JP2014194489A - Liquid crystal display module - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a liquid crystal display module having a bezel structure which suppresses a twist of a large and thin type liquid crystal panel such as an 80-inch model or a 90-inch model.SOLUTION: A bezel structure 120 of a large and thin type liquid crystal module 100 such as an 80-inch model or a 90-inch model comprises an upper-side bezel 121 and a lower-side bezel 122 which are integrated moldings of "U-shape" in a longer direction while not having a separation part "d" nearby four corners of a liquid crystal panel 110. The upper-side bezel 121 and lower-size bezel 122 are separated at a laterally center part of the liquid crystal panel 110, so separation parts "d" are present at right- and left-side laterally center parts of the liquid crystal panel 110. Thus the bezel structure 120 do not have the separation part "d" nearby the four corners, so the bezel structure 120 has stronger force for holding the liquid crystal panel 110 so as to suppress the liquid crystal panel 110 from twisting even when the load of the whole liquid crystal panel 110 is placed on the bezel structure 120.

Description

  The present invention relates to a liquid crystal display module including a liquid crystal panel and a backlight, and more particularly to a liquid crystal display module in which the liquid crystal panel is held by a bezel attached to an outer frame frame of the liquid crystal panel.

  In a liquid crystal display module including a liquid crystal panel and a backlight, the liquid crystal panel is held by a bezel. A conventional bezel mounting structure will be described with reference to FIGS.

  The liquid crystal panel 410 of the conventional liquid crystal display module 400 shown in FIG. 4A has four parts (hereinafter referred to as “pieces”): an upper side long bezel 421, a lower side long bezel 422, a left side short bezel 423, and a right side short bezel 424. ”). In such a bezel structure 420, the upper long bezel 421 and the left short bezel 423 are separated by a corner portion (hereinafter referred to as “corner”) on the upper left side of the liquid crystal panel 410. it can. Similarly, since the upper side long bezel 421 and the right side short bezel 424 are divided by the upper right corner of the liquid crystal panel 410, a separation part d is formed at the corner. Further, since the lower long bezel 422 and the left short bezel 423 are separated by the lower left corner of the liquid crystal panel 410, a separation part d is formed at the corner. Similarly, the lower long bezel 422 and the right short bezel 424 are separated by the lower right corner of the liquid crystal panel 410, so that a separation portion d is formed at the corner. Further, screws 421 a and 421 b are inserted into both ends of the upper side long bezel 421, so that the upper side long bezel 421 is fixed to the liquid crystal panel 410. Similarly, screws 422 a and 422 b are inserted into both ends of the lower side long bezel 422, so that the lower side long bezel 422 is fixed to the liquid crystal panel 410. The screws 423 a and 423 b are inserted into both ends of the left side short bezel 423, whereby the left side short bezel 423 is fixed to the liquid crystal panel 410. Screws 424 a and 424 b are inserted into both ends of the right side short bezel 424, so that the right side short bezel 424 is fixed to the liquid crystal panel 210. However, as shown in FIG. 4A, the separation part d of the bezel structure 420 is at the corners of the four corners of the liquid crystal panel 410, so the bezel structure 420 becomes a very weak structure and the liquid crystal panel 410 is twisted. There was something to do. For this reason, the separation part d is coupled with a metal screw.

