Abstract:
A liquid crystal display device includes a liquid crystal display panel, a backlight and a power supply controlling circuit substrate. The backlight has a rectangular shaped frame member with long and short sides, light sources in rod form within the frame member, and first and second electrode supporting members electrically connected to opposite ends of the light sources. A wire guide member is arranged along one long side of the frame member and holds a wire for electrically connecting at least one of the first and second electrode supporting members to the power supply controlling circuit substrate. The wire guide member has a wire securing portion where the wire is secured and a temporary wire securing portion which at least temporarily secures the wire running between the wire securing portion and the power supply controlling circuit substrate.

Description:
The present application claims priority from Japanese Application JP2007-226407 filed on Aug. 31, 2007, the content of which is hereby incorporated by reference into this application. 
     BACKGROUND OF THE INVENTION 
     (1) Field of the Invention 
     The present invention relates to a liquid crystal display device, and in particular, to a liquid crystal display device having a backlight directly behind the display. 
     (2) Related Art Statement 
     As liquid crystal display panels tend to become larger, liquid crystal display devices having a backlight directly behind the display where the surface light source for the backlight can be made uniform are used. 
     In such backlights, a number of fluorescent tubes are aligned in a direction perpendicular to the longitudinal direction within a plane of the lower frame (base) having a light reflecting function which faces the liquid crystal display panel. Each of these fluorescent tubes is sandwiched by electrode metal fixtures in electrode portions at the two ends, and the electrode metal fixtures are placed at the two ends of the above described base. 
     Thus, a number of electrode metal fixtures are formed on electrode supporting members in band form made of a conductive material which extend in the direction in which the above described fluorescent tubes are aligned. That is to say, the electrode supporting members have a function of sandwiching and holding a number of fluorescent tubes. 
     Therefore, the numbers of fluorescent tubes within the backlight area are connected in parallel by the electrode supporting members and the electrode metal fixtures at the two ends of the base. 
     In addition, a power supply controlling circuit substrate with an inverter for turning on and controlling the fluorescent tubes is mounted on the rear surface of the above described base in such a manner that one power supplying terminal of the power supply controlling circuit substrate is connected to the electrode supporting member on one end side via a wire (cable) and the other power supplying terminal is connected to the electrode supporting member on the other end side via a wire (cable), and as a result, power is supplied to the respective external electrode fluorescent tubes described above. 
     A liquid crystal display device having a backlight using external electrode fluorescent tubes as those described above is disclosed in the following Patent Document 1, for example. 
     (Patent Document 1) Japanese Unexamined Patent Publication 2005-347259 (Corresponding U.S. Application US2005/0265047 A1) 
     SUMMARY OF THE INVENTION 
     Problem to be Solved by the Invention 
     In liquid crystal display devices having the above described configuration, wires for the connection to the above described power supply controlling circuit substrate which are respectively connected to the above described electrode supporting members are formed so as to have a connector in the end portion on the side where connected to the above described power supply controlling circuit substrate, and these connectors can be electrically coupled with the connectors mounted on the above described power supply controlling circuit substrate. 
     The area of the power supply controlling circuit substrate is small relative to the lower frame, and therefore, the power supply controlling substrate is usually located on the rear surface of one of the above described electrode supporting members. 
     Therefore, in some cases one of the wires connected to the above described electrode supporting members must be longer than the other, and in such cases, trenches or hooks are created in the above described lower frame, and a measure for securing the longer wire to the lower frame is taken for wiring. 
     In order to make assembly easier, however, the wires must be in such a state as to allow for the free movement of parts between the location where the wires are secured to the lower frame and the above described power supply controlling circuit substrate. Therefore, the part of the wires over the location where the wires are secured to the lower frame cannot be helped from moving freely until the connection to the power supply controlling circuit substrate is completed. 
     This leads to a disadvantage, such that part of the wires over the location where the wires are secured to the lower frame frequently fluctuates and repeatedly interferes with the lower frame, making it easy for the wires to become disconnected and the connector to be damaged when the lower frame is carried at a stage before the above described power supply controlling substrate is attached to the above described base made of a lower frame and the like. 
     An object of the present invention is to provide a liquid crystal display device having a backlight where a light source and a power supply controlling circuit substrate for controlling the light source are connected through wires and assembly is easier. 
     Means for Solving Problem 
     The gist of typical inventions from among the inventions disclosed in the present specification is briefly described below. 
