Abstract:
The present invention relates to the plasma display panel module that integrates a sustainer board and reduces electromagnetic interference. The plasma display panel module includes a plasma display panel that includes scan electrode lines, sustain electrode lines, and a data electrode lines, an integration driving board that drives scan electrode lines and sustain electrode lines, a first electric current path that is connected between the integration driving board and the scan electrode lines, a second electric current path that is connected between the integration driving board and the sustain electrode lines, and a metal plate to release heat by a plasma display panel, which a penetration hole that the second electric current path penetrates is formed.

Description:
This Nonprovisional application claims priority under 35 U.S.C. § 119(a) on Patent Application No. 10-2003-033073 filed in Korea on May 23, 2003, the entire contents of which are hereby incorporated by reference. 
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to a plasma display panel module, and more specifically, a plasma display panel module with a sustainer board. 
     2. Description of the Background Art 
     Recently, a plasma display panel (hereinafter, referred to as “PDP”) with easiness of producing a larger size panel has received attention as a plate display device. A PDP usually displays images by adjusting a gas discharge period of each pixel by digital video data. A typical example of the PDP is an alternating current PDP with three electrodes that is driven by alternating current, as is shown in  FIG. 1 . 
       FIG. 1  is an enlarged view of a discharge cell that comprises an alternating current PDP known in the prior art. 
     A discharge cell  30  illustrated in  FIG. 1  has an upper plate that includes an upper substrate  10 , sustain electrodes  12 A and  12 B that are formed on the upper substrate  10  in order, an upper dielectric layer  14 , and a protective film  16 , and an lower plate that includes a lower substrate  18 , a data electrode  20  that is formed on the lower substrate  18  in order, a lower dielectric layer  22 , a division wall  24 , and a phosphor layer  26 . 
     The sustain electrodes  12 A and  12 B includes a scan electrode  12 A and a sustain electrode  12 B. Each of the sustain electrodes  12 A and  12 B is comprised of a transparent electrode and a metal electrode that decrease high resistance by the transparent electrode. 
     The scan electrode  12 A provides a scan signal for an address discharge and a sustain signal for a sustain discharge, and the sustain electrode  12 B provides a sustain signal. The data electrode  20  is formed so that the electrode intersects with the sustain electrodes  12 A and  12 B. The data electrode  20  provides a data signal for the address discharge. 
     Electrical charges that is generated by a discharge are accumulated in the upper dielectric layer  14  and the lower dielectric layer  22 . The protective film  16  prevents the upper dielectric layer  14  from damaging by sputtering in the discharge, and increases the discharge efficiency of secondary electrons. It is possible to decrease the discharge voltage externally applied by the upper dielectric layer  14 , the lower dielectric layer  22 , and the protective film  16 . 
     The division wall  24  forms a discharge space with the upper substrate  10  and the lower substrate  18 . The division wall  24  is formed in parallel to the data electrode  20 , and prevents ultraviolet rays generated by the gas discharge from leaking into adjacent cells. 
     The surface of the lower dielectric layer  22  and the division wall  24  is covered by the phosphor layer  26 , and the phosphor layer  26  generates red, green, or blue visible ray. Inert gases for the gas discharge, such as helium (He), neon (Ne), argon (Ar), xenon (Xe), or Kripton (Kr), mixed discharge gases by those inert gases, or excimer gases that can generate ultraviolet rays by the discharge, are charged in the discharge space. 
     The discharge cell  30  with this structure maintains the discharge by generating the surface discharge between the sustain electrodes  12 A and  12 B, after it is selected in the opposite discharge between the data electrode  20  and the scan electrode  12 A. Due to this, in the discharge cell  30 , the phosphor layer  26  emits light because of ultraviolet rays generated in the sustain discharge, and thereafter visible rays are released. 
     The gradation display of a PDP is comprised of a process of adjusting the sustain discharge period in the discharge cell  30  by video data, that is, adjusting the number of the sustain discharge. Then, color of a pixel is displayed by combination of three discharge cells that red, green, and blue phosphor layers  26  are applied. 
