Patent Publication Number: US-9892943-B2

Title: Method for laminating glass panels and vacuum lamination device using same

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to the field of liquid crystal panel manufacturing, and in particular to a method for laminating glass panels and a vacuum lamination device using the method. 
     2. The Related Arts 
     Liquid crystal displays have a variety of advantages, such as thin device body, low power consumption, and being free of radiation, and are thus of wide applications, such as mobile phone, personal digital assistant (PDA), digital camera, computer monitor, and notebook computer screen. 
     Most of the liquid crystal displays that are currently available in the market are backlighting liquid crystal displays, which comprise an enclosure, a liquid crystal panel arranged in the enclosure, and a backlight module mounted in the enclosure. The structure of a conventional liquid crystal panel is composed of a color filter (CF) substrate, a thin-film transistor (TFT) array substrate, and a liquid crystal layer arranged between the two substrates and the operation principle is that a driving voltage is applied to the two glass substrates to control rotation direction of the liquid crystal molecules of the liquid crystal layer in order to refract out light emitting from the backlight module for generating images. Since the liquid crystal panel itself does not emit light, light must be provided from the backlight module in order to normally display images. Thus, the backlight module is one of the key components of a liquid crystal display. The backlight modules can be classified in two types, namely a side-edge backlight module and a direct backlight module, according to the position where light gets incident. The direct backlight module comprises a light source, such as a cold cathode fluorescent lamp (CCFL) or a light-emitting diode (LED), which is arranged at the backside of the liquid crystal panel to form a planar light source directly supplied to the liquid crystal panel. The side-edge backlight module comprises an LED light bar, serving as a backlight source, which is arranged at an edge of a backplane to be located rearward of one side of the liquid crystal panel. The LED light bar emits light that enters a light guide plate (LGP) through a light incident face at one side of the light guide plate and is projected out of a light emergence face of the light guide plate, after being reflected and diffused, to pass through an optic film assembly to form a planar light source for the liquid crystal panel. 
     Referring to  FIG. 1 , a schematic perspective view is given to show a conventional liquid crystal display, which comprises a backlight module  100 , a mold frame  300  arranged on the backlight module  100 , a liquid crystal display panel  500  arranged on the mold frame  300 , and a bezel  700  mounted on the liquid crystal display panel  500 . The backlight module  100  provides the liquid crystal display panel  500  with a planar light source of uniform illumination. The mold frame  300  carries and supports the liquid crystal display panel  500 . The bezel  700  fixes the liquid crystal display panel  500  on the mold frame  300 . 
     A general manufacturing process of liquid crystal display panel comprises a front stage of array process (including thin film, yellow light, etching, and film stripping), an intermediate stage of cell process (including bonding of TFT substrate and the CF substrate), and a rear stage of assembling process (including mounting of drive ICs and printed circuit board). The front stage of array process generally manufactures the TFT substrate in order to control the movement of liquid crystal molecules. The intermediate stage of cell process generally introduces liquid crystal between the TFT substrate and the CF substrate. The rear stage of assembling process generally mounts the drive ICs and combining the printed circuit board to effect driving the liquid crystal molecules to rotate for displaying images. 
     The conventional process of introducing liquid crystal between the TFT substrate and the CF substrate is generally a process referred to as one drop filling (ODF), of which the manufacturing process comprises: dropping a predetermined amount of liquid crystal on a TFT substrate on which a PI (Polyimide) film has been coated and laying a mold frame to show a designated pattern on a CF substrate on which a PI film has been coated, both being then forwarded into a vacuum lamination machine to be assembled together, followed by irradiation of UV (Ultraviolet) light to have the mold frame partially cured, and finally having them baked in an oven to have the mold frame to completely cured to compete the entire ODF process. In the process, the vacuum lamination and UV curing steps are of particularly importance for the product quality. 