     A liquid crystal display device is provided with a liquid crystal display panel, a backlight provided on one surface side of the above described liquid crystal display panel and a power supply controlling circuit substrate for turning on and controlling the above described backlight which is mounted on the surface of the above described backlight on the side opposite to the surface which faces the above described liquid crystal display panel, and characterized in that 
     the above described backlight has a frame member, a number of light sources in rod form aligned in parallel within the frame member, a first electrode supporting member electrically connected to one end of the above described number of light sources in rod form, and a second electrode supporting member electrically connected to the other end of the above described number of light sources in rod form, a portion of the above described frame member is provided with a wire guide member where a wire for electrically connecting at least one of the above described first electrode supporting member and second electrode supporting member to the above described power supply controlling circuit substrate is provided, and the above described wire guide member is provided with a wire securing portion where the above described wire is secured and a temporary wire securing portion to which the above described wire running between the wire portion and the above described power supply controlling circuit substrate is secured. 
     Furthermore, a liquid crystal display device is provided with a liquid crystal display panel, a backlight provided on one surface side of the above described liquid crystal display panel and a power supply controlling circuit substrate for turning on and controlling the above described backlight which is mounted on the surface of the above described backlight on the side opposite to the surface which faces the above described liquid crystal display panel, and characterized in that the above described backlight has a frame member, a number of light sources in rod form aligned in parallel within the frame member, a first electrode supporting member electrically connected to one end of the above described number of light sources in rod form, and a second electrode supporting member electrically connected to the other end of the above described number of light sources in rod form, a portion of the above described frame member is provided with a wire guide member where a wire for electrically connecting at least one of the above described first electrode supporting member and second electrode supporting member to the above described power supply controlling circuit substrate is provided, a first connector is formed in the end portion of the above described wire which is connected to the above described power supply controlling circuit substrate, and the above described wire guide member is provided with a wire securing portion where the above described wire is secured and a temporary connector securing portion into which the above described first connector can be inserted. 
     Here, the present invention is not limited to the above described configuration, and various modifications are possible within such a scope as not to deviate from the technical idea of the present invention. 
     Effects of the Invention 
     In the thus formed liquid crystal display device, the wire running out from the light source which is connected to the power supply controlling substrate via a connector can be secured even when the wire is in such a state as not to be coupled with the above described power supply controlling circuit substrate, and therefore, the connector can be prevented from interfering with the lower frame. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a schematic diagram showing the configuration of the liquid crystal display device according to one embodiment of the present invention; 
         FIG. 2  is a cross sectional diagram showing a modular liquid crystal display device according to one embodiment of the present invention; 
         FIGS. 3(   a ) and  3 ( b ) are plan diagrams showing a backlight provided with the liquid crystal display device according to the present invention;  FIG. 3(   a ) is a diagram showing a state where a side wall plate BWh is provided, and  FIG. 3(   b ) is a diagram showing a state where the side wall plate BWh is removed; 
         FIG. 4  is a diagram showing the configuration of an electrode supporting member which is attached to the above described back light and electrode metal fixtures provided with this electrode supporting member; 
         FIG. 5  is a plan diagram showing the lower frame of the above described back light as viewed from the rear; 
         FIG. 6  is a diagram showing the configuration of a wire guide plate provided with the liquid crystal display device according to one embodiment of the present invention; 
         FIG. 7  is a diagram illustrating the manner in which the wire guide plate shown in  FIG. 6  is used; 
         FIG. 8  is a diagram showing the configuration of a wire guide plate provided with the liquid crystal display device according to one embodiment of the present invention; and 
         FIG. 9  is a diagram illustrating the manner in which the wire guide plate shown in  FIG. 6  is used. 
     
    
    
     EXPLANATION OF NUMERALS 
     
         
         PNL . . . liquid crystal display panel 
         OS . . . optical sheet 
         BL . . . backlight 
         AR . . . liquid crystal display region 
         SCD . . . semiconductor device (tape carrier type) 
         FB . . . flexible board 
         CH . . . semiconductor chip 
         PCB 1 , PCB 2  . . . printed circuit boards 
         DFR . . . lower frame 
         RS . . . reflective sheet 
         EFL . . . external electrode fluorescent tube 
         BWh . . . side wall plate 
         UFR . . . upper frame 
         MFR . . . middle frame 
         PWC . . . power supply controlling circuit substrate 
         WGB . . . wire guide plate 
         WR 1 , WR 2 , WR 3  . . . wires 
         CC . . . notch 
         TH 2 , TH 3  . . . through holes 
         TMT . . . electrode support 
         TMS . . . electrode supporting member 
         TMF . . . electrode metal fixture 
         SC . . . screw 
         WF . . . temporary wire securing portion 
         CF . . . temporary connector securing portion 
         FC . . . engaging portion 
         PJ . . . protrusion 
         DNT . . . recess 
         DN . . . dummy connector 
       
    
     DETAILED DESCRIPTION OF THE INVENTION 
     In the following, the liquid crystal display device according to an embodiment of the present invention is described in reference to the drawings. 
