Patent Publication Number: US-2007116938-A1

Title: Polymer composite formed article, printed wiring board using the formed article, and methods of producing them

Description:
TECHNICAL FIELD  
      The present invention generally relates to a polymer composite formed article having thermal expansion coefficients controlled to be isotropically reduced in both a direction extending along the surface of the formed article and a direction intersecting with said direction and a printed wiring board using the formed article. More specifically, the present invention relates to an epoxy resin composite formed article and a thermoplastic polymer composite formed article each having thermal expansion coefficients controlled to be isotropically reduced in both a direction extending along the surface of the formed article and a direction intersecting with said direction. The present invention also relates to printed wiring boards produced using the epoxy resin composite formed article and the thermoplastic polymer composite formed article.  
     BACKGROUND ART  
      Conventionally, polymer composite material formed articles in which functional fibers such as a glass fiber, a carbon fiber, a metal fiber, an aramid fiber, or a polybenzazole fiber are incorporated into a polymer material as a matrix have been widely known.  
      Meanwhile, polymer compositions including an epoxy resin, or a thermoplastic resin have been generally used as insulating materials for printed wiring boards, and electronic parts such as semiconductor packages to be implemented on the printed wiring boards. In addition to polymer materials such as an epoxy resin and a thermoplastic polymer, various dissimilar materials such as metal and ceramics have been used for those printed wiring boards and electronic parts. Those various dissimilar materials may be joined or arranged to be adjacent to each other in a wiring board or an electronic part. Therefore, when the temperature of the environment surrounding these wiring board or the electronic part changes, a difference in thermal expansion coefficients between the dissimilar materials may causes thermal stress in the wiring board, the electronic part itself, or at an interface between the dissimilar materials thereon. In particular, there is a large difference in thermal expansion coefficients between a polymer material such as an epoxy resin or a thermoplastic polymer for forming a wiring board (a general thermal expansion coefficient at room temperature: &gt;5×10 −5  (/K) and a metal such as copper to be used for a wiring material. (a thermal expansion coefficient at room temperature: 1.65×10 −5  (/K)). Therefore, a wiring board or an electronic part composed of a polymer material such as an epoxy resin and a metal may have problems including a cracking, peeling at an interface between a polymer material portion (e.g., epoxy resin) and a metal portion, and breakage or shorting of the wiring due to thermal stress generated.  
      To cope with the above-mentioned problems, a copper-clad laminate has been generally used as a printed wiring board. Such copper-clad laminate is formed by integrally molding a prepreg and copper foil under heat and pressure, and drying the resultant. The prepreg is obtained by impregnating a base material such as glass cloth with a polymer composition containing an epoxy resin, a thermoplastic polymer, or the like. Furthermore, Japanese Laid-Open Patent Publications No. 2002-53646, No. 2001-288251, and No. 10-145020 each disclose an epoxy resin composition having a reduced thermal expansion coefficient to reduce the thermal expansion coefficient of a substrate material. Japanese Laid-Open Patent Publications No. 11-147960 and No. 08-255959 each disclose a substrate including a special base material and reinforcing material. Japanese Laid-Open Patent Publications No. 10-034742 discloses a liquid crystal polymer laminated body used as a substrate material for a flexible printed wiring board or the like. The laminated body includes an isotropic liquid crystal polymer which has low thermal expansivity and which is oriented at random in a plane to reduce the anisotropy of a thermal expansion coefficient in the plane of the substrate. In addition, substrates blended with a filler having low expansivity such as silica have been proposed.  
      With the advent of the increase in number of layers, and complication, of printed wiring boards in recent years, it has become important to suppress thermal expansion, particularly in the thickness direction of a printed wiring board for the purpose of, for example, securing through-hole reliability of the boards. In each of such glass cloth-impregnated epoxy printed wiring boards and epoxy printed wiring boards including a special base material and reinforcing material as above-described, thermal expansion in a direction extending along the surface of the printed wiring board can be reduced. However, in contrast, thermal expansion in the thickness direction of the boards increases.  
      In an epoxy printed wiring board using an epoxy resin composition having a reduced thermal expansion coefficient or an epoxy printed wiring board blended with a filler having low expansivity such as silica, the thermal expansion of the wiring board can be isotropically reduced to some extent, but the reduction is insufficient. For example, Japanese Laid-Open Patent Publication No. 2004-175995 discloses a film in which a composition including a blend of a liquid crystal polymer and another thermoplastic polymer is used to reduce the thermal expansion coefficient in the thickness direction.  
      In an epoxy formed article in which molecular chains of a liquid crystalline epoxy resin are oriented in a specific direction by applying magnetic fields to the resin, thermal expansion in the orientation direction can be reduced, but thermal expansion in any other direction increases.  
      Therefore, a polymer formed article such as an epoxy resin formed article in which thermal expansion is isotropically reduced in each of a direction extending along the surface of the formed article and a direction perpendicular to the said direction has been strongly demanded.  
      The present invention has been made to address such problems as above-described. An objective of the present invention is to provide a polymer composite formed article such as an epoxy resin composite formed article in which thermal expansion is isotropically reduced in each of a direction extending along the surface of the formed article and a direction intersecting with said direction and a printed wiring board formed of such polymer composite formed article. Another objective of the present invention is to provide a method of producing the polymer composite formed article such as an epoxy resin composite formed article and a method of producing the printed wiring board formed of the polymer composite formed article.  
     DISCLOSURE OF THE INVENTION  
      To address to the problems above, one aspect of the present invention provides an epoxy resin composite formed article composed of an epoxy resin and fibers. In the formed article, the fibers are arranged along a first plane and molecular chains of the epoxy resin are oriented in a direction intersecting with the first plane. A degree of orientation α of the molecular chains of the epoxy resin is in a range of 0.5 or more and less than 1, as determined by the following expression (1) based on X-ray diffraction measurement: 
 
Degree of orientation α=(180−Δβ/180)   (1) 
 
      wherein Δβ represents a full width at half maximum in an intensity distribution measured in an azimuth angle direction from 0 to 360° at a fixed peak scatter angle in the X-ray diffraction measurement. Each of the thermal expansion coefficients of the epoxy resin composite formed article in the direction along the first plane and in the direction intersecting with the first plane is in a range of 5×10 −6  to 50×10 −6  (/K) and a difference between the thermal expansion coefficients in the direction along the first plane and in the direction intersecting with the first plane is 30×10 −6  (/K) or less. In this case, the thermal expansion coefficients can be controlled to be isotropically small, thereby reducing any damages such as cracks due to thermal expansion.  
      The epoxy resin is preferably a liquid crystalline epoxy resin having a mesogenic group in its molecular.  
      The fibers preferably comprise at least one of a fiber cloth and single fibers.  
      The fibers preferably consist of at least one selected from glass fibers, ceramic fibers, carbon fibers, metal fibers, and organic fibers.  
      In another aspect, a printed wiring board formed of the epoxy resin composite formed article is provided, wherein an electrically conductive layer is provided on at least one of a surface and inside of the epoxy resin composite formed article.  
      In still another aspect, a method for producing the epoxy resin composite formed article is provided. The method includes disposing the fibers within a cavity of a mold in such a manner that the fibers are arranged along the first plane, impregnating the fibers with an epoxy resin composition by filling the cavity of the mold with the epoxy resin composition, orienting molecular chains of the epoxy resin in a direction intersecting with the first plane, and curing the epoxy resin composition while the orientation of the molecular chains of the epoxy resin is maintained. According to this method, the epoxy resin composite formed article in which the thermal expansion coefficients are controlled to be isotropically small can be obtained easily.  
      In the step of orienting the molecular chains of the epoxy resin, the orientation of the molecular chains of the epoxy resin is preferably accomplished by application of a magnetic field thereto.  
      In another aspect, a method for producing the printed wiring board is also provided. The method includes disposing the fibers within a cavity of a mold in such a manner that the fibers are arranged along the first plane, impregnating the fibers with an epoxy resin composition by filling the cavity of the mold with the epoxy resin composition, orienting molecular chains of the epoxy resin in a direction intersecting with the first plane, curing the epoxy resin composition while the orientation of the molecular chains of the epoxy resin is maintained, and providing an electrically conductive layer on at least one of a surface and inside of the printed wiring board at least either prior to the step of disposing, or after the steps of impregnating, or curing. According to this method, the printed wiring board in which the thermal expansion coefficients are controlled to be isotropically small can be easily obtained.  
      In the step of orienting, the orientation of the molecular chains of the epoxy resin is preferably accomplished by application of a magnetic field thereto.  
      In still another aspect, an alternative method for producing the epoxy resin composite formed article. This method includes preparing an epoxy resin composition containing the fibers, filing a cavity of a mold with the epoxy resin composition in such a manner that a major axis of each of the fibers are arranged along the first plane, orienting molecular chains of the epoxy resin in a direction intersecting with the first plane, and curing the epoxy resin composition, while the orientation of the molecular chains of the epoxy resin is maintained. According this method, the epoxy resin formed article in which the thermal expansion coefficients are controlled to be isotropically small can be easily obtained.  
      In another aspect, a thermoplastic polymer composite formed article composed of a thermoplastic polymer and fibers. In the formed article, the fibers are arranged along a first plane and molecular chains of the thermoplastic polymer are oriented in a direction intersecting with the first plane.  