  Compared with the bezel structure 420 of the liquid crystal display module 400, the liquid crystal display module 500 including the conventional liquid crystal panel 510 shown in FIG. 4B has a structure that can suppress the twist of the liquid crystal panel 510. The liquid crystal panel 510 of the conventional liquid crystal display module 500 shown in FIG. 4B has a bezel composed of four pieces: an upper side long bezel 521, a lower side long bezel 522, a left side short bezel 523, and a right side short bezel 524. Retained in structure 520. In such a bezel structure 520, the upper side long bezel 521 and the left side short bezel 523 are separated slightly inside the upper left corner of the liquid crystal panel 410, so that a separation part d is formed slightly inside the corner. Similarly, since the upper side long bezel 521 and the right side short bezel 524 are separated slightly inside the upper right corner of the liquid crystal panel 410, a separation part d is formed slightly inside the corner. Further, since the lower long bezel 522 and the left short bezel 523 are separated slightly inside the lower left corner of the liquid crystal panel 410, a separation part d is formed slightly inside the corner. Similarly, since the lower long bezel 522 and the right short bezel 524 are separated slightly inside the lower right corner of the liquid crystal panel 410, a separation portion d is formed slightly inside the corner. Further, screws 521 a and 521 b are inserted into both ends of the upper side long bezel 521, so that the upper side long bezel 521 is fixed to the liquid crystal panel 510. Similarly, screws 522 a and 522 b are inserted into both ends of the lower side long bezel 522, so that the lower side long bezel 522 is fixed to the liquid crystal panel 510. Screws 523 a and 523 b are inserted into both ends of the left side short bezel 523, whereby the left side short bezel 523 is fixed to the liquid crystal panel 510. Screws 524 a and 524 b are inserted into both ends of the right-side short bezel 524, so that the right-side short bezel 524 is fixed to the liquid crystal panel 210. In the liquid crystal display module 500, the separation part d is not the corner of the liquid crystal panel 510, but near the upper and lower corners of the liquid crystal panel 510, and the separation part d is coupled by metal screw tightening. With this structure, the bezel structure 520 of the liquid crystal display module 500 has the bezel structure 420 of the liquid crystal display module 400 having the separation portions d at the four corners of the liquid crystal panel 410 as shown in FIG. As compared with the above, twist of the liquid crystal panel 510 can be suppressed.

  However, in a large and thin liquid crystal panel such as 80 type or 90 type, since the width of the outer frame frame of the liquid crystal panel becomes narrow, it is not possible to provide a screw tightening part at the separation part d which is the joint of the bezel pieces. . For this reason, the separation part d could not be coupled with metal screws. Therefore, the separation part d of the bezel structure in a large and thin liquid crystal panel such as 80 type or 90 type is not connected by screw fastening, and the separation part d of the bezel is formed inside the bezel using a molded product called P chassis. Are connected.

  Japanese Patent Application Laid-Open No. 2010-271660 (Patent Document 1) can be cited as a technique for preventing a step from occurring in a connecting portion of a bezel surrounding a liquid crystal panel in a liquid crystal module. The technique disclosed in Patent Document 1 provides a liquid crystal module that eliminates a step by aligning the heights of both bezel end portions in a connecting portion even if there is some deformation or distortion. Japanese Patent Laid-Open No. 2002-6292 (Patent Document 2) can be cited as a technique for preventing the deformation of the bezel in the liquid crystal display device. In the technique disclosed in Patent Document 2, a protrusion is formed on the bezel side between the frame (P chassis) and the bezel to prevent the bezel from being deformed, and the light from the backlight is generated by the bezel floating from the frame. A liquid crystal display device that prevents leakage from between a frame and a bezel is provided.

JP 2010-271660 A JP 2002-6292 A

  As described above, the liquid crystal module according to the technique disclosed in Patent Document 1 is connected to the bezel in the vicinity of the four corners so as to eliminate the step by aligning its height, thereby eliminating the deformation and distortion of the liquid crystal module. The appearance is not impaired. In addition, the liquid crystal display device according to the technique disclosed in Patent Document 2 is configured such that the structure of the bezel is integrated in a square frame shape, and a protrusion is formed on the bezel side to prevent the bezel from being deformed. Due to the deformation, the light of the backlight is prevented from leaking between the frame (P chassis) and the bezel.