       FIG. 2  is a diagram illustrating the whole alignment of electrodes in a PDP and includes the discharge cell  30  illustrated in  FIG. 1 . In  FIG. 2 , the discharge cell  30  locates in each of the intersections of scan electrode lines Y 1  through Ym, sustain electrode lines Z 1  through Zm, and data electrode lines X 1  through Xn. 
     The scan electrode lines Y 1  through Ym provide a scan pulse and a sustain pulse so that the discharge cell  30  is scanned by the line, and maintain the discharge in the discharge cell  30 . The sustain electrode lines Z 1  through Zm provide a common sustain pulse, and maintain the discharge in the discharge cell  30  with the scan electrode lines Y 1  through Ym. Data electrode lines X 1  through Xn provide a data pulse synchronized with the scan pulse by the line, so that the discharge cell  30  that the discharge is maintained by the theoretical value of the data pulse is selected. 
     A typical example of this PDP driving method is an address and display separation (hereinafter, referred to as “ADS”) driving method. In the method, the address period and the display period (in other words, the sustain period) are separated. 
     In the ADS driving method, one frame is divided into sub-fields corresponding to video data, and each of the sub-fields is redivided into the reset period, the address period, and the sustain period. Each of the sub-fields includes the same reset period RPD and the same address period APD, and also includes the sustain period SPD that different weighted values are assigned. Due to this, the PDP display gradation corresponding to the video data is displayed by the combination of sustain periods that maintain the discharge with the video data. 
       FIG. 3  is a common driving waveform that is provided for the PDP illustrated in  FIG. 2  in a sub-field  1  SF of some sub-fields. 
     The PDP equalizes all of the wall charges in the discharge cell  30  by erasing a certain amount of the wall charges, after it generates the full lighting discharge that uses a reset pulse RP in the reset period RPD as shown in  FIG. 3 . 
     Because of this, the reset pulse RP is provided with the scan electrode lines Y 1  through Ym. The reset pulse RP is composed of a ramp-up pulse and a ramp-down pulse. The ramp-up pulse gradually increases to the peak voltage Vr on the basis of the step voltage Vs, and the ramp-down pulse gradually decrease to the base voltage 0V. 
     The ramp-up pulse generates the first dark discharge in all the discharge cells  30 . Then, the ramp-down pulse and a bias pulse BP that is provided with the sustain electrodes Zi through Zm generates the second dark discharge in all the discharge cells  30 . 
     The ramp-down pulse decreases wall discharges generated in the scan electrode lines Y 1  through Ym and the sustain electrode lines Z 1  through Zm to a certain amount, and this equally initializes wall charges in all of the discharge cells  30 . In the reset period RPD, the voltage of data electrode lines X 1  through Xn is fixed at the base voltage 0V. 
     In the address period APD, the scan pulse SP is provided with the scan electrode lines Y 1  though Ym by the line, and the data pulse DP is selectively provided with each of the data electrode lines X 1  through Xn in synchronization with the scan pulse SP. 
     Due to this, the address discharge is generated in the discharge cells that the scan pulse SP and the data pulse DP are provided, and this generates sufficient amount of wall charges for the next sustain discharge. On the other hand, the address discharge is not generated in the discharge cells that the scan pulse SP and the data pulse DP are not provided, and this maintains the off-state. 
     In the sustain period SPD, a sustain pulse SUSPy and a sustain pulse SUSPz are alternately provided with the scan electrode lines Y 1  through Ym and the sustain electrode lines Z 1  through Zm, and the state of discharge cells that is decided in the address period APD is maintained. 
     In the concrete, the discharge cells, which sufficient amount of wall discharges is formed in the address period APD, maintain the on-state of the discharge by the sustain pulse SUSPy and the sustain pulse SUSPz, and the discharge cells in the off-state maintain the off-state without any discharge. 
     In the erase period EPD that follows the sustain period SPD, an erase pulse EP is provided for the sustain electrode lines Zi through Zm and the erase discharge is generated, and this erases wall discharges in all of the discharge cells  30 . 
     To provide the driving waveform with the PDP shown in  FIG. 2 , a driving device is installed on the back of a heat sink  64 , which is located on the backside of a PDP  40  as is shown in  FIGS. 4 and 5 . 