      The degree of orientation α of the molecular chains of the thermoplastic polymer is in a range of 0.5 or more and less than 1, as determined by the following expression (1) based on X-ray diffraction measurement, 
 
Degree of orientation α=(180−Δβ/180)   (1) 
 
      wherein Δβ represents a full width at half maximum in an intensity distribution measured in an azimuth angle direction from 0 to 360° at a fixed peak scatter angle in the X-ray diffraction measurement.  
      Each of the thermal expansion coefficients of the thermoplastic polymer composite formed article in the direction along the first plane and in the direction intersecting with the first plane is in a range of 5×10 −6  to 50×10 −6  (/K) and the difference between the thermal expansion coefficients in the direction along the first plane and in the direction intersecting with the first plane is 30×10 −6  (/K) or less. In this case, the thermal expansion coefficients can be controlled to be isotropically small, thereby reducing any damage such as cracks due to thermal expansion.  
      The thermoplastic polymer is preferably a liquid crystalline polymer having a mesogenic group in its molecular.  
      The liquid crystalline polymer is preferably at least one selected from aromatic polyester, aromatic polyamide, and aromatic polyesteramide.  
      The fibers preferably comprise at least one of a fiber cloth and single fibers.  
      The fibers preferably consist of at least one selected from glass fibers, ceramic fibers, carbon fibers, metal fibers, and organic fibers.  
      In an another aspect, a printed wiring board formed of the thermoplastic polymer composite formed article is provided, wherein an electrically conductive layer is provided on at least one of a surface and inside of the thermoplastic polymer composite formed article.  
      In still another aspect, a method for producing the thermoplastic polymer composite formed article is provided. This method includes disposing the fibers within a cavity of a mold in such a manner that the fibers are arranged along the first plane, impregnating the fibers with an thermoplastic polymer composition by filling the cavity of the mold with the thermoplastic polymer composition, orienting molecular chains of the thermoplastic polymer in a direction intersecting with the first plane, and solidifying the thermoplastic polymer composition while the orientation of the molecular chains of the thermoplastic polymer is maintained.  
      In another aspect, an alternative method for producing the thermoplastic polymer composite formed article is provided. This method includes forming a preform of a thermoplastic polymer composition containing the thermoplastic polymer, disposing the preform and the fibers within a cavity of a mold in such a manner the preform and the fibers are arranged along the first plane, impregnating the fibers with an thermoplastic polymer composition by melting the preform, orienting molecular chains of the thermoplastic polymer in a direction intersecting with the first plane, and solidifying the thermoplastic polymer composition while the orientation of the molecular chains of the thermoplastic polymer is maintained.  
      In another aspect, an alternative method for producing the thermoplastic polymer composite formed article is provided. This method includes preparing an thermoplastic polymer composition containing the thermoplastic polymer and the fibers, filing a cavity of a mold with the thermoplastic polymer composition in such a manner that a major axis of each of the fibers is arranged along the first plane, orienting molecular chains of the thermoplastic polymer in a direction intersecting with the first plane, and solidifying the thermoplastic polymer composition, while the orientation of the molecular chains of the thermoplastic polymer is maintained. According to these methods, a thermoplastic polymer composite formed article in which the thermal expansion coefficients are controlled to be isotropically small can be easily obtained.  
      In the step of orienting the molecular chains of the thermoplastic polymer in the direction intersecting with the first plane, the orientation of the molecular chains of the thermoplastic polymer is preferably accomplished by application of a magnetic field thereto.  
      In another aspect, a method for producing the printed wiring board is provided. This method includes disposing the fibers within a cavity of a mold in such a manner that the fibers are arranged along the first plane, impregnating the fibers with an thermoplastic polymer composition by filling the cavity of the mold with the thermoplastic polymer composition, orienting molecular chains of the thermoplastic polymer in a direction intersecting with the first plane, solidifying the thermoplastic polymer composition while the orientation of the molecular chains of the thermoplastic polymer is maintained, and providing an electrically conductive layer on at least one of a surface and inside of the printed wiring board at least either prior to the step of disposing, or after the steps of impregnating, or solidifying.  
      In still another aspect, an alternative method for producing the printed wiring board is provided. This method includes forming a preform of a thermoplastic polymer composition containing the thermoplastic polymer, disposing the preform and the fibers within a cavity of a mold in such a manner the preform and the fibers are arranged along the first plane, impregnating the fibers with an thermoplastic polymer composition by melting the preform, orienting molecular chains of the thermoplastic polymer in a direction intersecting with the first plane, solidifying the thermoplastic polymer composition while the orientation of the molecular chains of the thermoplastic polymer is maintained, and providing an electrically conductive layer on at least one of a surface and inside of the printed wiring board at least either prior to the step of disposing, or after the steps of impregnating, or solidifying.  
      In another aspect, an alternative method for producing the printed wiring board is provided. This method includes preparing a thermoplastic polymer composition containing the thermoplastic polymer and the fibers, filing a cavity of a mold with the thermoplastic polymer composition in such a manner that a major axis of each of the fibers are arranged along the first plane, orienting molecular chains of the thermoplastic polymer in a direction intersecting with the first plane, solidifying the thermoplastic polymer composition, while the orientation of the molecular chains of the thermoplastic polymer is maintained, and providing an electrically conductive layer on at least one of a surface and inside of the printed wiring board at least either prior to the step of disposing, or after the steps of impregnating, or solidifying. According to these methods, a printed wiring board in which thermal expansion coefficients are controlled to be isotropically small can be easily obtained.  
      In the step of orienting the molecular chains of the thermoplastic polymer in the direction intersecting with the first plane, the orientation of the molecular chains of the thermoplastic polymer is accomplished by application of a magnetic field thereto.  
      In another aspect, a polymer composite formed article composed of a polymer and fibers is provided. In this formed article, the fibers are arranged along a first plane and molecular chains of the polymer are oriented in a direction intersecting with the first plane.  
      The degree of orientation α of the molecular chains of the polymer is in a range of 0.5 or more and less than 1, as determined by the following expression (1) based on X-ray diffraction measurement, 
 
Degree of orientation α=(180−Δβ/180)   (1) 
 
      wherein Δβ represents a full width at half maximum in an intensity distribution measured in an azimuth angle direction from 0 to 360° at a fixed peak scatter angle in the X-ray diffraction measurement.  
      Each of the thermal expansion coefficients of the polymer composite formed article in the direction along the first plane and in the direction intersecting with the first plane is in a range of 5×10 −6  to 50×10 −6  (/K) and a difference between the thermal expansion coefficients in the direction along the first plane and in the direction intersecting with the first plane is 30×10 −6  (/K) or less. In this case, the thermal expansion coefficients are controlled to be isotropically small, thereby reducing any damages such as cracks due to thermal expansion. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       FIG. 1  is a perspective view showing an epoxy resin composite formed article of a first embodiment and a thermoplastic polymer composite formed article of a third embodiment.  
       FIG. 2  is a sectional view showing the epoxy resin composite formed article of the first embodiment.  
       FIG. 3  is a sectional view showing a printed wiring board of a second embodiment.  
       FIG. 4  is an X-ray diffraction pattern showing an X-ray diffraction intensity distribution in the radial direction of a debye ring of an epoxy resin composition component of the epoxy resin composite formed article.  
       FIG. 5  is a graph showing an intensity distribution in the azimuth angle direction of the epoxy resin composition component of the epoxy resin composite formed article.  
       FIG. 6  is a schematic view showing a method of producing the epoxy resin composite formed article of the first embodiment.  
       FIG. 7  is a schematic view showing the method of producing the epoxy resin composite formed article of the first embodiment.  
       FIG. 8  is a schematic view showing the method of producing the epoxy resin composite formed article of the first embodiment.  
       FIG. 9  is a schematic view showing a method of producing the printed wiring board of the second embodiment.  
       FIG. 10  is a schematic view showing the method of producing the printed wiring board of the second embodiment.  
       FIG. 11  is a sectional view showing the thermoplastic polymer composite formed article of the third embodiment.  
       FIG. 12  is a sectional view showing a printed wiring board of a fourth embodiment.  
       FIG. 13  is a schematic view showing a method of producing the thermoplastic polymer composite formed article of the third embodiment.  
       FIG. 14  is a schematic view showing the method of producing the thermoplastic polymer composite formed article of the third embodiment. 
    
    
     BEST MODE FOR CARRYING OUT THE INVENTION  
      Hereinafter, the best mode for carrying out the present invention will be described in detail.  
      The present invention provides a polymer composite formed article composed of a polymer and fibers. In the polymer composite formed article, the fibers are arranged along a first plane, and the molecular chains of the polymer are oriented in a direction intersecting with the first plane, whereby a thermal expansion coefficient is reduced in each direction.  
     First Embodiment  
      With reference to  FIGS. 1 and 2 , an epoxy resin composite formed article  1  according to a first embodiment of the present invention will be described. The epoxy resin composite formed article  1  has a plate-like shape, and is formed of an epoxy resin composition  16  and a plurality of fiber cloths  15 . In the epoxy resin composite formed article  1 , each fiber cloth  15  is a cloth constructed from a great number of single fibers. Each fiber cloth  15  is arranged in the epoxy resin composition  16  to be parallel with a first plane, that is, a surface of the formed article  1 . In the epoxy resin composite formed article  1  of this embodiment, the molecular chains of an epoxy resin in the epoxy resin composition  16  are oriented in the direction perpendicular to the first plane, namely, in the thickness direction (Z direction in  FIG. 1 ) of the formed article  1 . In other words, the molecular chains of the epoxy resin are arranged to be perpendicular to each fiber cloth  15 .  