     &lt;Configuration of Entirety&gt; 
       FIG. 2  is a schematic diagram showing the configuration of the liquid crystal display device according to one embodiment of the present invention. 
     A liquid crystal display panel PNL, an optical sheet OS and a backlight BL are provided in this order from the viewer side. 
     The liquid crystal display panel PNL is formed of a pair of substrates SUB 1  and SUB 2  made of glass, for example, which are provided in parallel as outer walls, and liquid crystal which intervenes between these substrates SUB 1  and SUB 2 . 
     Pixels (not shown) aligned in a matrix are formed on the surface of the above described substrates SUB 1  and SUB 2  on the liquid crystal side with the above described liquid crystal as one component, so that each of the pixels can control the transmissivity of the liquid crystal to light. 
     In addition, the region where these pixels are formed is used as a liquid crystal display region AR (region surrounded by single-dot chain line in figure), and the entirety of the liquid crystal display region AR is irradiated with light from the below described backlight BL, so that the viewer can recognize an image through light that passes through the respective pixels. 
     The substrate SUB 1  provided in the rear relative to the viewer side has portions which are exposed from the substrate SUB 2  on the left side and on the upper side in the figure, and one side of a number of semiconductor devices SCD can be connected in these portions. These semiconductor devices SCD are so-called tape carrier type semiconductor devices and formed of semiconductor chips CH mounted on the upper surface of flexible boards FB where wires are formed. 
     The semiconductor devices SCD are formed of circuits for individually driving each of the above describe pixels. In the semiconductor devices SCD (video signal driving circuit) which are aligned in the x direction in the figure from among the above described semiconductor devices SCD, a printed circuit board PCB 1  is connected on the side facing the side that is connected to the above described substrate SUB 1 , so that external input signals can be inputted via the printed circuit board PCB 1 . 
     In addition, in the semiconductor devices SCD (scanning signal driving circuit) which are aligned in the y direction in the figure from among the above described semiconductor devices SCD, an external input signal is inputted via a wire (not shown) formed on the surface of the substrate SUB 1 , and therefore, no printed circuit board corresponding to the above described printed circuit board PCB 1  is connected in the configuration. 
     In addition, a backlight BL is provided on the rear surface of the liquid crystal display panel PNL via a diffusion sheet, a prism sheet or a multilayer optical sheet OS of these, for example. The optical sheet OS diffuses light from the backlight BL or collects light, so that light is guided toward the liquid crystal display panel PNL side. 
     The backlight BL is a so-called directly-behind-the-display type and has a number of external electrode fluorescent tubes EFL which are aligned in the y direction in the figure and of which the longitudinal direction coincides with the x direction in the figure within a plane which is parallel to the liquid crystal display panel PNL, and these external electrode fluorescent tubes EFL are respectively supported by a lower frame DFR in box form which is formed of, for example, a metal. 
     A reflective sheet RS is mounted on the surface of the lower frame DFR, and side wall surfaces BW gained by raising the periphery by bending the reflective sheet RS is formed in the upper and lower sides in the figure. 
     Here, side wall plates BWh made of a resin material having an inclination with the outside higher are provided on the left and right side of the lower frame DFR in the figure so as to cover the electrodes at the two ends of the above described external electrode fluorescent tubes EFL. Here, notches CC for preventing interference with the external electrode fluorescent tubes EFL are created on the lower side of the side wall plates BWh. 
     These side wall plates BWh have a light reflecting function on the surface on the above described liquid crystal display panel PNL side and form a substantial side wall portion of the back light BL together with the side wall surfaces BW of the above described reflective sheet RS. The configuration of the back light BL is described in further detail below. 