     Referring to  FIGS. 2-5 , which illustrates a general process of vacuum lamination and UV curing that is conventionally used, specifically, the process comprises: firstly, laminating and assembling the TFT substrate  502  and the CF substrate  504  in a vacuum chamber in such a way that the precision of lamination is set to be of an error within ±5 um and may be within ±3 um for some high-end products, otherwise it might result in light leak of display, downgrading for poor quality product, or being directly disposed of. Then, a turn-over stage  503  is used to turn over the laminated TFT substrate  502  and the CF substrate  504  to prevent the UV light from incapable of irradiating seal resin  508  in the subsequent UV curing step due to the UV light being blocked by a black matrix (BM)  542  formed on the CF substrate  504 . Finally, a UV lamp  505  and a UV mask  507  are used to irradiate the area of the seal resin  508  to cure the seal resin  508 . The UV mask  507  shields the area of the liquid crystal  506  to avoid influence of the UV light on the property of the liquid crystal. 
     Such a conventional process has the following disadvantages: 
     (1) After the TFT substrate and the CF substrate have been laminated but before they are subjected to the irradiation of the UV light, since the seal resin has not yet been cured, turning over may result in a great deviation from the desired assembling precision due to the deformation of the substrates, so that the lamination precision may get larger than 5 um after the irradiation of the UV light and eventually, downgrading or disposal of the product may result. 
     (2) Similarly, after the TFT substrate and the CF substrate have been laminated but before they are subjected to the irradiation of the UV light, since the seal resin has not yet been cured, if it would be of a long time (generally around 10 minutes) not subjecting to UV irradiation, molecules of the seal resin may get into the liquid crystal to cause contamination and affecting the performance of displaying; if the time is further extended, then the liquid crystal may penetrate through the seal resin to cause disposal of product, this generally occurring in abnormality of transporting device or malfunctioning of UV irradiating facility. 
     (3) Irradiation carried out with the UV irradiating facility is generally non-parallel light irradiation so that if size and location of an opening formed in a UV mask are not correct, then liquid crystal located around the seal resin may get exposed to irradiation of the UV light and reaction occurs. This makes it difficult to get a desired pre-tilt angle in a liquid crystal alignment step in the subsequent manufacturing process and leads to alignment abnormality of the product. 
     SUMMARY OF THE INVENTION 
     An object of the present invention is to provide a method for laminating glass panels, in which a glass panel lamination process and a UV curing process are combined together to effectively improve the yield rate of manufacturing and lower down the cost of manufacturing. 
     Another object of the present invention is to provide a vacuum lamination device that has a simple structure and a low cost and can effectively improve the manufacturing efficiency and yield rate of liquid crystal display panel. 
     To achieve the above objects, the present invention provides a method for laminating glass panels, which comprises the following steps: 
     (1) providing a TFT (Thin-Film Transistor) substrate and a CF (Color Filter) substrate to be laminated, the CF substrate being coated with a seal resin, the TFT substrate carrying liquid crystal dropped thereon; 
     (2) aligning and laminating the TFT substrate and the CF substrate in a vacuum environment to complete a lamination process; 
     (3) applying UV (Ultraviolet) light to transmit through the TFT substrate for carrying out UV curing of the seal resin interposed between the laminated CF substrate and TFT substrate so as to complete a UV curing process; and 
     (4) removing the laminated CF substrate and the TFT substrate that have been subjected to the UV curing process out of the vacuum environment. 
     Step (2) specifically comprises: providing a vacuum chamber, an upper positioning plate, and a lower positioning plate, wherein the lower positioning plate is made of quartz glass, attracting and holding the CF substrate on the upper positioning plate, attracting and holding the TFT substrate on the lower positioning plate, and moving the upper positioning plate and the lower positioning plate relative to each other in the vacuum chamber until the CF substrate and the TFT substrate are aligned and laminated together. 
     The upper positioning plate is made of a metal material. The upper positioning plate attracts and holds the CF substrate through adhesive attachment or electrostatic attraction. The quartz glass that makes the lower positioning plate has a content of hydroxyl that is smaller than or equal to 60 ppm. The lower positioning plate attracts and holds the TFT substrate through vacuum attraction. 