      In this embodiment, discrete single fibers may be used in addition to or as an alternative to the fiber cloths  15 .  
      In this case, for example, the single fibers are oriented in such a manner that each fiber axis of the single fibers is parallel to the surface of the epoxy resin composite formed article  1  (for example, the X and Y directions of  FIG. 1 ) and preferably directed in a random direction respectively, while the molecular chains of the epoxy resin are oriented in the thickness direction of the formed article  1  (the Z direction of  FIG. 1 ).  
     Second Embodiment  
      With reference to  FIG. 3 , a printed wiring board  2  according to a second embodiment of the present invention embodied using the epoxy resin composite formed article  1  will be described. The printed wiring board  2  includes an epoxy resin composite formed article  1  formed in the same manner as in the first embodiment and conductive layers  14   a  and  14   b  formed on the upper and lower surfaces of the formed article  1  so as to sandwich the formed article  1  therebetween. In the epoxy resin composite formed article  1 , the fiber cloths  15  are arranged to be parallel with the surface of the wiring board  2 . In the epoxy resin composite formed article  1 , the molecular chains of the epoxy resin are oriented in the direction perpendicular to the surface of the wiring board  2 , that is, in the thickness direction of the wiring board  2 .  
      In this embodiment as well, single fibers may be used in addition to or as an alternative to the fiber cloths  15 . In this case, as in the case of the first embodiment, the single fibers are oriented in such a manner that each fiber axis is parallel to the surface of the epoxy resin composite formed article  1  (for example, the X and Y directions of  FIG. 1 ) and preferably, directed in a random direction respectively, while the molecular chains of the epoxy resin are oriented in the thickness direction of the formed article  1  (the Z direction of  FIG. 1 ).  
     Third Embodiment  
      With reference to  FIGS. 1 and 11 , a thermoplastic polymer composite formed article  10  according to a third embodiment of the present invention will be described. The thermoplastic polymer composite formed article  10  has a plate-like shape. The formed article  10  is formed of a thermoplastic polymer composition  160  and a plurality of fiber cloths  15 . In the thermoplastic polymer composite formed article  10 , each fiber cloth  15  is a cloth composed of a great number of single fibers. Each fiber cloth  15  is arranged in the thermoplastic polymer composition  160  to be parallel with a first plane, that is, the surface of the formed article  10  in this embodiment. In the thermoplastic polymer composite formed article  10 , the molecular chains of a thermoplastic polymer in the thermoplastic polymer composition  160  are oriented in the direction perpendicular to the first plane, i.e., in the thickness direction of the formed article (the Z direction of  FIG. 1 ) in this embodiment. In other words, the molecular chains of the thermoplastic polymer are arranged to be perpendicular to each fiber cloth  15 .  
      In this embodiment, discrete single fibers may be used in addition to or as an alternative to the fiber cloths  15 .  
      In this case, for example, the single fibers are oriented in such a manner that each fiber axis is parallel to the surface of the thermoplastic polymer composite formed article  10  and preferably, directed in a random direction respectively, while the molecular chains of the thermoplastic polymer are oriented in the thickness direction of the formed article  10  (the Z direction of  FIG. 1 ).  
     Fourth Embodiment  
      With reference to  FIG. 12 , a printed wiring board  20  according to a fourth embodiment of the present invention embodied using the thermoplastic polymer composite formed article  10  will be described. The printed wiring board  20  includes the thermoplastic polymer composite formed article  10  formed in the same manner as in the first embodiment and the conductive layers  14   a  and  14   b  formed on the upper and lower surfaces of the formed article  10  so as to sandwich the formed article  10  between them. In the thermoplastic polymer composite formed article  10 , the fiber cloths  15  are arranged parallel to the surface of the wiring board  20 . In the thermoplastic polymer composite formed article  10 , the molecular chains of the thermoplastic polymer is oriented in the direction perpendicular to the surface of the wiring board  20 , i.e. in the thickness direction of the wiring board  20 .  
      In this embodiment, discrete single fibers may be also used in addition to or as an alternative to the fiber cloths  15 . In this case, as in the case of the third embodiment, the single fibers are oriented in such a manner that each fiber axis is in parallel with the surface of the thermoplastic polymer composite formed article  10  and preferably, directed in a random direction respectively, while the molecular chains of the thermoplastic polymer are oriented in the thickness direction of the formed article  10  (the Z direction of  FIG. 1 ).  
      In each of the second and fourth embodiments, the printed wiring board requires high electrical insulating property in an insulator portion thereof. Therefore, the fiber cloths and the single fibers arranged in the epoxy resin composite formed article  1  and the thermoplastic polymer composite formed article  10  are preferably insulative. A layer capable of forming an electrical circuit such as metal foil, a metal-plated layer, or a conductive paste layer can be used for each of the conductive layers  14   a  and  14   b.    
      In the epoxy resin composite formed article  1  and the thermoplastic polymer composite formed article  10  of the first to fourth embodiments, the degree of orientation α of the molecular chains of the epoxy resin or the thermoplastic polymer is in a range of 0.5 or more and less than 1.0. The degree of orientation α is determined by the following expression (1) based on the X-ray diffraction measurement. 
 
Degree of orientation α=(180−Δβ/ 180  . . .   (1) 
 
 wherein Δβ represents a full width at half maximum in an intensity distribution measured in an azimuth angle direction from 0 to 360° at a fixed peak scatter angle in the X-ray diffraction measurement. 
 
      In order to determine the degree of orientation α, the epoxy resin composite formed article  1  or the thermoplastic polymer composite formed article  10  is subjected to wide-angle X-ray diffraction measurement (transmission). When a sample is irradiated with an X-ray in an X-ray diffraction instrument, a concentric arc-like diffraction pattern (debye ring) is obtained if any particles (molecular chains) in the sample are oriented. Firstly, a diffraction pattern showing an X-ray diffraction intensity distribution in the radial direction from the center of such debye ring is obtained for the sample of the formed article (see  FIG. 4 ). In this diffraction pattern, the axis of abscissa indicates an angle  2 θ twice as large as the diffraction angle θ of an X-ray. A peak observed at the position of  2 θ=20° is considered to show a distance between molecular chains of a solid epoxy resin or thermoplastic polymer.  
      The angle at which the diffraction peak of the epoxy resin or the thermoplastic resin (peak scatter angle) appears is generally around 20°, although the angle may range from about 15° to 30° depending on a difference in structure of the epoxy resin or the thermoplastic resin or on a difference in constituents of the epoxy resin composition or the thermoplastic resin composition. An X-ray diffraction intensity distribution in the azimuth angle direction (the circumferential direction of the debye ring) from 0° to 360° is measured, while the measurement angle in the radial direction is fixed at the angle (peak scatter angle) at which the diffraction peak occurs. Thereby, such an X-ray diffraction intensity distribution in the azimuth angle direction at the peak scatter angle as shown in  FIG. 5  can be obtained. A sharper peak in the intensity distribution means that the molecular chains of the epoxy resin or the thermoplastic resin are more highly oriented in a fixed direction. Therefore, a width of the peak at half height (full width at half maximum Δβ) is determined in the intensity distribution in the azimuth angle direction. Then, the full width at half maximum Δβ is substituted into the expression (1). Thereby, the degree of orientation α of the molecular chain of the epoxy resin or the thermoplastic polymer can be calculated. The degree of orientation α is 0.72 in the case of the intensity distribution in the azimuth angle direction shown in  FIG. 5 .  
      To obtain an effect as expected from the present invention with improved efficiency, the value for the degree of orientation a is in a range of 0.5 or more and less than 1.0, preferably 0.55 or more and less than 1.0, more preferably 0.6 or more and less than 1.0, or still more preferably 0.7 or more and less than 1.0. However, a range for the degree of orientation a varies depending on the extent to which a thermal expansion coefficient must be reduced. In an epoxy resin composite formed article and a thermoplastic polymer composite formed article, the degree of orientation α of the molecular chains of each of an epoxy resin and a thermoplastic polymer within the above ranges can significantly reduce the thermal expansion coefficient in the orientation direction of each formed article.  
      When the degree of orientation α in each of the epoxy resin composite formed article and the thermoplastic polymer composite formed article of the present invention is less than 0.5, the thermal expansion coefficient of each of the formed articles is not reduced enough to obtain sufficient effects. Meanwhile, the degree of orientation α cannot be equal to or more than 1.0 in the expression (1) because the full width at half maximum Δβ always has a positive value.  
      Each of the thermal expansion coefficients of the epoxy resin composite formed article  1  and the thermoplastic polymer composite formed article  10  in the direction parallel to the first plane, namely, the surface of the formed articles  1 ,  10  and in the direction perpendicular to the first plane is in a range of 5×10 −6  to 50×10 −6  (/K), or more preferably 10×10 −6  to 40×10 −6  (/K), and a difference between the thermal expansion coefficients in the direction along the first plane and in the direction perpendicular to the first plane is 30×10 −6  (/K) or less.  