  In the large and thin liquid crystal panel 510 such as the 80 type or the 90 type, for example, a load of the entire liquid crystal panel 510 is applied to the bezel structure 520 of the liquid crystal panel 510 illustrated in FIG. However, since the bezel structure 520 has four separation parts d in the vicinity of the upper and lower corners of the liquid crystal panel 510, a large and thin liquid crystal panel 510 such as an 80 type or a 90 type is shown in FIG. Twist like. In other words, the bezel structure 520 has a weak force for holding the liquid crystal panel 510 in the vicinity of the corner of the liquid crystal panel 510. Therefore, the upper surface 530 and the lower surface 540 of the liquid crystal panel 510 are displaced in opposite directions with respect to the center. Twisting occurs. For this reason, the twist of the liquid crystal panel 510 cannot be suppressed only by connecting the bezels in the vicinity of the four corners and aligning the heights thereof as in Patent Document 1. On the other hand, as in Patent Document 2, the twist of the liquid crystal panel 510 can be suppressed by integrally forming the bezel with a rectangular frame shape. However, in the large and thin liquid crystal panel 510 such as the 80 type and the 90 type, instead of dividing into four pieces as in the bezel structure 520, a single-piece bezel connected in a square frame shape as in Patent Document 2 is used. Since the bezel mold itself becomes large, the manufacturing cost of the bezel increases.

  This invention is made | formed in view of such a condition, and it aims at providing the technique which can solve the said subject.

The liquid crystal display module of the present invention is characterized in that, in a bezel structure for holding a liquid crystal panel, a separation portion is provided only at the central portion of the side of the liquid crystal panel.
In the liquid crystal display module of the present invention, the central portion is a central portion of a short side.
In addition, the side of the liquid crystal display module of the present invention is characterized in that it is separated into a U shape at the central portion of the short side.
Further, the liquid crystal display module of the present invention is characterized in that the central portion is a central portion of a long side.
In addition, the side of the liquid crystal display module of the present invention is characterized by being separated into a U-shape at the central portion of the long side.

  ADVANTAGE OF THE INVENTION According to this invention, the liquid crystal display module by which a liquid crystal panel is hold | maintained by the bezel which can suppress the twist of large and thin liquid crystal panels, such as 80 type | mold and 90 type | mold, and can be manufactured without high cost can be provided.

It is a figure explaining the twist in the bezel structure and bezel structure of the liquid crystal display module which concerns on embodiment of this invention. It is a figure which shows the allowable target value with respect to the twist of the liquid crystal panel which concerns on embodiment of this invention. It is a figure which shows the example of the other bezel structure similar to the bezel structure of the liquid crystal display module which concerns on embodiment of this invention. It is a figure which shows the bezel structure of the conventional liquid crystal display module. It is a figure explaining the twist in the bezel structure and bezel structure of the conventional liquid crystal display module.

  Hereinafter, modes for carrying out the present invention (hereinafter referred to as embodiments) will be described with reference to the drawings. In the embodiment of the present invention, the bezel structure is divided into two pieces, an upper side and a lower side, and these two pieces are integrally molded with a “U-shape” to give rigidity, and four corners are provided. Is held by this integrally molded bezel to suppress twisting of the liquid crystal panel.

  First, the bezel structure of the embodiment will be described with reference to FIG. A liquid crystal panel 110 included in the liquid crystal display module 100 shown in FIG. 1A is held by a bezel structure 120 (not shown). The bezel structure 120 is constituted by a piece that is an integral molding of two “U” shapes, an upper side bezel 121 and a lower side bezel 122. In such a bezel structure 120, as shown in the enlarged view of FIG. 1, since the corner of the upper side bezel 121 is integrally molded, there is no separation part d in the corner. Similarly, since the corner of the lower bezel 122 is integrally molded, there is no separation part d at the corner. Since the upper side bezel 121 and the lower side bezel 122 are separated by the horizontal center portion of the liquid crystal panel 110, the left and right lateral center portions of the liquid crystal panel 110 have separation portions d. Further, screws 121 a and 121 b are inserted into both ends of the upper bezel 121, so that the upper bezel 121 is fixed to the liquid crystal panel 110. Similarly, screws 122 a and 122 b are inserted into both ends of the lower bezel 122, so that the lower bezel 122 is fixed to the liquid crystal panel 110.