     &lt;Configuration of Modules&gt; 
     In addition, the liquid crystal display panel PNL, the optical sheet OS and the back light BL are formed of an upper frame UFR and a middle frame MFR which are respectively secured to the above described lower frame DFR, as shown in  FIG. 3 , so as to form a module liquid crystal display device which is combined with the liquid crystal display panel PNL. Here,  FIG. 3  is a cross sectional diagram along line III-III in  FIG. 2 . 
     At least one opening OP for exposing the liquid crystal display region AR of the liquid crystal display panel PNL is created in the upper frame UFR on the viewer side. 
     Here, the semiconductor device SCD connected to the substrate SUB 1  of the liquid crystal display panel PNL is provided in such a state that the side connected to the printed circuit board PCB 1  is bent at a right angle in the portion of the flexible board FB. This is so that the frame becomes narrower in the liquid crystal display device. 
     In addition, as shown in  FIG. 3 , a power controlling circuit substrate PWC provided with an inverter for supplying power to the above described external electrode fluorescent tube EFL and turning on and controlling light is mounted on the rear surface of the lower frame DFR. This power supply controlling circuit substrate PWC is mounted on the rear surface on the lower left side of the lower frame DFR, for example (shown by dotted line in  FIG. 4 ) when the lower frame BFR is viewed from the liquid crystal display panel PNL side. 
     Furthermore, a wire guide plate WGB formed of, for example, a resin, is attached to the lower side on the rear surface of the lower frame DFR from among a pair of sides in the x direction of the above described lower frame. The electrodes at the two ends of the above described external electrode fluorescent tubes EFL are electrically connected to the above described power supply controlling circuit substrate PWC and the electrical connection between the electrodes of the above described external electrode fluorescent tubes EFL and the power supply controlling circuit substrate PCW which is located far away from the above described power supply controlling circuit substrate PWC can be achieved through the wire WR 1  which is guided by the above described wire guide plate WGB. The wire guide plate WGB and the above described wire WR 1  are described in further detail below. 
     &lt;Backlight&gt; 
       FIG. 4(   a ) is a diagram showing only the backlight BL shown in  FIG. 2 , and  FIG. 4(   b ) is a diagram showing a state where the above described side wall plate BWh is removed from the backlight BL shown in  FIG. 4(   a ). 
     The respective side wall plates BWh are provided so as to overlap with the electrode supports TMT made of, for example, a resin material, which are secured to the lower frame BFR, and the electrode supporting members TMS provided on the surface o the electrode supports TFT are exposed when the side wall plates BWF are removed from the electrode supports TMT. 
     The electrode supporting members TMS are formed of a number of electrode metal fixtures TMF for supporting and electrically connecting the electrodes of the external electrode fluorescent tubes EFL. The electrode supporting members TMS are formed through press processing together with the electrode metal fixtures TMF. 
     The electrode supporting members TMS are provided along the two short sides within the lower frame BFR, and the two electrode supporting members TMS have the same structure. 
     The electrode supporting members TMS are secured to the above described electrode supports TMT using screws SC at one end in the longitudinal direction, for example. The electrode metal fixtures TMF are secured to the support TMT only at one end in the longitudinal direction, so that the electrode metal fixtures TMF are prevented from lifting off from the electrode supporting members TMS and bending due to thermal expansion. 
     Incidentally, when the side wall plates BWh are secured to the electrode supporting members TMS (by means of screws, for example), the electrode supporting members TMS are slightly pressed against the electrode supports TMT by a number of protrusions (not shown) formed on the surface of the side wall plates BWh on the side facing the electrode supporting members TMS at certain intervals in the longitudinal direction of the electrode supporting members TMS. 
     &lt;Electrode Supporting Members&gt; 
       FIG. 5(   a ) is a diagram showing one of the electrode supporting members TMS shown in  FIG. 4(   b ) in detail, and an enlarged diagram showing the portion surrounded by the dotted line a in  FIG. 4(   b ). In addition,  FIG. 5(   b ) is a cross sectional diagram along line b-b in  FIG. 5(   a ). 
     As shown in  FIG. 5(   a ), the electrode supporting members TMS have bases BP for securing electrode metal fixtures TMF and left side connection portions JC(L) and right side connection portions JC(R) which are connected to the bases BP on the two sides, and the bases BP, as well as the respective connection portions JC(L) and JC(R), are formed in a ladder pattern as viewed in a plane. 
     Three electrode metal fixtures TMF are formed side by side along each base BP, for example. Each of these three electrode metal fixtures TMF is formed so as to be electrically connected to one electrode of an external electrode fluorescent tube EFL, so that the connection becomes more reliable. 