      In the epoxy resin composite formed article  1  or the thermoplastic polymer composite formed article  10 , the fiber cloths  15  (or the single fibers) are arranged to be parallel to the surface of the formed article (the first plane), and the molecular chains of the epoxy resin or the thermoplastic polymer are oriented in the direction perpendicular to the surface of the formed article, i.e. the thickness direction of the formed article. The molecular chains of the epoxy resin or the thermoplastic polymer as a matrix of the formed article 1 or 10 are oriented in the direction intersecting with the fiber cloths  15  (or the single fibers) in this way. Thereby, thermal expansion can be reduced in both the direction in which the fiber cloths  15  (or the single fibers) extend (i.e. the direction along the surface) and the direction intersecting with said direction in which the molecular chains of the epoxy resin or the thermoplastic polymer extend (i.e. the thickness direction). In addition, the molecular chains of the epoxy resin or the thermoplastic polymer are extremely small as compared to the fibers constructing the fiber cloths  15  or gaps between the fibers, so the orientation of the molecular chains is hardly inhibited by the fiber cloths  15  (or single fibers). Accordingly, the fiber cloths  15  (or single fibers) can be incorporated at a high density into the formed article.  
      The epoxy resin composite formed article  1  and the thermoplastic polymer composite formed article  10  are applicable to insulating materials for various composite materials, printed wiring boards, semiconductor packages, casings, and the like. As a result, in the various electronic parts, problems due to a difference in thermal expansion between the epoxy resin or the thermoplastic polymer material and any other material including cracks, peeling of an interface, and breakage or short of circuit wirings, and reductions in properties of the electronic parts in association with the problems can be reduced.  
      In addition, the printed wiring boards 2 and 20 in the second and fourth embodiments are each characterized in that the conductive layers  14   a  and  14   b  are formed on both surfaces of the epoxy resin composite formed article  1  or the thermoplastic polymer composite formed article  10  as an insulator to form the boards  2 ,  20 . Each of the printed wiring boards  2  and  20  can reduce problems due to a difference in thermal expansion between each of the conductive layers  14   a,    14   b  and the insulator (the epoxy resin composite formed article  1  or the thermoplastic polymer composite formed article  10 ) such as cracks, peeling of an interface, and breakage and short of circuit wirings, and reductions in properties in association with the problems, and can improve through-hole stability.  
      Hereinafter, the respective constituents of the epoxy resin composite formed article  1  and the thermoplastic polymer composite formed article  10  of the present invention will be described in detail.  
      &lt;Epoxy Resin&gt; 
      Examples of an epoxy resin used in an epoxy resin composition include a bisphenol type, a novolac type, a naphthalene type, a triphenol alkane type, a biphenyl type, a cyclic aliphatic epoxy resins, and halides or hydrides thereof. Each of those epoxy resins may be used alone, or two or more of them may be used in combination. Furthermore, among of those epoxy resins, a liquid crystalline epoxy resin having a mesogenic group in a molecule is particularly preferably used for the epoxy resin composite formed article. Liquid crystallinity of the liquid crystalline epoxy resin having a mesogenic group can facilitate to orient the molecular chains of the epoxy resin, and control the degree of orientation of the epoxy resin. The content of the liquid crystalline epoxy resin having a mesogenic group in a molecule in the total epoxy resins contained in the epoxy resin composition is preferably, but not particularly limited to, 50 wt % or more.  
      A liquid crystalline epoxy resin having a mesogenic group in the main chain of the molecule is a particularly preferable. The term “mesogenic group” refers to a functional group capable of exhibiting liquid crystallinity. Specific examples of the group include biphenyl, cyanobiphenyl, terphenyl, cyanoterphenyl, phenyl benzoate, azobenzene, azomethine, azoxybenzene, stilbene, phenyl cyclohexyl, biphenyl cyclohexyl, phenoxyphenyl, benzylideneaniline, benzyl benzoate, bipyridine, phenyl pyrimidine, phenyl dioxane, benzoyl aniline, tolan, and derivatives thereof.  
      The number of mesogenic groups in a molecular chain of an epoxy resin is at least one, and may be two or more. The liquid crystalline epoxy resin may also include a soft structure portion called a bent chain (spacer), which is composed of, for example, an aliphatic hydrocarbon group, an aliphatic ether group, an aliphatic ester group, a siloxane bond between the mesogenic groups.  
      Such liquid crystalline epoxy resin exhibits a liquid crystal state in a certain temperature range, and has a property that some of the mesogenic groups tend to be regularly arranged. The liquid crystallinity can be confirmed by exhibition of strong birefringence inherent in a liquid crystal obtained in an ordinary polarization test using an orthogonal polarizer. The liquid crystalline epoxy resin may exhibit any kind of the liquid crystal states including nematic, smectic, cholesteric, and discotic states. The liquid crystalline epoxy resin having a mesogenic group and another epoxy resin containing no mesogenic group may be mixed for use.  
      &lt;Thermoplastic Polymer&gt; 
      A liquid crystal thermoplastic polymer having a mesogenic group in a molecule is preferably used as a thermoplastic polymer in a thermoplastic polymer composition. The liquid crystallinity of the liquid crystal thermoplastic polymer having a mesogenic group in a molecule can facilitate orientation of the molecular chains of the thermoplastic polymer and control the degree of orientation of the thermoplastic polymer. The content of the liquid crystal thermoplastic polymer having a mesogenic group in a total amount of the thermoplastic polymers contained in the composition is preferably, but not particularly limited to, 50 wt % or more.  
      A liquid crystal polymer having a mesogenic group in the main chain of a molecule (a main chain type liquid crystal polymer) is a particularly preferable for use. The term “mesogenic group” refers to a functional group capable of exhibiting liquid crystallinity. Specific examples of the group include biphenyl, cyanobiphenyl, terphenyl, cyanoterphenyl, phenyl benzoate, azobenzene, azomethine, azoxybenzene, stilbene, phenyl cyclohexyl, biphenyl cyclohexyl, phenoxyphenyl, benzylideneaniline, benzyl benzoate, bipyridine, phenyl pyrimidine, phenyl dioxane, benzoyl aniline, tolan, and derivatives thereof.  
      The number of mesogenic groups in a molecular chain of the liquid crystal thermoplastic polymer is at least one, and may be two or more. The liquid crystal thermoplastic polymer also may include a soft structure portion called a bent chain (spacer), which is composed of, for example an aliphatic hydrocarbon group, an aliphatic ether group, an aliphatic ester group, and a siloxane bond, between mesogenic groups.  
      A thermal liquid crystal polymer is a specific example of the liquid crystal thermoplastic polymer.  
      The term of “thermal liquid crystal polymer” refers to a liquid crystal polymer which has thermoplasticity and which exhibits a liquid crystal state showing optical anisotropy within a predetermined temperature range when melted by heating. Examples of the thermal liquid crystal polymer include polyester, polyamide, polyesteramide, polyether ketone, polycarbonate, and polyimide. Each of those polymers may be used alone, or two or more of them may be used in combination.  
      Such liquid crystal thermoplastic polymer is in a liquid crystal state in a predetermined temperature range, and has a property that some of the mesogenic groups tend to be regularly arranged. The liquid crystallinity can be confirmed by exhibition of strong birefringence inherent in a liquid crystal obtained in an ordinary polarization test using an orthogonal polarizer. The liquid crystal thermoplastic polymer may exhibit any kind of the liquid crystal states including nematic, smectic, cholesteric, and discotic states. A liquid crystal thermoplastic polymer having a mesogenic group in a molecule and a thermoplastic polymer containing no mesogenic group in a molecule may be mixed and used.  
      &lt;Fiber&gt; 
      The fibers to be used for the epoxy resin composite formed article  1  and the thermoplastic polymer composite formed article  10  of the present invention are a fiber cloth or an aggregation of discrete single fibers (simply referred to as “single fibers”) The fiber length and fiber diameter of a single fiber in a fiber cloth or group of single fibers to be used, and the weave density of fibers in a fiber cloth are not particularly limited. However, in consideration of the productivity, handling, and ease of blending into an epoxy resin composition and a thermoplastic polymer composition of a single fiber, the diameter of a single fiber is practically preferably 0.1 to 30 μm, and the weave density of fibers in a fiber cloth is preferably about 5 to 50 fibers/25 mm for each of a weft and a warp. Each of fibers in a fiber cloth may be woven to be spaced apart from each other in such a manner that the fiber cloth can be easily impregnated with the epoxy resin composition and the thermoplastic polymer composition. A ratio between the numbers of warps and wefts to be knitted may be appropriately adjusted. In addition, the fiber cloth may be a woven or non-woven fabric obtained by fixing fibers with a polymer resin, such as a felt cloth. Although the kinds of single fibers constituting the fiber cloth and the aggregation of single fibers are not particularly limited, at least one selected from glass fibers, carbon fibers, metal fibers, ceramic fibers, and organic fibers is preferable.  
      When the value for the anisotropic diamagnetic susceptibility χ a  of a fiber is large, the fiber receives a large force in a direction parallel with or perpendicular to a line of magnetic force in a magnetic field. The anisotropic diamagnetic susceptibility χ a  is a value showing the anisotropy of a diamagnetic susceptibility generated by applying an external magnetic field, the value being obtained by subtracting a susceptibility χ ⊥  in the direction perpendicular to the fiber axis of the fiber from a susceptibility χ″ in the direction of the fiber axis. A fiber in which the anisotropic diamagnetic susceptibility χ a  has a positive value such as a carbon fiber, an aramid fiber, or a polybenzazole fiber receives a force such that each fiber axis is aligned parallel to lines of magnetic force M in a magnetic field. The molecular chains of a main chain type liquid crystalline epoxy resin and a main chain type liquid crystal thermoplastic polymer also receives a force such that their axes are aligned parallel to the lines of magnetic force M in a magnetic field. As a result, these molecular chains are oriented in the direction parallel to the lines of the magnetic force.  