     The driving device shown in  FIGS. 4 and 5  has a driving board Y  45 , a sustainer board Z  48 , a data driver board  50 , a control board  42 , and a power board that is not shown in the diagrams. 
     The driving board Y  45  drives the scan electrode lines Y 1  through Ym in the PDP  40 , and the sustainer board Z  48  drives the sustain electrode lines Z 1  through Zm. The data driver board  50  drives the data electrode liens X 1  through Xm, and the control board  42  controls the driving board Y  45 , the sustainer board Z  48 , and the data driver board  50 . The power board that is not shown in the diagrams supplies power with the control board  42 , the driving board Y  45 , the sustainer board Z  48 , and the data driver board  50 . 
     The driving board Y  45  includes a scan driver board  44  and a sustainer board Y  46 . The scan driver board  44  generates the reset pulse RP and the scan pulse SP, which are shown in  FIG. 3  of PDP  40 . The sustainer board Y  46  generates the sustain pulse Y SUSPy. 
     The scan driver board  44  provides the scan pulse SP with the scan electrode lines Y 1  through Ym in the PDP  40  via a flexible printed circuit (hereinafter, referred to as “FPC”)  51 . The sustainer board Y  46  provides the sustain pulse Y SUSPy with the scan electrode lines Y 1  through Ym via the scan driver board  44  and a FPC Y  51 . 
     The sustainer board Z  48  generates the bias pulse BP and the sustain pulse Z SUSz, which are shown in  FIG. 3 , and provides them with the sustain electrode lines Z 1  through Zm in the PDP  40  via a FPC Z  52 . 
     The data driver board  50  generates the data pulse DP shown in  FIG. 3 , and provides this to the data electrode lines X 1  through Xn in the PDP  40  via a FPC X  54 . 
     The control board  42  generates each of the timing control signals X, Y, and Z. The control board  42  provides a timing control signal Y with the driving board Y  45  via a first FPC  56 , provides a timing control signal Z with the sustainer board Z  48  via a second FPC  58 , and provides a timing control signal Z with the data driver board  50  via a third FPC  60 . 
     In case of driving a PDP module with this structure, a electric current path in the sustain period SPD is as follows. Firstly, when sustain pulse Y SUSPy is provided with the scan electrode lines Y 1  through Ym from the driving board Y  45 , the first electric current path follows the direction of: the driving board Y  45 , the scan electrode lines Y 1  through Ym, a panel capacitor, the sustain electrode lines Z 1  through Zm, the sustainer board Z  48 , the heat sink  64 , and the driving board Y  45 . 
     Also, when the sustain pulse Z SUSPz is provided with the sustain electrode lines Z 1  through Zm from the sustainer board Z  48 , the second electric current path follows the direction of: the sustainer board Z  48 , the sustain electrode lines Z 1  through Zm, the panel capacitor, the scan electrode lines Y 1  through Ym, the driving board Y  45 , the heat sink  64 , and the sustainer board Z  48 . 
     SUMMARY OF THE INVENTION 
     Accordingly, an object of the present invention is to solve at least the problems and disadvantages of the background art. 
     The objective of the present invention is to integrate sustainer boards and provide a PDP module that decreases the electromagnetic interference. 
     The PDP module in the embodiment of the present invention is comprised of a plasma display panel that has scan electrode lines, sustain electrode lines, and data electrode lines, an integration driving board that drives the scan electrode lines and the sustain electrode lines, a first electrode path that is connected between an integration driving board and a scan electrode line, a second electrode path that is connected between the integration driving board and a sustain electrode line, and a metal plate to release heat from the PDP, which a penetration hole that the second electric current path penetrates is formed. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The invention will be described in detail with reference to the following drawings in which like numerals refer to like elements. 
         FIG. 1  is an oblique perspective diagram illustrating a discharge cell in a common three electrodes alternate current type plasma display panel. 
         FIG. 2  is a diagram illustrating a whole alignment of electrodes in a common plasma display. 
         FIG. 3  is a driving waveform by plasma display panel illustrated in  FIG. 2 . 
