liquid crystal display (1);
An optical waveguide (5) disposed on the back side of the liquid crystal display (1) and emitting light from the light source (8) toward the liquid crystal display (1);
A wiring board (7) provided with a liquid crystal driving circuit unit for driving the liquid crystal display (1);
A drive circuit (9) that performs on-off drive of the light source (8) and serves as a heat source for generating heat;
In a liquid crystal display device comprising a heat radiating member (10d) for radiating heat generated by the drive circuit (9),
The wiring substrate (7) is disposed opposite to the back surface of the optical waveguide (5), and the heat radiating member (10d) is disposed opposite to the wiring substrate (7) through a gap opened to the atmosphere. ,
A heat pipe (10c) is formed of a member having a higher heat transfer coefficient than the heat dissipation member (10d), and transmits heat generated by the drive circuit (9) to the heat dissipation member (10d).
The heat pipe (10c) is arranged from the lower position toward the upper position from the drive circuit (9) toward the heat radiating member (10d), and the drive circuit ( 9) It is bent at first and second intermediate positions (10ca, 10cb) between the end located on the side and the end located on the heat radiating member (10d) side, and the first and second The intermediate position (10ca, 10cb) is located below the end located on the drive circuit (9) side and the end located on the heat radiating member (10d) side. 2. A liquid crystal display device, wherein water (12) is stored between two intermediate positions (10ca, 10cb). A liquid crystal display (1) for performing desired display with liquid crystal;
A light source (8) serving as a heat source for illuminating the liquid crystal display (1) and generating heat;
An optical waveguide (5) disposed on the back side of the liquid crystal display (1) and emitting light from the light source (8) toward the liquid crystal display (1);
A wiring board (7) provided with a liquid crystal driving circuit unit for driving the liquid crystal display (1);
A drive circuit (9) for performing on-off drive of the light source (8);
In a liquid crystal display device comprising a heat radiating member (10d) for radiating heat generated by the light source (8),
The wiring substrate (7) is disposed opposite to the back surface of the optical waveguide (5), and the heat radiating member (10d) is disposed opposite to the wiring substrate (7) through a gap opened to the atmosphere. ,
A heat pipe (10c) is formed of a member having a higher heat transfer coefficient than the heat dissipation member (10d), and transmits heat generated by the light source (8) to the heat dissipation member (10d).
The heat pipe (10c) is arranged from the lower position toward the upper position from the light source (8) toward the heat radiating member (10d), and the light source (8) of the heat pipe (10c). The first and second intermediate positions are bent at first and second intermediate positions (10ca and 10cb) between the end located on the side and the end located on the heat radiating member (10d) side. (10ca, 10cb) is located below the end located on the light source (8) side and the end located on the heat radiating member (10d) side, and the first and second intermediate positions A liquid crystal display device in which water (12) is stored between (10ca, 10cb).

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