      As described above, the molecular chains of an epoxy resin and a thermoplastic polymer also tends to be oriented parallel to lines of magnetic force M. Therefore, when fibers having the anisotropic diamagnetic susceptibility χ a  in a positive value are used and the molecular chains of an epoxy resin or a thermoplastic polymer are oriented by a magnetic field, attention must be paid to prevent the fibers from being oriented by the magnetic field in the same direction as the orientation direction of the molecular chains of the epoxy resin or the thermoplastic polymer. Examples of a method for the prevention include use of fibers hardly oriented by a magnetic field, that is, fibers in which the anisotropic diamagnetic susceptibility χ a  itself is small; long fibers, aggregated and assembled fibers, or fibers having a high specific gravity that require larger force to be oriented; and the use of an epoxy resin composition or thermoplastic polymer composition having high viscosity.  
      In addition, a fiber cloth and single fibers may be used in combination. Furthermore, two or more kinds of fiber cloths or single fibers may be used together. As long as at least one kind of fiber cloth or single fibers among the fiber cloths and the single fibers are arranged in a direction intersecting with the orientation direction of the molecular chains of the epoxy resin or the thermoplastic polymer, the other fiber cloths or single fibers may not be oriented, or may be arranged in the same direction as the orientation direction of the molecular chains of the epoxy resin or the thermoplastic polymer.  
      &lt;Epoxy Resin Composition&gt; 
      The epoxy resin composition  16  for forming the epoxy resin composite formed article  1  contains epoxy resin as above-described, and arbitrarily at least one of a fiber cloth and a set of single fibers. The epoxy resin composition may be added with a curing agent for the purpose of curing the epoxy resin through any reaction. The kind and amount of curing agent to be added as well as conditions for heat curing, photo-curing, and moisture curing are not particularly limited. For example, ordinary amine-based curing agents, acid anhydride-based curing agents, phenol-based curing agents, latent curing agents, polymercaptan-based curing agents, polyaminoamide-based curing agents, isocyanates, block isocyanate, or the like can be used. Each of those curing agents may be used alone, or two or more of them may be used as a mixture. The content of each of those curing agents is typically the same as the amount of the curing agent to be used.  
      Epoxy groups of the epoxy resin may be self-polymerized without blending of any curing agent. In this case, a polymerization initiator is added to the epoxy resin composition.  
      The epoxy resin to be used in the present invention can be polymerized through a cationic polymerization using any one of acids such as AlCl 3 , SnCl 4 , TiCl 4 , BF 3 , PCl 5 , SbF 5  and salts thereof as a polymerization initiator. Similarly, the epoxy resin can be polymerized through an anionic polymerization using an ammonium salt such as tetrabutyl ammonium bromide or dimethyl dibenzyl ammonium chloride as a polymerization initiator.  
      The epoxy resin composition may contain a small amount of another reaction curable resin in addition to the epoxy resin.  
      &lt;Thermoplastic Polymer Composition&gt; 
      The thermoplastic polymer composition  160  for forming the thermoplastic polymer composite formed article  10  contains the thermoplastic polymer as above-described. Furthermore, the thermoplastic polymer composition  160  may contain at least one of a fiber cloth and a set of single fibers.  
      Each of the epoxy resin composition and the thermoplastic polymer composition can be blended with an appropriate amount of a filler for additionally reducing the expansion coefficient of each epoxy resin composite formed article and the thermoplastic polymer composite formed article and for improving various properties such as fracture toughness, flexural strength, dielectric constant, and thermal conductivity. Examples of the fillers include metals, metal oxides, metal nitrides, metal carbides, metal hydroxides, metal carbonate compounds, metal-coated resins, resin fillers, carbon fibers, glass fibers, glass beads, carbon-based materials, talc, and clay. Examples of the metals include silver, copper, gold, platinum, and zircon. Examples of the metal oxides include silicon oxide, aluminum oxide, and magnesium oxide. Examples of the metal nitrides include boron nitride, aluminum nitride, and silicon nitride. An example of the metal carbides includes silicon carbide. Examples of the metal hydroxides include aluminum hydroxide and magnesium hydroxide. The filler may be subjected to a treatment with a typical coupling agent for the purposes of improving wettability between the epoxy resin or the thermoplastic polymer and the filler, reinforcing the interface between the epoxy resin or the thermoplastic polymer and the filler, and promoting the dispersion of the fillers into the epoxy resin or the thermoplastic polymer.  
      It should be noted that each of the epoxy resin composition and the thermoplastic polymer composition can be added with a curing accelerator, a curing retardant, a reinforcement, a stress-lowering agent such as rubbers or elastomers, a pigment, a dye, a fluorescent bleach, a dispersant, a stabilizer, a UV absorber, an energy quencher, an antistatic agent, an antioxidant, a thermal stabilizer, a lubricant, a flame retardant, a defoaming agent, a plasticizer, a solvent, or the like, as required.  
      Next, the methods for producing the epoxy resin composite formed article  1 , the thermoplastic polymer composite formed article  10 , and the printed wiring boards  2 ,  20  will be described.  
      The epoxy resin composite formed article  1  is formed by: arranging the fiber cloths  15  along a first plane (for example, the surface of the formed article  1 ) in the epoxy resin composition  16 ; and curing the epoxy resin composition  16  in a state where the molecular chains of an epoxy resin in the composition  16  are oriented in the direction intersecting with the first plane (for example, the thickness direction of the formed article  1 ).  
      The thermoplastic polymer composite formed article  10  is formed by: arranging the fiber cloths  15  along a first plane (for example, the surface of the formed article  10 ) in the thermoplastic polymer composition  160 ; and solidifying the thermoplastic polymer composition  160  in a state where the molecular chains of a thermoplastic polymer in the composition  160  are oriented in the direction intersecting with the first plane (for example, the thickness direction of the formed article  10 ).  
      A device capable of molding an epoxy resin and a thermoplastic polymer such as a transfer molding device, a press molding device, a cast molding device, an injection molding device, or an extrusion molding device can be used as a molding device. The epoxy resin composition  16  and the thermoplastic polymer composition  160  can be molded into an epoxy resin composite formed article and a thermoplastic polymer composite formed article in any one of various shapes including a sheet, a film, a block, a granular shape, a rod, a tubular, and a fibrous shape.  
      An example of a method of orienting the molecular chains of each of the epoxy resin and the thermoplastic polymer in the compositions  16  and  160  includes a method involving orienting the molecular chains by means of at least one selected from rubbing, stretching, rolling, a flow field, a shear field, a magnetic field, and an electric field prior to or upon curing/solidification of the compositions. Of those orientation methods, an orientation method by means of a magnetic field is preferable because the direction in which the molecular chains of the epoxy resin and the thermoplastic polymer are oriented can be easily controlled. The application of a magnetic field to the epoxy resin or the thermoplastic polymer causes their molecular chains to be oriented parallel to lines of magnetic force M. Some of the orientation processes above-described can be used together as required.  
      Examples of a magnetic field generator device for generating a magnetic field include a permanent magnet, an electromagnet, a superconducting magnet, and a coil. Of those magnetic field generators, a superconducting magnet is preferable because it can generate a magnetic field having a practical magnetic flux density.  
      The magnetic flux density of a magnetic field to be applied to the epoxy resin composition is preferably 0.2 to 20 tesla (T), more preferably 0.5 to 15 T, or most preferably 1 to 10 T. A magnetic flux density of less than 0.2 T cannot sufficiently orient the rigid molecular chains of an epoxy resin, resulting in an insufficient reduction in thermal expansion coefficient. On the other hand, a magnetic field having a magnetic flux density in excess of 20 T is hardly obtained in practical use. A magnetic flux density in a range of 0.2 to 20 T provides an epoxy resin composite formed article having a low thermal expansion coefficient and is practical.  
      The magnetic flux density of a magnetic field to be applied to the thermoplastic polymer composition is preferably 1 to 20 tesla (T), more preferably 2 to 15 T, or most preferably 3 to 10 T. A magnetic flux density of less than 1 T cannot sufficiently orient the molecular chains of a thermoplastic polymer, resulting in an insufficient reduction in thermal expansion coefficient. On the other hand, a magnetic field having a magnetic flux density in excess of 20 T is hardly obtained in practical use. A magnetic flux density in a range of 1 to 20 T provides a thermoplastic polymer composite formed article having a low thermal expansion coefficient and is practical.  
      Next, specific methods for producing the epoxy resin composite formed article  1 , the thermoplastic polymer composite formed article  10 , and the printed wiring boards  2  and  20  will be described in detail with reference to FIGS.  6  to  10 , and  FIGS. 13 and 14 .  
      At first, a method for producing the epoxy resin composite formed article  1  formed into a plate-like shape according to the first embodiment, as shown in  FIG. 2 , will be described. In  FIG. 6 , a mold  11  is provided with a cavity  12  having a shape corresponding to the desired shape of a formed article. At first, as shown in  FIG. 6 , one fiber cloth  15  is disposed in the cavity  12  such that the fiber cloth  15  is arranged along, or preferably parallel to, the bottom surface of the cavity  12 . Next, as shown in  FIG. 7 , the cavity  12  is filled with the epoxy resin composition  16 . At this time, after multiple fiber cloths  15  have been disposed within the cavity in a stacked manner, the epoxy resin composition  16  may be flowed into the cavity to impregnate the multiple fiber cloths  15  with the epoxy resin composition  16 . Alternatively, after one fiber cloth  15  has been di-sposed in the cavity, the epoxy resin composition  16  may be injected into the cavity to impregnate the fiber cloth  15  with the epoxy resin composition  16 , and then another fiber cloth  15  may be disposed thereon. Repeating those operations may result in multiple fiber cloths  15  stacked in the formed article  1  thereby obtained.  