  In such a large and thin liquid crystal panel 110 such as the 80 type or 90 type shown in FIG. 1A, the load of the entire liquid crystal panel 110 is applied to the bezel structure 120 of the liquid crystal panel 110 shown in FIG. It is done. However, the bezel structure 120 is composed of an upper side bezel 121 and a lower side bezel 122 in which the longitudinal direction in which the upper and lower corners of the liquid crystal panel 110 are not formed with separation portions d is integrally formed in a “U” shape. Therefore, the large and thin liquid crystal panel 110 such as 80 type or 90 type can suppress twist as shown in FIG. In other words, the bezel structure 120 has a strong force for holding the liquid crystal panel 110 near the corner of the liquid crystal panel 110, and thus the liquid crystal panel 110 is displaced by the positions of the upper surface 130 and the lower surface 140 of the liquid crystal panel 110 being opposite to each other in the opposite direction. Can be prevented from twisting. FIG. 2 shows a design target allowable angle (hereinafter referred to as “target allowable angle”) with respect to twist in the liquid crystal panel 110. The target allowable angle is an angle allowed for twisting in order to maintain high quality without deteriorating the appearance. In the liquid crystal panel 110 of the liquid crystal display module 100 including the bezel structure 120, when the twist of the upper surface 130 is measured, the target allowable angle shown in FIG. 2 is within a range of 0.5 degrees. Further, since the upper bezel 121 and the lower bezel 122 are the same “U” -shaped pieces, they can be manufactured using the same mold.

  Next, another example of the bezel structure similar to the bezel structure 120 of the liquid crystal display module 100 in the embodiment will be described with reference to FIG.

  As described above, the bezel structure 120 of the liquid crystal display module 100 shown in FIG. 3A has the separation part d at the left and right lateral center portions of the liquid crystal panel 110. Further, since the upper side bezel 121 and the lower side bezel 122 are the same “U” -shaped pieces, there are two pieces per unit.

  A liquid crystal panel 210 provided in the liquid crystal display module 200 shown in FIG. 3B is held by a bezel structure 220 formed of two “U” -shaped pieces, that is, a left side bezel 221 and a right side bezel 222. Yes. In such a bezel structure 220, since the corner of the left-side bezel 221 is integrally molded, there is no separation part d at the corner. Similarly, since the corner of the right-side bezel 222 is integrally molded, there is no separation part d at the corner. Since the left-side bezel 221 and the right-side bezel 222 are separated by the vertical center portion of the liquid crystal panel 210, the upper and lower vertical center portions of the liquid crystal panel 210 have separation portions d. Further, the left bezel 221 is fixed to the liquid crystal panel 210 by inserting screws 221 a and 221 b into both ends of the left bezel 221. Similarly, screws 222 a and 222 b are inserted into both ends of the right side bezel 222, so that the right side bezel 222 is fixed to the liquid crystal panel 210. Thus, the bezel structure 220 has the separation part d in the vertical center part on the upper side and the lower side of the liquid crystal panel 210. In addition, the left-side bezel 221 and the right-side bezel 222 are the same “U” -shaped piece, and thus are two pieces per unit.