     Step (3) specifically comprises: providing a UV lamp, a light guide plate, and a UV mask, wherein the UV lamp is arranged outside the vacuum chamber and the light guide plate and the UV mask are arranged inside the vacuum chamber, whereby the UV lamp emits UV light and the UV lights transmits into the light guide plate and converts into a planar light source to sequentially transmit through the UV mask, the lower positioning plate, and the TFT substrate to irradiate the seal resin so as to achieve curing of the seal resin. 
     Step (3) further comprises: providing a prism plate, whereby UV light projecting from the light guide plate is allowed to transmit through the prism plate and is projected, in a direction substantially normal to the light guide plate, toward the UV mask to subsequently transmit through the lower positioning plate and the TFT substrate to irradiate the seal resin and achieve curing of the seal resin. 
     The present invention also provides a vacuum lamination device, which comprises: a vacuum chamber, an upper positioning plate and a lower positioning plate mounted in the vacuum chamber and movable with respect to each other, a UV mask mounted to a surface of the lower positioning plate that is distant from the upper positioning plate, a prism plate mounted in the vacuum chamber and located below the UV mask, a light guide plate arranged in the vacuum chamber and located below the prism plate, a UV lamp arranged outside the vacuum chamber and located at one side of the light guide plate, and a plurality of reflection plates arranged at an outer circumference of the light guide plate. The upper positioning plate functions to attract and hold a CF substrate. The lower positioning plate is made of a transparent material for attracting and holding a TFT substrate. The upper positioning plate and the lower positioning plate are movable toward each other to laminate the CF substrate and the TFT substrate together. The UV lamp emits a UV light that sequentially transmits through the light guide plate, the prism plate, the UV mask, the lower positioning plate, and the TFT substrate to irradiate seal resin interposed between the CF substrate and the TFT substrate so as to achieve vacuum lamination of the CF substrate and the TFT substrate and UV curing. 
     The upper positioning plate is made of a metal material. The upper positioning plate attracts and holds the CF substrate through adhesive attachment or electrostatic attraction. The lower positioning plate is made of quartz glass and the quartz glass has a content of hydroxyl that is smaller than or equal to 60 ppm. The lower positioning plate attracts and holds the TFT substrate through vacuum attraction. The UV mask is mounted through vacuum suction to the lower positioning plate. 
     The UV lamp comprises a UV emitter and a reflection hood arranged outside and around the UV emitter. The reflection hood has two ends respectively located at upper and lower sides of the light guide plate. 
     The light guide plate is made of quartz glass and the quartz glass has a content of hydroxyl that is smaller than or equal to 60 ppm. The light guide plate comprises: a light exit surface facing the prism plate, a bottom surface opposite to the light exit surface, and a plurality of lateral surfaces between the light exit surface and the bottom surface. The plurality of lateral surfaces comprises at least a light incident surface. The bottom surface of the light guide plate comprises a plurality of optic structures uniformly distributed thereon. The optic structures comprise concave hemispherical structures. The prism plate is made of quartz glass that has a content of hydroxyl that is smaller than or equal to 60 ppm. The prism plate has an upper surface that is formed of a serration structure, whereby the UV light, after being filtered by the prism plate is projected in a vertical direction. 
     The light guide plate comprises a light incident surface. The UV lamp is set at the light incident surface of the light guide plate. The reflection plates are of a number of four respectively set at the remaining three lateral surfaces, except the light incident surface, of the light guide plate and the bottom surface. 
