1. Field of the Invention
The present invention relates to a backlight module and more particularly, to a light source protective structure of a backlight module for flat panel display to protect the light source and resist impact from a light guide plate.
2. Description of Related Art
A Liquid Crystal display (LCD) is a sort of display panel, which can't be provided with spontaneous glowing, and must be applied with an additional light source to achieve the designed display function. Therefore, the backlight module comprises light source is one of the key component on LCD.
Further, a delicate electronic apparatus must pass a standard test before they are available in the market, assuring the approval quality of the products in order to protect consumers. The manufacturers of backlight modules execute strict quality control and service system to make sure the quality of their products. Most manufacturers are trying to apply for high standard in order to obtain the acceptance of customer from the competitive market, for example, to execute the reliability test on their products.
To take reference with
During the reliability test of said backlight module 9, the backlight module 9 is arranged to suffer an impact in the direction of a predetermined angle, for example, Y-direction, and at the same time the backlight module 9 is also examined for checking the broken status in predetermined spot. In the meantime, light guide plate 92 of backlight module 9 will occur a sliding motion, therefore, light guide plate 92 may strike light source 97. As a result of causing damage on light source 97 and further affect the luminance of backlight module 9.
In order to avoid light source 97 to be hit by light guide plate 92, the two ends of reflector 95 is bended downward to form with a bending strip 951, The strips extend and locate at the non-luminous electrode portions 971 and these two protrusions can buffer off the impact caused from the movement of lighting guide 92 without shielding the light source 97.
However, reflector 95 is usually made of a thin metal sheet member, the two bending strips 951 are insufficient to stop the light guide plate 92 from displacement during the impact. The formation of the two bending strips 951 will cause a concentration of stress, thereby affecting the strength of the reflector 95. Further, the light of the light source 97 will be diffused through the cut area of the reflector 95, thereby resulting in an optical abnormality.
Further, bending the reflector 95 for forming the two bending strips 951 produces rough edges, and the procedure is also complicated for practicing.
Except the aforesaid method, there is also a known method as taping the light guide plate to prevent displacement of the light guide plate relative to the light source. However, the adhesive tape is insufficient to handle the so-called reliability tests.
More addition to a known method, which the two ends of the reflector are properly cut into two cavities. The bottom shell can be used for stopping the displacement of light guide plate. According to this method, the shape of the light guide plate must be specially designed. Further, it also tends to cause an optical abnormality.
Therefore, it is desirable to provide an improved method to mitigate or obviate the aforementioned problems.
A light source protective structure of a backlight module of the present invention includes: a reflector, and said reflector further comprises an accommodating space, an opening, and at least one protrusion; wherein said light source is accommodated inside the accommodating space and radiated to a opening, said light guide plate is adjacent to said opening, said at least one protrusion is adjacent to said opening and protrudes toward said accommodating spaceto prohibit displacement of said light guide plate toward said light source upon shock of said backlight module.
The light source mentioned above is preferred to be a lamp having non-luminous electrode portions at two distal ends thereof; said at least one protrusion of said reflector is disposed corresponding to said non-luminous electrode portions of said light source. The at least one protrusion of said reflector can be formed through any conventional method. Preferably, the at least one protrusion of said reflector is formed of a part of said reflector by stamping and has either an oval, round or square shape. The reflector of said reflector can be formed in any form. Preferably, the reflector is formed of a reflective sheet member. More preferably, the reflective sheet member is an aluminum sheet. In addition, the backlight module can further comprise a lens and a diffuser arranged in a stack over the light guide plate, and the backlight module is also provided with glasses in order.
Another light source protective structure of a backlight module of the present invention comprises a lamp cover, and a reflector. The backlight module here comprises a light source and a light guide plate. The lamp cover is placed round said light source and has at least one lug formed on said lamp cover. The reflector is mounted in said lamp cover and has a accommodating space and an opening;
On the other hand, the light source is accommodated inside said accommodating space and radiated to said opening, said light guide plate is adjacent to said opening, said lug protruding between said light source and said light guide plate, and adapted to prohibit displacement of said light guide plate toward said light source upon shock of said backlight module.
Preferably, the reflector is also provided with at least one through hole and the at least one lug of said lamp cover is inserted through said through hole of said reflector into said accommodating space between said light source and said light guide plate. Moreover, the reflector can selectively further comprise an extension board overlapped on said lamp cover; said through hole of said reflector is formed in said extension board. In addition, the lamp cover preferably has a semicircular, triangular, square, trapezoid or any other shape. The lug of said lamp cover has a cross section of any conventional shape. Preferably, the at least one lug of said lamp cover has an angled cross section in either L-shaped, oblique semicircular, triangular or any other shaped. The reflector mentioned above can be formed of any form. Preferably, the reflector mentioned above is formed of a reflective sheet member. More preferably, reflective sheet member is an aluminum sheet.