  A liquid crystal panel 310 included in the liquid crystal display module 300 illustrated in FIG. 3C is an integral molding of four “U” shapes, that is, an upper left side bezel 321, an upper right side bezel 322, a lower left side bezel 323, and a lower right side bezel 324. It is held by a bezel structure 320 composed of a piece. In such a bezel structure 320, the corner of the upper left side bezel 321 is integrally molded, and therefore there is no separation part d at the corner. Similarly, since the corner of the upper right side bezel 322 is integrally molded, there is no separation part d at the corner. Since the corner of the lower left side bezel 323 is integrally molded, there is no separation part d at the corner. Since the corner of the lower right side bezel 324 is integrally formed, there is no separation part d at the corner. Since the upper left side bezel 321 and the upper right side bezel 322 are separated by a vertical center portion on the upper side of the liquid crystal panel 310, a separation part d is provided in the vertical center portion on the upper side of the liquid crystal panel 310. Since the upper left side bezel 321 and the lower left side bezel 323 are separated by the horizontal center portion on the left side of the liquid crystal panel 310, the separation portion d is provided in the horizontal center portion on the left side of the liquid crystal panel 310. The upper right side bezel 322 and the lower right side bezel 324 are separated by the lateral center portion on the right side of the liquid crystal panel 310, so that the separation portion d is provided at the lateral center portion on the right side of the liquid crystal panel 310. Since the lower left side bezel 323 and the lower right side bezel 324 are separated by a vertical center portion on the lower side of the liquid crystal panel 310, a separation part d is provided in the vertical center portion on the lower side of the liquid crystal panel 310. Further, screws 321 a and 321 b are inserted into both ends of the upper left side bezel 321, whereby the upper left side bezel 321 is fixed to the liquid crystal panel 310. Similarly, screws 322 a and 322 b are inserted into both ends of the upper right side bezel 322, so that the upper right side bezel 322 is fixed to the liquid crystal panel 310. Screws 323 a and 323 b are inserted into both ends of the lower left side bezel 323, so that the lower left side bezel 323 is fixed to the liquid crystal panel 310. Screws 324 a and 324 b are inserted into both ends of the lower right side bezel 324, so that the lower right side bezel 324 is fixed to the liquid crystal panel 310. As described above, the bezel structure 320 includes the separation portions d in the upper and lower vertical center portions of the liquid crystal panel 310 and the left and right lateral center portions. Further, the upper left side bezel 321, the upper right side bezel 322, the lower left side bezel 323, and the lower right side bezel 324 are the same “<” shape pieces, so there are four pieces per unit.

Next, the bezel structure 120 of the liquid crystal display module 100 shown in FIG. 3 (1), the bezel structure 220 of the liquid crystal display module 200 shown in FIG. 3 (2), and the bezel structure of the liquid crystal display module 300 shown in FIG. 3 (3). Compare 320 strengths. The strongest structure among them is a bezel structure 120 in which a separation part d is provided at the lateral center of the liquid crystal panel 110. In a bezel structure having a long side and a short side, if there is a separation part d on the long side that receives the load of the liquid crystal panel, the liquid crystal panel bends in the direction of the long side, so that the entire long side receives the load. For this reason, when the long side is formed into a “U” -shaped integrated frame shape, it becomes strong because there is no separation part d on the long side, and bending of the liquid crystal panel can be suppressed. Therefore, the bezel structure 120 having no separation part d in the longitudinal center part is stronger than the bezel structure 220 having the separation part d in the longitudinal center part. The weakest bezel structure is a bezel structure 320 having four separation portions d in the vertical center portion and the horizontal center portion of the liquid crystal panel 310. Since the bezel structure 320 has four pieces per unit, the mold can be reduced and the manufacturing cost can be reduced. However, since the separation part d is provided on the long side and the short side, the structure becomes the weakest.
Thus, the strongest structure is the bezel structure 120, the next strongest structure is the bezel structure 220, and the weakest structure is the bezel structure 320. Thus, although these three bezel structures 120, bezel structures 220, and bezel structures 320 are strong and weak, there are no separation parts d near the corners of the four corners, so that the conventional bezel structure 420 and the bezel structure 520 It is a strong structure. Therefore, the bezel structure 120, the bezel structure 220, and the bezel structure 320 can be applied to a liquid crystal display module including a large and thin liquid crystal panel such as an 80 type or a 90 type.

  In the embodiment, the screws 121a and 121b are inserted into both ends of the upper bezel 121 of the bezel structure 120, and the screws 122a and 122b are inserted into both ends of the lower bezel 122 of the bezel structure 120. The bezel 122 is fixed to the liquid crystal panel 110, but the upper bezel 121 and the lower bezel 122 can be fixed to the liquid crystal panel 110 as long as the upper bezel 121 and the lower bezel 122 can be fixed to the liquid crystal panel 110. Moreover, although the target allowable angle is set as 0.5 degrees, the value is not limited to this value as long as high quality can be maintained without deteriorating the appearance of the liquid crystal display panel. Further, in the bezel structure 120, the separation part d is provided in the left and right lateral central portions of the liquid crystal panel 110. However, there is some error in the lateral central portion as long as the effect of the embodiment is within the range. Also good. In the bezel structure 220, the separation portion d is provided at the vertical center portion on the upper side and the lower side of the liquid crystal panel 210. However, as long as the effect of the embodiment is within the range, even if there is some error in the vertical center portion. Good. Similarly, in the bezel structure 320, the upper and lower vertical center portions of the liquid crystal panel 310 and the left and right lateral center portions have the separation portions d. There may be some errors in the vertical center and the horizontal center.