     The present invention further provides a vacuum lamination device, which comprises: a vacuum chamber, an upper positioning plate and a lower positioning plate mounted in the vacuum chamber and movable with respect to each other, a UV mask mounted to a surface of the lower positioning plate that is distant from the upper positioning plate, a prism plate mounted in the vacuum chamber and located below the UV mask, a light guide plate arranged in the vacuum chamber and located below the prism plate, a UV lamp arranged outside the vacuum chamber and located at one side of the light guide plate, and a plurality of reflection plates arranged at an outer circumference of the light guide plate, the upper positioning plate functioning to attract and hold a CF substrate, the lower positioning plate being made of a transparent material for attracting and holding a TFT substrate, the upper positioning plate and the lower positioning plate being movable toward each other to laminate the CF substrate and the TFT substrate together, the UV lamp emitting a UV light that sequentially transmits through the light guide plate, the prism plate, the UV mask, the lower positioning plate, and the TFT substrate to irradiate seal resin interposed between the CF substrate and the TFT substrate so as to achieve vacuum lamination of the CF substrate and the TFT substrate and UV curing; 
     wherein the upper positioning plate is made of a metal material, the upper positioning plate attracting and holding the CF substrate through adhesive attachment or electrostatic attraction, the lower positioning plate being made of quartz glass, the quartz glass having a content of hydroxyl that is smaller than or equal to 60 ppm, the lower positioning plate attracting and holding the TFT substrate through vacuum attraction, the UV mask being mounted through vacuum suction to the lower positioning plate; and 
     wherein the UV lamp comprises a UV emitter and a reflection hood arranged outside and around the UV emitter, the reflection hood having two ends respectively located at upper and lower sides of the light guide plate. 
     The light guide plate is made of quartz glass and the quartz glass has a content of hydroxyl that is smaller than or equal to 60 ppm. The light guide plate comprises: a light exit surface facing the prism plate, a bottom surface opposite to the light exit surface, and a plurality of lateral surfaces between the light exit surface and the bottom surface. The plurality of lateral surfaces comprises at least a light incident surface. The bottom surface of the light guide plate comprises a plurality of optic structures uniformly distributed thereon. The optic structures comprise concave hemispherical structures. The prism plate is made of quartz glass that has a content of hydroxyl that is smaller than or equal to 60 ppm. The prism plate has an upper surface that is formed of a serration structure, whereby the UV light, after being filtered by the prism plate is projected in a vertical direction. 
     The light guide plate comprises a light incident surface. The UV lamp is set at the light incident surface of the light guide plate. The reflection plates are of a number of four respectively set at the remaining three lateral surfaces, except the light incident surface, of the light guide plate and the bottom surface. 
     The efficacy of the present invention is that the present invention provides a method for laminating glass panels and a vacuum lamination device using the method, which effectively lowers down the manufacture cost and improve the yield rate, wherein specifically, a UV lamp module is arranged under a lower positioning plate of the vacuum lamination device to directly irradiate UV light after vacuum lamination of the CF substrate and the TFT substrate in order to cure the seal resin to thereby eliminate the occurrence of downgrading or disposal of product in the conventional process where laminated CF substrate and TFT substrate must be removed out and subjected to turning over, which leads to deformation of the substrates, before UV irradiation can be performed and also effectively shorten the time between lamination and irradiation of UV light to thereby avoid the occurrence of contamination of the liquid crystal by the seal resin or penetration of the liquid crystal through the seal resin due to an excessively long time interval between the two processes. Further, with the arrangement of a prism plate to subject the UV light to filtration, the light that is projected to the TFT substrate is substantially perpendicular to the TFT substrate so as to avoid irradiation of liquid crystal around a seal resin by the UV light due to inappropriate arrangement of sizes and locations of openings of a UV mask and reaction resulting therefrom, which lead to incapability of obtaining a desired pre-tilt angle for alignment operation of liquid crystal in the subsequent process and thus abnormal alignment of the product. 
     For better understanding of the features and technical contents of the present invention, reference will be made to the following detailed description of the present invention and the attached drawings. However, the drawings are provided for the purposes of reference and illustration and are not intended to impose limitations to the present invention. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The technical solution, as well as other beneficial advantages, of the present invention will be apparent from the following detailed description of embodiments of the present invention, with reference to the attached drawing. In the drawing: 
         FIG. 1  is a schematic perspective view showing a conventional liquid crystal display; 
         FIGS. 2-5  are schematic views illustrating a conventional process of vacuum lamination and UV curing; 
         FIG. 6  is a flow chart illustrating a method for laminating glass panels the present invention; and 
         FIG. 7  is a schematic view illustrating a vacuum lamination device according to the present invention in operation in laminating a CF substrate and a TFT substrate. 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     To further expound the technical solution adopted in the present invention and the advantages thereof, a detailed description is given to a preferred embodiment of the present invention and the attached drawings. 