         FIG. 4  is a diagram illustrating the backside structure of a conventional plasma display panel module. 
         FIG. 5  is a cross-section diagram illustrating a plasma display panel module illustrated in  FIG. 4 . 
         FIG. 6  is a diagram illustrating the backside structure of a plasma display panel module in the embodiment of the present invention. 
         FIG. 7  is a cross-section diagram illustrating a plasma display module illustrated in  FIG. 6 . 
         FIG. 8  is a cross-section diagram illustrating a path of an output signal by a Y-Z integration board illustrated in  FIG. 7 . 
     
    
    
     DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
     In the PDP module of the embodiment of the present invention, the second electric current path is connected to the integration driving board and is connected to the sustain electrode line via a path between the PDP and the metal plate through the penetration hole. 
     In the PDP module in the embodiment of the present invention, the penetration hole is formed adjacent to the integration driving board. 
     In the PDP module in the embodiment of the present invention, the first and second electric current paths are respectively a first FPC and a second FPC. 
     In the PDP module of the embodiment of the present invention, the first electric current path is connected to either the face or the back of a side of the integration driving board. 
     In the PDP module of the embodiment of the present invention, the second electric current path is connected to either the face or the back of the other side of the integration driving board. 
     In the PDP module of the embodiment of the present invention, the integration driving board has a scan driver board that generates a scan pulse provided with the scan electrode lines, an integration sustainer board that generates the first sustain pulse provided with the scan electrode line and a second sustain pulse provided with the sustain electrode lines, and a connector that connects the scan driver board to the integration sustainer board. 
     The PDP module of the embodiment of the present invention further includes a data driver board that generates a data pulse provided with the data electrode line, a FPC that is connected between the data driver board and the data electrode line, a control board that provides a control signal with upper board  90  in parallel, and the data electrode lines X 1  through Xn are formed on the lower board  92 . 
     Also, a pad region Y  94  is formed on a side of the upper board  90 , and a pad Y (not shown in the diagram) that is connected to the scan electrode lines is formed in this region. On the other hand, a pad region Z  96  is formed on the other side of the upper board  90 , and a pad Z (not shown in the diagram) that is connected to the sustain electrode lines (not shown in the diagram) is formed in this region. 
     And, a pad region X is formed on a side of the lower board  92 , and a pad X (not shown in the diagram) that is connected to a data line is formed in this region. The upper board  90  and lower board  92  are attached so that the pad region Y  94 , the pad region Z  96 , and pad region X (not shown in the diagram) can be exposed. 
     The heat sink  86  is installed in the place where whole the heat sink overlaps with the back of the PDP  70 , so that the heat sink can easily release heat generated in the PDP  70 . Also, a penetrating hole  85  is formed in the heat sink  86 . A FPC Z  84  can penetrate the heat sink  86  through the hole, and can electrically connect a sustain circuit Z (not shown in the diagram) in a Y-Z sustainer board  74  and a pad region Z  96  that is formed on the upper board  90 . The penetrating hole  85  is formed adjacent to the Y-Z sustainer board  74 . 
     The control board  72  generates each of timing control signals X, Y, and Z. The control board  72  provides the timing control signals Y and Z with a Y-Z integration board  100  via a first FPC  76 , and provides the timing control signal X with the data driver board  80  via a second FPC  78 . 
     The data driver board  80  generates the data pulse DP with the timing control signal X from the control board  72 , and provides the data pulse with the data electrode lines in the PDP  70  via a FPC X  88 , as is shown in  FIG. 3 . The FPC X  88  is connected to the pad region X (not shown in the diagram) that is installed in the data driver board  80  and the PDP  70 . 
     The Y-Z integration board  100  is comprised of the scan driver board  73 , the Y-Z sustainer board  74 , and a connector  75  that connects the boards  73  and  74 . 
     With the timing control signal Y from the control board  72 , the scan driver board  73  generates the reset pulse RP that is provided with scan electrode lines in the reset period APD as is shown in  FIG. 3 , and generates the scan pulse SP that is provided in the address period APD. Also, the scan driver board  73  provides the reset pulse RP and the scan pulse SP with the scan electrode lines in the PDP  70  via a FPC Y  82 . 