  According to the liquid crystal display module 100 of the above-described embodiment, the upper side bezel 121 and the lower side of the “U” -shaped integrally formed with no separation part d in the vicinity of the four corners of the liquid crystal panel 110 in the longitudinal direction of the bezel structure 120. The bezel 122 is provided with rigidity, and the twist of the liquid crystal panel 110 is suppressed. Further, by suppressing the twist of the liquid crystal panel 110, the completeness of the quality of appearance can be increased in the large-sized thin high-priced liquid crystal display module 100 such as the 80 type or the 90 type. Further, since the bezel structure 120 has two pieces per one of the upper side bezel 121 and the lower side bezel 122, the mold becomes smaller and the manufacturing cost can be reduced as compared with the integrally formed bezel connected to the square frame shape. it can.

  According to such an embodiment, it is possible to provide a liquid crystal display module in which the liquid crystal panel is held by a bezel that can prevent the twisting of a large and thin liquid crystal panel such as 80 type or 90 type and can be manufactured without high cost. .

  In the above, it demonstrated based on embodiment of this invention. This embodiment is an exemplification, and it will be understood by those skilled in the art that various modifications can be made to combinations of these components, and such modifications are also within the scope of the present invention.

DESCRIPTION OF SYMBOLS 100 ..... Liquid crystal display module 110 ........ Liquid crystal panel 120 ..... Bezel structure 121 ........ Upper bezel 121a, 121b ... Screw 122 ... Lower side bezel 122a, 122b ... Screw 130 ... Upper surface of liquid crystal panel 140 ... Lower surface of liquid crystal panel 200 ... ... Liquid crystal display module 210 ... Liquid crystal panel 220 ... Bezel structure 221 ... Left side bezel 221a, 221b ... Screw 222 ... ··· Right side bezel 222a, 222b ··· Screw 300 ························································································・ ・ ・ ・ ・ Upper left bezel 321a, 321b ··· Screw 322 ··· Upper right side bezel 322a, 322b ··· Screw 323 ··· Lower left side bezel 323a, 323b ··· Screw 324 ·····・ Lower right side bezel 324a, 324b ... Screw 400 ......... Liquid crystal display module 410 ...... Liquid crystal panel 420 ...... Bezel structure 421 ... ... Upper side long bezel 421a, 421b ··· Screw 422 ··· Lower side long bezel 422a, 422b ··· Screw 423 ··· Left hand short bezel 423a, 423b ··· Screw 424 ... Short side bezel 424a, 424b ... Screw 500 ... Liquid crystal display module 510 ... Liquid crystal panel 520 ... Zell structure 521... Upper side longitudinal bezel 521a, 521b .. Screw 522... Lower side longitudinal bezel 522a, 522b .. Screw 523. Bezel 523a, 523b ··· Screw 524 ··· Short side bezel 524a, 524b ··· Screw 530 ·················································· Underside of

Claims (5)

In the bezel structure that holds the liquid crystal panel,
A liquid crystal display module having a separating portion only at a central portion of the side of the liquid crystal panel.   The liquid crystal display module according to claim 1, wherein the central portion is a central portion of a short side.   The liquid crystal display module according to claim 2, wherein the side is separated into a U-shape at a central portion of the short side.   The liquid crystal display module according to claim 1, wherein the central portion is a central portion of a long side.   The liquid crystal display module according to claim 4, wherein the side is separated into a U-shape at a central portion of the long side.

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