     Referring to  FIG. 6 , with additional reference to  FIG. 7 , the present invention provides a method for laminating glass panels, which specifically comprises the following steps: 
     Step 1: providing a TFT (Thin-Film Transistor) substrate  240  and a CF (Color Filter) substrate  220  to be laminated, the CF substrate  220  being coated with a seal resin  204 , the TFT substrate  240  carrying liquid crystal  402  dropped thereon. 
     Step 2: aligning and laminating the TFT substrate  240  and the CF substrate  220  in a vacuum environment to complete a lamination process. 
     Step 2 specifically comprises: providing a vacuum chamber  2 , an upper positioning plate  22 , and a lower positioning plate  24 , wherein the lower positioning plate  24  is made of quartz glass, attracting and holding the CF substrate  220  on the upper positioning plate  22 , attracting and holding the TFT substrate  240  on the lower positioning plate  24 , and moving the upper positioning plate  22  and the lower positioning plate  24  relative to each other in the vacuum chamber  2  until the CF substrate  220  and the TFT substrate  240  are aligned and laminated together. 
     Preferably, the upper positioning plate  22  is made of a metal material. The way that the upper positioning plate  22  attracts and holds the CF substrate  220  is adhesive attachment or electrostatic attraction. The lower positioning plate  24  is preferably made of quartz glass. The quartz glass has a content of hydroxyl (—OH) that is smaller than or equal to 60 ppm to allow the transmittance of ultraviolet light to be greater than or equal to 90% and has an effective utilization time that exceeds 2,000 hours where the transmittance is lowered to 80% of the initial level so as to not affect the transmittance of UV light. The way that the lower positioning plate  24  attracts and holds the TFT substrate  240  is vacuum attraction. In other words, the lower positioning plate  24  is provided with uniform apertures (not shown) and is coupled to a vacuum pipe line whereby a electromagnetic vacuum valve (not shown) can be used to control if the TFT substrate  240  is attracted and held or not. 
     Step 3: applying UV (Ultraviolet) light to transmit through the TFT substrate  240  for carrying out UV curing of the seal resin  204  interposed between the laminated CF substrate  220  and TFT substrate  240  so as to complete a UV curing process. 
     Step 3 specifically comprises: providing a UV lamp  29 , a light guide plate  28 , and a UV mask  26 , wherein the UV lamp  29  is arranged outside the vacuum chamber  2  and the light guide plate  28  and the UV mask  26  are arranged inside the vacuum chamber  2 , whereby the UV lamp  29  emits UV light and the UV lights transmits into the light guide plate  28  and converts into a planar light source to sequentially transmit through the UV mask  26 , the lower positioning plate  24 , and the TFT substrate  240  to irradiate the seal resin  204  so as to achieve curing of the seal resin  204 . 
     Step 3 further comprises: providing a prism plate  27 , whereby UV light projecting from the light guide plate  28  is allowed to transmit through the prism plate  27  and is projected, in a direction substantially normal to the light guide plate  28 , toward the UV mask  26  to subsequently transmit through the lower positioning plate  24  and the TFT substrate  240  to irradiate the seal resin  204  and achieve curing of the seal resin  204 . 
     Preferably, the light guide plate  28  is made of quartz glass and the quartz glass has a content of hydroxyl that is smaller than or equal to 60 ppm. The light guide plate  28  comprises: a light exit surface  281  facing the prism plate  27 , a bottom surface  283  opposite to the light exit surface  281 , and a plurality of lateral surfaces  285  between the light exit surface  281  and the bottom surface  283 . The plurality of lateral surfaces  285  comprises at least a light incident surface. The bottom surface  283  of the light guide plate  28  comprises a plurality of the optic structures  282  uniformly distributed thereon for dispersing the UV light reflected by the reflection plate  280  so as to have the light transmit toward the light exit surface  281  of the light guide plate  28 . In the instant embodiment, the optic structures  282  are concave hemispherical structures. 