     As is shown in  FIG. 7 , the FPC Y  82  is connected to the scan driver board  73  and the pad region Y  94  in the PDP  70 , and is connected to the face or the back of a side of the scan driver board  73 . 
     With timing control signals Y and Z from the control board  72 , the Y-Z sustainer board  74  generates the sustain pulse Y SUSPy that is provided with the scan electrode lines in the sustain period SPD, and generates sustain pulse Z SUSPz that is provided with the sustain electrode lines in place of the sustain pulse Y SUSPy. 
     And, the Y-Z sustainer board  74  generates the bias pulse BP that is provided with the sustain electrode lines in the reset period RTPD and the address period APD, as is shown in  FIG. 3 . 
     The Y-Z sustainer board  100  has a sustain circuit Y (not shown in the diagram) that generates the sustain pulse Y SUSPy and the sustain circuit Z (not shown in the diagram) that generates the bias pulse BP and the sustain pulse Z SUSPz. 
     As is shown in  FIG. 8 , the Y-Z sustainer board  74  in this embodiment provides the sustain pulse Y SUSPy with the scan electrode lines in the PDP  70  via the path whose direction is the connector  75 , the scan driver board  73 , and the FPC Y  82 . Also, as is shown in  FIG. 8 , the Y-Z sustainer board  74  provides the bias pulse BP and the sustain pulse Z SUSPz with the sustain electrode lines in the PDP  70  through the penetration hole  85  formed in the heat sink  86 , via the FPC Z  84  that is electrically connected to the sustain circuit Z (not shown in the diagram) in the Y-Z sustainer board  74  and the pad region Z  96  on the upper board  90 . 
     As is shown in  FIG. 7 , the FPC Z  84  has electrical connection to the Y-Z sustainer board  74 , and is connected to the pad region Z  96  that is formed in the PDP  70  via a path between the PDP  70  and the heat sink  86  through the penetration hole  85  formed in the heat sink  86 . The FPC Z  86  is connected to the face or back of a side of the Y-Z sustainer board  74 . 
     In this case, the sustain circuits Y and Z are integrated into the Y-Z sustainer board  74 , and the heat sink  86  cannot play a part as an electrical current path. This makes it possible to decrease electromagnetic interference in the PDP  70 . 
     In the concrete, when the Y-Z sustainer board  74  provides the sustain pulse Y SUSPy with the scan electrode lines, the first electric current path follows the direction of: the Y-Z sustainer board  74 , the connector, the scan driver board  73 , the FPC Y  82 , the scan electrode lines, the panel capacitor, the sustain electrode lines, the FPC Z  84 , the Y-Z sustainer board  74 . 
     On the other hand, the second electric current path, which the Y-Z sustainer board  74  provides the sustain pulse Z SUSPz with the sustain electrode lines in the PDP  70 , follows the direction of: the Y-Z sustainer board  74 , the FPC Z  84 , the sustain electrode lines, the panel capacitor, the scan electrode lines, the FPC Y  82 , the scan driver board  73 , the connector  75 , and the Y-Z sustainer board  74 . 
     In this case, the FPC Z  84  is connected to the pad region Z  96  via a path between the PDP  70  and the heat sink  86  through the penetration hale  85  formed in the heat sink  86 , and the heat sink  86  cannot play a role as a electric current path. This makes it possible to decrease the electromagnetic interference in the PDP  70 . 
     As is described above, the sustain circuits Y and Z are integrated into one board in the PDP module related to the embodiment of the present invention. This makes it possible to simplify the structure of the circuit boards. 
     Especially, in the PDP module related to the embodiment of the present invention, the Y-Z sustainer board, which the sustain circuits Y and Z are integrated into, is located in one side of the heat sink, and the heat sink cannot play a part as a electric current path. Therefore, this makes it possible to decrease the electromagnetic interference in the PDP. 
     The invention being thus described, it will be obvious that the same may be varied in many ways. Such variations are not to be regarded as a departure from the spirit and scope of the invention, and all such modifications as would be obvious to one skilled in the art are intended to be included within the scope of the following claims.