      A step for removing mixed air bubbles under reduced or increased pressure is preferably performed during or after the step of filling the epoxy resin composition  16 .  
      The mold  11  is equipped with a heater (not shown) as required. The epoxy resin composition  16  is maintained in a melted state in the step of filling the epoxy resin composition  16 . In addition, the epoxy resin composition  16  is maintained in a liquid crystal state when the epoxy resin composition  16  contains an epoxy resin having a mesogenic group in a molecule.  
      Next, as shown in  FIG. 8 , the epoxy resin composition  16  in the cavity  12  is applied with a magnetic field having a predetermined magnetic flux density by a pair of permanent magnets  13  as magnetic field generators. The pair of permanent magnets  13  is arranged above and below the mold  11 . In this embodiment, lines of magnetic force M of a magnetic field generated by the permanent magnets  13  are arranged matching to the thickness direction of the cavity  12 . The magnetic field may be applied to the mold  11  before the cavity  12  is filled with the epoxy resin composition  16 . At this time, the lines of magnetic force M coincide with the thickness direction of the epoxy resin composition  16 , so the molecular chains of an epoxy resin, or preferably the rigid molecular chains of an epoxy resin having a mesogenic group in a molecule can be oriented in the thickness direction of the epoxy resin composition  16 .  
      While the oriented state of the epoxy resin is maintained, the epoxy resin composition is cured and removed from the mold  11 . As a result, the epoxy resin composite formed article  1  of the present invention is obtained.  
      A prepreg in which each fiber cloth  15  is preliminarily impregnated with the epoxy resin composition  16  may be used. The prepreg may be heated to be in a melted state and applied with a magnetic field so that the molecular chains of the epoxy resin are oriented in the direction intersecting with the fiber cloth as above-described. At this time, the epoxy resin must have melt viscosity to the extent that molecular chains of the resin can be oriented by a magnetic field upon heating.  
      Furthermore, when fibers are used instead of the fiber cloth  15  in the above production method, the cavity  12  of the mold  11  may be filled with an epoxy resin composition added with the fibers in advance. In this case, when the fibers are longer than the thickness of the cavity  12 , the major axis of the each fiber spontaneously orients in the direction along the bottom surface of the cavity  12 . Of course, the major axis of the each fiber may be oriented in the direction along the bottom surface of the cavity  12  by an external force such as a flow field or a shear field.  
      A method for producing the thermoplastic polymer composite formed article  10  formed into a plate-like shape according to the third embodiment, as shown in  FIG. 11 , will be described. In  FIG. 13 , the mold  11  is provided with the cavity  12  having a shape corresponding to the desired shape of a formed article, namely a plate shape in this embodiment. At first, as shown in  FIG. 13 , the thermoplastic polymer composition  160  preformed into a sheet or a flat plate is arranged in the cavity  12  along, or preferably parallel to, the bottom surface of the cavity. Next, at least one fiber cloth  15  is disposed along the upper surface of the sheet of the thermoplastic polymer composition  160 , or preferably parallel to the bottom surface of the mold. Those operations are repeated to laminate multiple thermoplastic polymer composition sheets and multiple fiber cloths  15 .  
      The mold  11  is equipped with a heater (not shown) for press molding the laminated thermoplastic polymer composition sheets and fiber cloths  15  under heat. During the press molding, the thermoplastic polymer composition sheets are melted to be in liquid states, and are then impregnated into the fiber cloths  15 . In addition, the thermoplastic polymer composition  160  is maintained in a liquid crystal state, when the thermoplastic polymer composition  160  contains a liquid crystal polymer having a mesogenic group in a molecule. During the step of press molding under heat, the cavity  12  is preferably vacuumed to prevent air from mixing into the melted thermoplastic polymer composition  160 . Furthermore, as shown in  FIG. 14 , the pair of permanent magnets  13  is arranged as magnetic field generators above and below the mold  11 . These permanent magnets  13  apply a magnetic field having a predetermined magnetic flux density to the polymer composition  160  disposed in the cavity  12 . In this embodiment, the lines of magnetic force M of a magnetic field generated by the permanent magnets  13  are directed to coincide with the thickness direction of the cavity  12 . As a result, the molecular chains of a thermoplastic polymer, or preferably the rigid molecular chains of a liquid crystal thermoplastic polymer having a mesogenic group in a molecule can be oriented in the thickness direction of the thermoplastic polymer composition  160  molded into a plate-like shape in the cavity  12 . The magnetic field may be applied to the mold  11  before the thermoplastic polymer composition sheets are laminated in the cavity  12 .  
      While the oriented state of the thermoplastic polymer is maintained, the thermoplastic polymer composition  160  is solidified, for example, by cooling and removed from the mold  11 . As a result, the thermoplastic polymer composite formed article  10  of the present invention is obtained.  
      A sheet of the thermoplastic polymer composition  160  in which a thermoplastic polymer is mixed with single fibers in advance may be used in the above production method. When the thermoplastic polymer composition  160  containing the single fibers is preliminarily molded into a sheet-like shape, the major axis of each single fiber spontaneously orients in the direction along the surface of the sheet. While this sheet of the thermoplastic polymer composition  160  is heated to be in a melted state, a magnetic field is applied in the thickness direction of the sheet as described above to orient the molecular chains of the thermoplastic polymer in the direction intersecting with the single fibers.  
      As in the production method of the epoxy resin composite formed article  1  of the first embodiment, the thermoplastic polymer composite formed article  10  can be produced by: disposing a fiber cloth(s)  15  in the cavity  12  of the mold  11  at first; and injecting the thermoplastic polymer composition  160  in a melted state into the cavity  12 . In this case, the production method is substantially same as that for the epoxy resin composite formed article  1  of the first embodiment, except that the epoxy resin composition is substituted by a melted thermoplastic polymer composition.  
      Furthermore, when single fibers are used instead of the fiber cloth  15  in the production method, the thermoplastic polymer composition  160  preliminarily added with single fibers maybe injected into the cavity  12  of the mold  11 . In this case, when a fiber is longer than the thickness of the cavity  12 , the major axis of the fiber spontaneously orients in the direction along the bottom surface of the cavity  12 . The major axis of the fiber also can be oriented in the direction along the bottom surface of the cavity  12  by an external force such as a flow field or a shear field. Such external force may be generated when the thermoplastic polymer composition is injected into the cavity  12  of the mold  11 .  
      In any case, the thermoplastic polymer composition must have melting viscosity to the extent that its molecular chains can be oriented by a magnetic field in a melted state.  
      To produce the printed wiring board of the second embodiment shown in  FIG. 3 , in the production method of the epoxy resin composite formed article  1  of the first embodiment, the conductive layer  14   a  composed of, for example, metal foil is disposed on the bottom surface of the cavity  12  prior to the step of disposing the fiber cloth  15  in the cavity  12  of the mold  11 , as shown in  FIG. 9 . Furthermore, after the step of filling the cavity  12  with the epoxy resin composition  16 , as shown in  FIG. 10 , the conductive layer  14   b  is additionally disposed on the epoxy resin composition  16  filled into the cavity  12 . After that, a magnetic field is applied to orient the molecular chains of an epoxy resin in the thickness direction of the epoxy resin composition  16  in the same manner as in the production method of the first embodiment shown in  FIG. 8 . While the oriented state of the epoxy resin is maintained, the epoxy resin composition is cured and removed from the mold  11 . As a result, an epoxy resin composite formed article having the conductive layers  14   a  and  14   b  disposed on both of its surfaces is obtained. Furthermore, the conductive layers  14   a  and  14   b  are patterned by means of a conventionally known method such as etching to produce the printed wiring board  2  of the present invention.  
      In addition, a multi-layer printed wiring board can be produced by disposing metal foil having a circuit formed therein in advance between the above-mentioned prepregs.  
      To produce the printed wiring board of the fourth embodiment shown in  FIG. 12 , as shown in  FIG. 9 , the conductive layer  14   a  composed of, for example, metal foil is disposed on the bottom surface of the cavity  12  prior to the step of disposing the thermoplastic polymer composition  160  preliminarily molded into a sheet-like shape and the fiber cloth  15  in the cavity  12  of the mold  11  in the above-mentioned method of producing the thermoplastic polymer composite formed article  10  of the third embodiment. Furthermore, as shown in  FIG. 10 , the conductive layer  14   b  is additionally disposed on the thermoplastic polymer composition  160  disposed at the uppermost portion in the cavity  12  after the step of laminating the thermoplastic polymer composition  160  and the fiber cloth  150  in the cavity  12 . After that, a magnetic field is applied to orient the molecular chains of a thermoplastic polymer in the thickness direction of the thermoplastic polymer composition  160  in the cavity  12  in the same manner as in the production method of the third embodiment shown in  FIG. 8 . While the oriented state of the thermoplastic polymer is maintained, the thermoplastic polymer composition is solidified and removed from the mold  11 . As a result, a thermoplastic polymer composite formed article having the conductive layers  14   a  and  14   b  disposed on both of its surfaces is obtained. Furthermore, the conductive layers  14   a  and  14   b  are patterned by means of a conventionally known method such as etching to produce the printed wiring board  20  of the present invention.  