     As shown in  FIG. 5(   b ), the electrode metal fixtures TMF are formed so as to have a forked structure with a pair of prongs which face each other and sandwich an electrode of an external electrode fluorescent tube EFL from both sides. That is to say, a pair of supports SP gained by bending the two sides of a base BP at a right angle, for example, is provided with arc portions for pressing an electrode of an external electrode fluorescent tube EFL from two sides along the circumference of the electrode which face each other. In addition, electrode metal fixtures TMF are provided with guiding portions IT which make it easy to guide electrodes of external electrode fluorescent tubes EFL to the point between the electrode metal fixtures TMF. Here, the dotted circle in  FIG. 5(   b ) is the outer periphery of an electrode of an external electrode fluorescent tube EFL. 
     As shown in  FIG. 4(   b ), the thus formed electrode supporting members TMS have a wire WR 2  leading out from the portion secured to the electrode support TMT by means of a screw SC on the right side of the electrode supporting member TMS (shown as TMS(L) in figure), and this wire WR 2  passes through a through hole (or notch) TH 2  created in the lower frame DFR so as to lead out to the rear surface of the lower frame DFR. In addition, a wire WR 3  leads out from the portion secured to the electrode support TMT by means of a screw SC on the right side of the electrode supporting member TMS (shown as TMS(R) in figure), and this wire WR 3  passes through a through hole (or notch) TH 3  created in the lower frame DFR so as to lead out to the rear surface of the lower frame DFR. 
     A power supply controlling circuit substrate PWC is mounted on the rear surface of the lower frame DFR, as described above, and power is supplied to the electrode supporting members TMS(L) and TMS(R) through the wires WR 2  and WR 3  via this power supply controlling circuit substrate PWC. 
     &lt;Power Supply Controlling Circuit Substrate and Wire Guide Plate&gt; 
       FIG. 6  is a plan diagram showing the lower frame DFR as viewed from the rear side, and shows the lower frame DFR shown in  FIGS. 4(   a ) and  4 ( b ) in a turned-over state with the left and right reversed. 
     In  FIG. 6 , the wire WR 2  connected to the electrode supporting member TMS(L) passes through the through hole TH 2  so as to lead out to the rear surface of the lower frame DFR, and is connected to a connector CN 2  which can be electrically coupled with a connector CN 2 ′ mounted on the power supply controlling circuit substrate PWC at the end of the wire that runs out from the rear surface. 
     In this case, the portion of the wire WR 2  which leads out to the rear side of the lower frame DFR is in the vicinity of the power supply controlling circuit substrate PWC, and therefore, the wire WR 2  is short. 
     In contrast, the portion of the wire WR 3  connected to the electrode supporting member TMS(R) which passes through the through hole TH 3  and leads out to the rear surface of the lower frame DFR is in a location far away from the power supply controlling circuit substrate PWC. Therefore, the wire WR 3  makes electrical connection with the power supply controlling circuit substrate PWC possible through the wire WR 1  guided to the wire guide plate WGB. That is to say, the wire WR 3  is short. 
     The above described wire guide plate WGB is attached along the bottom side of the lower frame DFR in the figure. One end of the wire guide plate WGB is in the vicinity of the above described through hole TH 3 , and the other end is located close to the above described power supply controlling circuit substrate PWC. 
     The above described wire guide plate WGB is provided with a wire WR 1  which is guided in the longitudinal direction of the wire guide plate WGB, and the above described connector CN 1   a  which is electrically coupled with a connector CN 3  and the above described connector CN 1   b  which is electrically coupled with a connector CN 1 ′ are connected to the two ends of the wire WR 1 . 
     The portion of the wire WR 1  which extends over the power supply controlling circuit substrate TWC side and over the location where the guidance by the above described wire guide plate WGB ends (location where the wire becomes free from the wire guide plate WGB) is sufficiently long. 
     Here, as shown in  FIG. 6 , engaging portions FC are formed in the vicinity of the two ends of the wire guide plate WGB, so that these engaging portions FC can prevent the wire WR 1  from becoming free from the wire guide plate WGB. 
     In addition, though electrical parts other than the connectors CN 1 ′ and CN 2 ′ are mounted on the power supply controlling circuit substrate PWC,  FIG. 6  does not show these. 