     The prism plate  27  is made of quartz glass and the quartz glass has a content of hydroxyl that is smaller than or equal to 60 ppm. The prism plate  27  has an upper surface that is formed of a serration structure, whereby the UV light, after being filtered by the prism plate  27  is projected in a vertical direction to have the light perpendicularly projecting to the UV mask  26  for improving precision and preventing the liquid crystal  402  around the seal resin  204  from being irradiated by the UV light and resulting in reaction. 
     Step 4: removing the laminated CF substrate  220  and the TFT substrate  240  that have been subjected to the UV curing process out of the vacuum environment. 
     A robotic arm is used to remove the laminated CF substrate  220  and TFT substrate  240  out of the vacuum chamber  2  and to forward it to a heating oven to have the seal resin  204  further cured. 
     The method for laminating glass panels according to the present invention allows the seal resin  204  to be subjected to UV curing after the CF substrate  220  and the TFT substrate  240  has been laminated without the need of turning over so as to effectively eliminate the occurrence of downgrading or disposal of product in the conventional process where laminated CF substrate and TFT substrate must be removed out and subjected to turning over, which leads to deformation of the substrates, before UV irradiation can be performed and also effectively shorten the time between lamination and irradiation of UV light to thereby avoid the occurrence of contamination of the liquid crystal by the seal resin or penetration of the liquid crystal through the seal resin due to an excessively long time interval between the two processes. 
     Referring to  FIG. 7 , the present invention further provides a vacuum lamination device, which comprises: a vacuum chamber  2 , an upper positioning plate  22  and a lower positioning plate  24  mounted in the vacuum chamber  2  and movable with respect to each other, a UV mask  26  mounted to a surface of the lower positioning plate  24  that is distant from the upper positioning plate  22 , a prism plate  27  mounted in the vacuum chamber  2  and located below the UV mask  26 , a light guide plate  28  arranged in the vacuum chamber  2  and located below the prism plate  27 , a UV lamp  29  arranged outside the vacuum chamber  2  and located at one side of the light guide plate  28 , and a plurality of reflection plates  280  arranged at an outer circumference of the light guide plate  28 . After vacuum lamination of a CF substrate  220  and a TFT substrate  240  that are respectively attracted and held on the upper and lower positioning plates  22 ,  24 , the UV lamp  29  emits a UV light that transmits through the light guide plate  28 , the prism plate  27 , and the UV mask  26  to irradiate the seal resin  204  interposed between the CF substrate  220  and the TFT substrate  240  to achieve UV curing of the CF substrate  220  and the TFT substrate  240 . The present invention effectively combines UV curing facility in an existing vacuum lamination device to allow the two processes of vacuum lamination and UV curing to be carried out in the vacuum lamination device thereby effectively shortening the manufacturing time and lowering the manufacturing cost and also improving product quality. 
     In the instant embodiment, the upper positioning plate  22  is made of a metal material for attracting and holding the CF substrate  220 . The lower positioning plate  24  is made of a transparent material for attracting and holding the TFT substrate  240 . The lower positioning plate  24  is preferably made of quartz glass. The quartz glass has a content of hydroxyl (—OH) that is smaller than or equal to 60 ppm to allow the transmittance of ultraviolet light to be greater than or equal to 90% and has an effective utilization time that exceeds 2,000 hours where the transmittance is lowered to 80% of the initial level so as to not affect the transmittance of UV light. The upper positioning plate  22  and the lower positioning plate  24  are movable towards each other to have the CF substrate  220  and the TFT substrate  240  attracted and held thereon laminated together to complete the vacuum lamination process. 
     Preferably, the way that the upper positioning plate  22  attracts and holds the CF substrate  220  is adhesive attachment or electrostatic attraction and the way that the lower positioning plate  24  attracts and holds the TFT substrate  240  is vacuum attraction. In other words, the lower positioning plate  24  is provided with uniform apertures (not shown) and is coupled to a vacuum pipe line whereby a electromagnetic vacuum valve (not shown) can be used to control if the TFT substrate  240  is attracted and held or not. 