      In addition, a multi-layer printed wiring board can be produced by disposing a metal foil(s) having circuits preliminarily formed therein between two polymer composition sheets when the polymer composition sheet and the fiber cloth  15  are disposed in a stack.  
      The above embodiments can be modified as described below.  
      An epoxy resin composite formed article or a thermoplastic polymer composite formed article is produced in advance, and a conductive layer composed of metal foil or the like is integrated with the epoxy resin composite formed article or the thermoplastic polymer composite formed article through an adhesive layer or the like to form a printed wiring board.  
      A metal-plated layer or a conductive paste layer is used as a conductive layer instead of a metal foil. At this time, a prepreg in which a fiber cloth is preliminarily impregnated with an epoxy resin composition or a thermoplastic polymer composition may be used, or an epoxy resin composite formed article or a thermoplastic polymer composite formed article may be produced in advance.  
      In the epoxy resin composite formed article  1  or the thermoplastic polymer composite formed article  10 , each fiber cloth may be arranged to be parallel to the thickness direction of the formed article, and the molecular chains of an epoxy resin or a thermoplastic polymer may be oriented to be parallel to the surface of the formed article. In this case, in the above production method, the pair of permanent magnets  13  is arranged on both sides of the mold  11  to be opposed to each other in such a manner that the lines of magnetic force M are parallel to the surface of the epoxy resin composition  16  or the thermoplastic polymer composition  160  in the cavity  12 .  
      The pair of permanent magnets  13  is arranged to sandwich the mold  11  between them, but one of the permanent magnets  13  may be omitted.  
      The pair of permanent magnets  13  is arranged in such a manner that the S pole of one of the magnets is opposed to the N pole of the other. However, the pair may be arranged in such a manner that the S poles, or N poles, of both the magnets are opposed to each other.  
      The lines of magnetic force M are linear, but may be curved or the like. The pair of permanent magnets  13  is arranged in such manners that the lines of magnetic force M extend in one direction. However, the pair of permanent magnets  13  may be arranged in such manners that the lines of magnetic force M extend in two or more directions. Furthermore, one of one line M of magnetic force and the mold  11  may be rotated.  
      A large number of single fibers may be used instead of a fiber cloth. In this case, in the above production method, multiple single fibers may be arranged in the cavity  12  to be parallel to the surface of a formed article to be obtained before the cavity  12  is filled with the epoxy resin composition  16 . Alternatively, the epoxy resin composition  16  or the thermoplastic polymer composition  160  may be mixed with a single fiber in advance. In this case, as described above, it must be noted the fibers are prevented from being oriented in the same direction as the orientation direction of the molecular chains of the epoxy resin or the thermoplastic polymer upon the orientation of these molecular chains by a magnetic field.  
      The fiber axis of a fiber in a formed article has only to be oriented along a first plane, and is not needed to be exactly parallel to the first plane. In addition, the molecular chains of the epoxy resin or the thermoplastic polymer has only to be oriented in the direction intersecting with the first plane, and is not needed to be exactly perpendicular to the first plane.  
      Hereinafter, the above embodiments will be described more specifically by way of examples and comparative examples. However, these examples do not limit the scope of the present invention at all.  
     EXAMPLES  
      Printed wiring board formed of epoxy resin composite formed article  
     Example 1  
      A printed wiring board using the epoxy resin composite formed article of the present invention as an insulating layer and copper foil as a conductive layer was produced. The epoxy resin composition  16  prepared by mixing terephthalylidene-bis-(4-amino-3-methylphenol)diglycidyl ether, having a mesogenic group in the main chain of a molecule, as an epoxy resin and 4,4′-diamino-1,2-diphenylethane as a curing agent in a ration of 1 mol:0.5 mole was used. A glass cloth “MS130” manufactured by Asahi Fiber-Glass Co., Ltd. (having a weight of 106 g/m 2  and a density of 19 fibers/25 mm) was used as the fiber cloth  15 . Copper foil (having a thickness of 18 μm) was used as each of the conductive layers  14   a  and  14   b.  The number of glass cloths to be used was set in such a manner that the content of the glass cloth in a formed article would be 8 vol %. Copper foil (the conductive layer  14   a ) was disposed on the bottom surface of the cavity  12  of the mold  11 . Then three glass cloths  15  were disposed over the foil to be parallel to the bottom surface of the cavity  12 . After that, the mold  11  was heated to 170° C. in temperature, and then the cavity  12  was filled with the epoxy resin composition  16  to impregnate the epoxy resin composition  16  into the glass cloths  15 . After that, another copper foil (the conductive layer  14   b ) was disposed on the epoxy resin composition  16 . After that, the composition  16  was cured at 170° C. for 10 minutes in a magnetic field having a magnetic flux density of 10 tesla. Thus, a laminate of 2 mm in thickness was obtained. Next, the laminate was drilled to form 200 holes each having a hole diameter of 0.9 mm therein. The resultant was subjected to a copper through-hole plating treatment and then patterned in such a manner land diameter of each hole, a circuit width, and a circuit interval would be 1.3 mm, 0.2 mm, and 0.2 mm, respectively. Thereby, the printed wiring board  2  was obtained.  
     Examples 2 and 3  
      Each of the printed wiring boards  2  was produced in the same manner as in Example 1 except that the number of glass cloths to be disposed in the cavity  12  (the content of the glass cloth) was changed as shown in Table 1.  
     Example 4  
      The printed wiring board  2  was produced in the same manner as in Example 1 except that the number of glass cloths to be disposed in the cavity  12  (the content of the glass cloth) and a magnetic flux density were changed as shown in Table 1.  
     Example 5  
      The same epoxy resin as that of Example 1 and the same curing agent as that of Example 1 were mixed in a ratio of 1 mole:0.5 mole. The mixture was added with glass fibers “CS03BC273” manufactured by Asahi Fiber-Glass Co., Ltd. (each having a fiber length of 3 mm) as single fibers, instead of the glass cloths of Examples 1 to 4, to the epoxy resin composition  16 . The amount of glass fibers to be added was set in such a manner that the content of the glass fibers in a formed article would be 21 vol %. The same copper foil as that of Example 1 was used as each of the conductive layers  14   a  and  14   b.  At first, copper foil (the conductive layer  14   a ) was disposed on the bottom surface of the cavity  12  of the mold  11 . After that, the mold  11  was heated to 170° C., and then the cavity  12  was filled with the epoxy resin composition  16 . Then, another copper foil (the conductive layer  14   b ) was disposed on the epoxy resin composition  16 . After that, the epoxy resin composition  16  was cured at 170° C. for 10 minutes in a magnetic field having a magnetic flux density of 10 tesla. Thus, a laminate of 2 mm in thickness was obtained. The directions of the lines of magnetic force M were aligned with the thickness direction of the laminate. Next, the laminate was used to produce the printed wiring board  2  in the same manner as in Example 1.  
     Example 6  
      An epoxy resin composition obtained by mixing the same epoxy resin as that of Example 1 and of the same curing agent in a ratio of 1 mole:0.5 mole as that of Example 1 was used. The same glass cloth as that of Example 1 was used as a fiber cloth. The same copper foil as that of Example 1 was used as each of the conductive layers  14   a  and  14   b.  The number of glass cloths to be used was set in such a manner that the content of the glass cloth in a formed article would be 17 vol %. At first, one glass cloth  15  was impregnated with the epoxy resin composition  16  melted by heating. After that, the resultant was solidified by cooling in a magnetic field having a magnetic flux density of 10 tesla to produce a prepreg. Copper foil was disposed in the cavity  12  of the same mold  11  as that of Example 1, and ten prepregs thus obtained were disposed in a stack over the copper foil. Furthermore, another copper foil was disposed on the resultant. The resultant was heated and pressurized at 170° C. in a magnetic field having a magnetic flux density of 10 tesla to produce a laminate of 2 mm in thickness. The directions of the lines of magnetic force M were aligned with the thickness direction of the laminate. Next, the laminate was used to produce the printed wiring board  2  in the same manner as in Example 1.  
     Comparative Example 1  
      The epoxy resin composition  16  was used to produce a printed wiring board containing neither fiber cloth nor single fibers. The epoxy resin composition  16  was prepared by mixing of terephthalylidene-bis-(4-amino-3-methylphenol)diglycidyl ether having a mesogenic group in a molecule as an epoxy resin and of 4,4′-diamino-1,2-diphenylethane as a curing agent in a ratio of 1 mole:0.5 mole. The same copper foil as that of Example 1 was used as a conductive layer. At first, copper foil (the conductive layer  14   a ) was disposed on the bottom surface of the cavity  12  of the mold  11 . After that, the mold  11  was heated to 170° C., and then the cavity  12  was filled with the epoxy resin composition  16 . After that, another copper foil (the conductive layer  14   b ) was disposed on the epoxy resin composition  16 . Then, the epoxy resin composition  16  was cured at 170° C. for 10 minutes with no magnetic field applied to produce a laminate of 2 mm in thickness. Next, the laminate was used to produce the printed wiring board  2  in the same manner as in Example 1.  