     &lt;Details of Wire Guide Plate&gt; 
       FIG. 1(   a ) is a plan diagram showing the portion of the wire guide plate WGB on the side close to the power supply controlling circuit substrate PWC. Here,  FIGS. 1(   b ),  1 ( c ) and  1 ( d ) are cross sectional diagrams along lines b-b, c-c and d-d in  FIG. 1(   a ). 
     A recess DNT for containing the wire WR 1  is created in the longitudinal direction in the wire guide plate WGB, and a number of protrusions PJ are provided at certain intervals on the wall surface of the recess DNT (only one shown in figure), and in these portions a small gap is formed. This is in order to make it difficult for the wire WR 1  to come out from the recess DNT. 
     In addition, as shown in  FIG. 1(   d ), the engaging portions FC are formed of members supported on one side, of which one end is secured to the wire guide plate WGB, and which covers the recess DNT. The wire WR 1  provided in the recess DNT is prevented from moving (coming off from the wire guide plate WGB) by the engaging portions FC when the wire is pulled up relative to the wire guide plate WGB. 
     Furthermore, temporary wire securing portions WF are formed on the wall surface on the side opposite to the side where the engaging portions FC are formed. For example, two temporary wire securing portions WF are provided in the vicinity of the engaging portions FC on the connector CN 1   b  side in the longitudinal direction of the wire guide plate WGB. The respective temporary wire securing portions WF are formed of members supported on one side, of which one end is secured to the wire guide plate WGB and which is formed so as to cover the upper surface of the wire guide plate WGB. 
       FIG. 1  is a diagram showing the connector CN 1   b  of the wire WR 1  in the state before being electrically coupled with the connector CN 1 ′ of the power source controlling circuit substrate PWC. 
     The portion of the wire WR 1  between the connecting portions FC of the wire guide plate WGB and the connector CN 1   b  is relatively long. Therefore, when the lower frame BFR is carried at a stage where the power supply controlling circuit substrate PWC is not attached to the lower frame DFR, the portion of the wire WR 1  between the engaging portions FC and the above described connector CN 1   b  fluctuates with the engaging portions FC at the center. In this state, the wire WR 1  is very troublesome at the time of transportation and assembly. In addition, there is a risk that the wire WR 1  may be disconnected during the operation by human mistake. Furthermore, there is also a possibility that the connector CN 1   b  may be damaged as a result of frequent and repeated interference with the lower frame DFR. 
     Therefore, in the present embodiment, a temporary wire securing portion WF is provided, so that the portion of the wire WR 1  between the engaging portions FC of the wire guide plate WGB and the connector CN 1   b  can be temporarily secured to the temporary wire securing portion at the time of transportation. 
       FIG. 7  is a diagram corresponding to  FIG. 1 , and shows a case where the portion of the wire WR 1  between the engaging portions FC of the wire guide plate WGB and the above described connector CN 1   b  is bent in a portion of the engaging portions FC, so that the wire WR 1  in the vicinity of the connector CN 1   b  is temporarily secured by the temporary wire securing portion WF. 
     As a result, the portion of the wire WR 1  between the engaging portions FC of the wire guide plate WGB and the above described connector CN 1   b  does not fluctuate when the lower frame DFR is carried, and it becomes possible to prevent the state from becoming such that the connector CN 1   b  interferes with the lower frame DFR. 
     Other Embodiments 
       FIG. 8  is a diagram showing the configuration of a main portion of the liquid crystal display device according to another embodiment of the present invention, and corresponds to  FIG. 1 . 
     In the above described embodiment, temporary engaging portions WF are provided to the wire guide plate GB in order to prevent the portion of the wire WR 1  between the engaging portions FC and the connector CN 1   b  from fluctuating. Alternatively, only the connector CN 1   b  may be temporarily secured to the wire guide plate WGB. An example of this is shown in  FIG. 8 . 
     In  FIG. 8 , a temporary connector securing portion CF having a dummy connector DN into which the connector CN 1   b  can be inserted is provided in the vicinity of the engaging portions FC on the wire guide plate WGB. Though this temporary connector securing portion CF is formed on the left of the engaging portion CF in the figure, it may be formed on the right. 
       FIG. 9  is a diagram corresponding to  FIG. 8 , and shows a case where the connector CN 1   b  is inserted into the temporary connector securing portion CF so that the connector CN 1   b  is temporarily secured. 
     As a result, it becomes possible to prevent a state where the connector CN 1   b  interferes with the lower frame DFR when the lower frame DFR is carried. 
     The above described embodiments may be used alone or combined for use. This is because the effects of each embodiment can be gained both when used alone and in combination.