Furthermore, the backlight module is preferred to be a module further comprising a lens and a diffuser arranged in a stack over said light guide plate and the backlight module is also provided with glasses in order.
Other objects, advantages, and novel features of the invention will become more apparent from the following detailed description when taken in conjunction with the accompanying drawings.
Referring to FIGS. 3˜5, a backlight module 1 is shown comprising a bottom shell 11, a light guide plate 12, a reflector 13, a light source 14, a lens 15, and a diffuser 16. The light guide plate 12, the lens 15 and the diffuser 16 are arranged in a stack over the top of the bottom shell 11. The reflector 13 is located at one lateral side of the bottom shell 11. The backlight module 1 is further mounted with glasses and other devices (not shown).
The reflector 13 surrounds an accommodating space 131 and an opening 132. The opening 132 faces downward to the bottom shell 11. According to this embodiment, the reflector 13 is formed by bending an aluminum reflecting sheet member. The light source 14 is mounted in the accommodating space 131, having non-luminous electrode portions 141 at two distal ends thereof for connection to power source. According to this embodiment, the light source 14 is a lamp.
Further, the light guide plate 12 is set adjacent to the opening 132 of the reflector 13 and the light source 14 in the accommodating space 131. The reflector 13 further has two protrusions 133 respectively disposed at two ends of a longitudinal axis thereof. According to this embodiment, the protrusions 133 are respectively formed of a part of the body of the reflector 13 by stamping, having an oval shape. These two protrusions 133 are disposed adjacent to the opening 132 corresponding to the non-luminous electrode portions 141 at the two ends of the light source 14 and respectively projecting into the accommodating space 131 of the reflector 13.
As stated above, the two protrusions 133 are respectively projecting into the accommodating space 131 corresponding to the non-luminous electrode portions 141 at the two ends of the light source 14, therefore, the protrusions 133 do not block the light of the light source 14, i.e., the radiation function of the light source 14 works well, maintaining the luminance of the backlight module 1. Further, during the so-called reliability test, i.e., impact test of the backlight module 1, the two protrusions 133 of the reflector 13 effectively prohibit displacement of the light guide plate 12, preventing impact of the light guide plate 12 against the light source 14.
FIGS. 8˜10 show a backlight module 2 constructed according to the fourth embodiment of the present invention. According to this embodiment, the backlight module 2 comprises a bottom shell 21, a light guide plate 22, a reflector 23, a light source 24, lamp cover 25, a lens 26, and a diffuser 27. The light guide plate 22, the lens 26 and the diffuser 27 are arranged in a stack over the top side of the bottom shell 21. The lamp cover 25 is provided at one lateral side 211 of the bottom shell 21. The backlight module 2 is further mounted with a glass and other devices (not shown).
Further, the reflector 23 is mounted on the lamp cover 25, defining an accommodating space 231 and an opening 232. The opening 232 faces the bottom shell 21. According to this embodiment, bending an aluminum reflecting sheet member into shape makes the reflector 23. The reflector 23 has an extension board 234 overlapped on the lamp cover 25. The extension board 234 has two through holes 233 bilaterally disposed adjacent to the opening 232.
Further, the light source 24 is mounted in the accommodating space 231, having non-luminous electrode portions 241 at the two distal ends thereof for connection to power source. According to this embodiment, the light source 24 is a lamp. The light guide plate 22 is set adjacent to the opening 232 of the reflector 23 and the light source 24 in the accommodating space 231.
It should be noted that the lamp cover 25 has two upward lugs 251 respectively inserted through the through holes 233 of the extension board 234 and protruding in between the opening 232 of the reflector 23 and the light guide plate 22 corresponding to the non-luminous electrode portions 241 at the two ends of the light source 24. According to this embodiment, the cross section of lugs 251 are L-shaped angled lugs and provided with semicircular shape.
As indicated above, the two upward lugs 251 of the lamp cover 25 are respectively inserted through the through holes 233 of the extension board 234 and protruding in between the opening 232 of the reflector 23 and the light guide plate 22 corresponding to the non-luminous electrode portions 241 at the two ends of the light source 24, they do not block the light of the light source 24, i.e., the luminance of the backlight module 2 is well maintained. Further, during the so-called reliability test, i.e., impact test of the backlight module 2, the two upward lugs 251 of the lamp cover 25 effectively prohibit displacement of the light guide plate 22, preventing impact of the light guide plate 22 against the light source 24.
Although the present invention has been explained in relation to its preferred embodiment, it is to be understood that many other possible modifications and variations can be made without departing from the spirit and scope of the invention as hereinafter claimed.
Number | Date | Country | Kind |
---|---|---|---|
093133005 | Oct 2004 | TW | national |