     The UV mask  26  can be of different specifications according to the sizes of liquid crystal display panel. The UV mask  26  is mounted to the lower positioning plate  24  through vacuum suction so that the UV mask  26  can be replaced with different ones according to the sizes of the liquid crystal display panels with easy mounting and dismounting operations. 
     The light guide plate  28  is made of quartz glass and the quartz glass has a content of hydroxyl that is smaller than or equal to 60 ppm. The light guide plate  28  comprises: a light exit surface  281  facing the prism plate  27 , a bottom surface  283  opposite to the light exit surface  281 , and a plurality of lateral surfaces  285  between the light exit surface  281  and the bottom surface  283 . The plurality of lateral surfaces  285  comprises at least a light incident surface. The bottom surface  283  of the light guide plate  28  comprises a plurality of optic structures  282  uniformly distributed thereon for dispersing the UV light reflected by the reflection plate  280  so as to have the light transmit toward the light exit surface  281  of the light guide plate  28 . In the instant embodiment, the optic structures  282  are concave hemispherical structures. 
     The prism plate  27  is made of quartz glass and the quartz glass has a content of hydroxyl that is smaller than or equal to 60 ppm. The prism plate  27  has an upper surface that is formed of a serration structure, whereby the UV light, after being filtered by the prism plate  27  is projected in a vertical direction to have the light perpendicularly projecting to the UV mask  26  for improving precision and preventing the liquid crystal  402  around the seal resin  204  from being irradiated by the UV light and resulting in reaction. 
     The UV lamp  29  is arranged outside the vacuum chamber  2  and is coupled to the vacuum chamber  2  through hermetic enclosure to prevent temperature rise caused by the excessive amount of heat emission during the operation of the UV lamp  29  from causing excessive amounts of deformation of the substrates that affect the precision of lamination. The UV lamp  29  comprises a UV emitter  292  and a reflection hood  294  arranged outside and around the UV emitter  292 . The reflection hood  294  is of a curved shape and has two ends respectively located at upper and lower sides of the light guide plate  28  to reflect the UV light emitting from the UV emitter  292  toward the light incident surface of the light guide plate  28  so as to increase the utilization of the UV light. 
     The quantities of the UV lamp  29  and the reflection plate  280  can be selected according to practical needs. In the instant embodiment, the light guide plate  28  comprises a light incident surface and the quantity of UV lamp  29  used is one. The UV lamp  29  is set at one side of the light incident surface. The number of reflection plate  280  used is four, respectively set at the remaining three lateral surfaces  285 , except the light incident surface, of the light guide plate  28  and the bottom surface  283  for reflecting light backward to have the light eventually projecting out through the light exit surface thereby increasing the utilization of the UV light. 
     In summary, the present invention provides a method for laminating glass panels and a vacuum lamination device using the method, which effectively lowers down the manufacture cost and improve the yield rate, wherein specifically, a UV lamp module is arranged under a lower positioning plate of the vacuum lamination device to directly irradiate UV light after vacuum lamination of the CF substrate and the TFT substrate in order to cure the seal resin to thereby eliminate the occurrence of downgrading or disposal of product in the conventional process where laminated CF substrate and TFT substrate must be removed out and subjected to turning over, which leads to deformation of the substrates, before UV irradiation can be performed and also effectively shorten the time between lamination and irradiation of UV light to thereby avoid the occurrence of contamination of the liquid crystal by the seal resin or penetration of the liquid crystal through the seal resin due to an excessively long time interval between the two processes. Further, with the arrangement of a prism plate to subject the UV light to filtration, the light that is projected to the TFT substrate is substantially perpendicular to the TFT substrate so as to avoid irradiation of liquid crystal around a seal resin by the UV light due to inappropriate arrangement of sizes and locations of openings of a UV mask and reaction resulting therefrom, which lead to incapability of obtaining a desired pre-tilt angle for alignment operation of liquid crystal in the subsequent process and thus abnormal alignment of the product. 
     Based on the description given above, those having ordinary skills of the art may easily contemplate various changes and modifications of the technical solution and technical ideas of the present invention and all these changes and modifications are considered within the protection scope of right for the present invention.