     Comparative Example 2  
      An epoxy resin composition prepared by mixing terephthalylidene-bis-(4-amino-3-methylphenol)diglycidyl ether having a mesogenic group in a molecule as an epoxy resin and 4,4′-diamino-1,2-diphenylethane as a curing agent in a ratio of 1 mole:0.5 mole was used to produce a printed wiring board containing neither fiber cloth nor fiber. The same copper foil as that of Example 1 was used as a conductive layer. Copper foil (the conductive layer  14   a ) was disposed on the bottom surface of the cavity  12  of the mold  11 . After that, the mold  11  was heated to 170° C., and then the cavity  12  was filled with the epoxy resin composition. After that, another copper foil (the conductive layer  14   b ) was disposed on the epoxy resin composition  16 . Next, the resultant was cured at 170° C. for 10 minutes in a magnetic field having a magnetic flux density of 10 tesla to produce a printed wiring board having a thickness of 2 mm. The directions of the lines of magnetic force M were aligned with the thickness direction of the laminate. Next, the laminate was used to produce the printed wiring board  2  in the same manner as in Example 1.  
     Comparative Example 3  
      The same epoxy resin composition  16 , glass cloth, and copper foil as those of Example 1 were used. The number of glass cloths was set in such a manner that the content of the glass cloth in a formed article would be 17 vol %. At first, copper foil (the conductive layer  14   a ) was disposed on the bottom surface of the cavity  12  of the mold  11 , and ten glass cloths were disposed in a stack over the foil to be parallel to the bottom surface of the cavity  12 . After that, the mold  11  was heated to 170° C., and then the cavity  12  was filled with the epoxy resin composition  16  to impregnate the epoxy resin composition  16  into the glass cloths  15 . After that, another copper foil (the conductive layer  14   b ) was disposed on the epoxy resin composition  16 . After that, the epoxy resin composition  16  was cured at 170° C. for 10 minutes with no magnetic field applied. Thus, a laminate of 2 mm in thickness was obtained. Next, the laminate was used to produce the printed wiring board  2  in the same manner as in Example 1.  
      As for a portion of the epoxy resin composite formed article in each of the printed wiring boards produced in Examples 1 to 6 and Comparative Example 2, the degree of orientation α of the epoxy resin of was measured. A test piece (2 mm in thickness) was used to determine the degree of orientation α of the epoxy resin from an X-ray diffraction pattern measured by means of an X-ray diffraction instrument (“M18XHF 22 -SRA” manufactured by MAC Science Co., Ltd). Each test piece is composed only of the epoxy resin composite formed article portion of each of the printed wiring boards of Examples 1 to 6 and Comparative Example 2.  
      In addition, the thermal expansion coefficients of the epoxy resin composite formed article portion of each of the printed wiring boards  2  produced in the respective examples and comparative examples in the direction along the surface of the printed wiring board  2  and in the thickness direction of the printed wiring board  2  were measured. A test piece (2 mm) was used to measure a thermal expansion coefficient by means of an apparatus for thermomechanical analysis (“TMA-50” manufactured by Shimadzu Corporation) at a load of 3 g and a rate of temperature increase of 10° C./min. Each test piece is composed only of the epoxy resin composite formed article portion of each of the printed wiring boards of the respective examples and comparative examples.  
      Furthermore, a through-hole reliability test was conducted on each of the printed wiring boards  2 . Each of the printed wiring boards  2  was immersed in oil at 260° C. for 10 seconds and in water at 20° C. for 10 seconds in conformance with JIS-C0025. This operation was defined as one cycle. The cycle was repeated, and the number of cycles at which any breakage of wirings occurred was counted.  
      Table 1 shows the measured values and test results of the printed wiring boards produced in Examples 1 to 6 and Comparative Examples 1 to 3.  
                           TABLE 1                                          Comparative           Example   Example                                                         1   2   3   4   5   6   1   2   3                                                                 Content of glass cloth (vol %)   8 (3)     14 (5)     17 (10)     17 (10)     —   17 (10)     —   —   17 (10)         (Number of glass cloths)       Content of glass fibers (vol %)   —   —   —   —   21       —   —   —       Magnetic flux density (tesla)   10   10   10   5   10   10   0   10   0       Degree of orientation α   0.72   0.72   0.72   0.70   0.72   0.70   —   0.72   —       Thermal expansion coefficient   18   20   23   21   10   25   66   3.5   93       in thickness direction (10 −6 /K)       Thermal expansion coefficient   40   21   15   16   40   14   69   105   17       in direction along surface (10 −6 /K)       Through-hole reliability   160   250   270   265   230   255   50   70   20       (Number of cycles)                  
 
      As is apparent from the results shown in Table 1, in each of Examples 1 to 4 and 6, each of the thermal expansion coefficients in the direction along the surface of the wiring board in which the glass cloth extends and in the thickness direction in which the molecular chains of the epoxy resin were oriented exhibited a lower value, namely, 40×10 −6 /K or less. In Example 5 as well, the thermal expansion coefficient in the direction along the surface of the wiring board as well as that in the thickness direction in which the molecular chains of the epoxy resin was oriented exhibited a lower value (40×10 −6 /K or less). The reason for this is probably as follows. The each fiber axis of the glass fibers added to the epoxy resin composition  16  were oriented in the direction along the surface of the wiring board because the composition was molded into a plate-like shape. Even when a magnetic field was applied thereafter, the fibers were hardly influenced by the magnetic field because of its relative long fiber length (3 mm), and hence the oriented state was maintained. Accordingly, in each of Examples 1 to 6, the difference between the thermal expansion coefficient in the direction along the surface and the thermal expansion coefficient in the thickness direction is at most 30×10 −6 /K (in Example 3). This shows that a printed wiring board composed of an epoxy resin composite in which thermal expansion coefficients are controlled to be small in both the direction along the surface of the wiring board and the thickness direction were obtained in each of these Examples. In addition, each of the printed wiring boards of Examples 1 to 6 had better through-hole reliability than that of each of the printed wiring boards of Comparative Examples 1 to 3.  
      On the other hand, in Comparative Example 1, the difference between the thermal expansion coefficients in the direction along the surface of the wiring board and in the thickness direction was small, but each of the thermal expansion coefficients exceeded 60×10 −6 /K. In Comparative Example 2, the thermal expansion coefficient in the thickness direction, in which the molecular chains of the epoxy resin were oriented, showed a lower value, but the thermal expansion coefficient in the direction along the surface showed an extremely higher value. In Comparative Example 3, the thermal expansion coefficient in the direction along the surface in which a glass cloth expanded showed a lower value, but the thermal expansion coefficient in the thickness direction showed a higher value. In addition, none of the printed wiring boards of Comparative Examples 1 to 3 provided sufficient through-hole reliability.  
      Printed wiring board formed of thermoplastic polymer composite formed article  
     Example 7  
      A printed wiring board using the thermoplastic polymer composite formed article  10  of the present invention as an insulating layer and copper foil as a conductive layer was produced. The thermoplastic polymer composition  160  containing a thermoplastic polymer including 4-hydroxy benzoate/(terephthalic acid and ethylene glycol (molar ratio 1:1))=80/20 mol% as a repeating unit was used. A “1080” manufactured by Asahi-Schwebel Co., Ltd. serving as a glass cloth (having a weight of 48 g/m 2  and a density of 60 (vertical)×47 (horizontal) fibers/inch) was used as the fiber cloth  15 . Electrolytic copper foil manufactured by NIKKO MATERIALS Co., Ltd. (having a thickness of 18 μm) was used as each of the conductive layers  14   a  and  14   b.  The number of glass cloths to be used was set in such a manner that the content of the glass cloth in a formed article would be 3.7 vol %.  
      At first, copper foil (the conductive layer  14   a ) was disposed on the bottom surface of the cavity  12  of the mold  11 . Then the thermoplastic polymer composition  160  preliminarily molded into a sheet having a thickness of 0.40 mm and the glass cloth  15  were disposed in a stack over the foil to be parallel to the bottom surface of the cavity  12 . Four tiers each composed of the thermoplastic polymer composition  160  and the glass cloth  150  were superimposed, and then a sheet of the thermoplastic polymer composition  160  was disposed thereover. Then, another copper foil (the conductive layer  14   b ) was disposed on the resultant. After that, the mold was heated and pressurized at 310° C. for 15 minutes in a magnetic field having a magnetic flux density of 10 tesla, and was then slowly cooled to room temperature to produce a laminate of 2 mm in thickness. The directions of the lines of magnetic force M were aligned with the thickness direction of the laminate. Next, the laminate was drilled to form 200 holes each having a hole diameter of 0.9 mm therein, and was subjected to a copper through-hole plating treatment. After that, the resultant was patterned in such a manner that the land diameter of each hole, the circuit width, and the circuit interval would be 1.3 mm, 0.2 mm, and 0.2 mm, respectively, to thereby produce the printed wiring board  20 .  
     Example 8  
      The printed wiring board  20  was produced in the same manner as in Example 7 except that the number of glass cloths to be disposed in the cavity  12  (the content of the glass cloth) was changed as shown in Table 2.  
     Example 9  
      The printed wiring board  20  was produced in the same manner as in Example 7 except that the number of glass cloths to be disposed in the cavity  12  (the content of the glass cloth) and a magnetic flux density were changed as shown in Table 2.  
     Example 10  
      The printed wiring board  20  was produced in the same manner as in Example 7 except that: the thermoplastic polymer composition  160  synthesized by reacting 2,2′-bipyridine-4,4′-dicarboxylic acid with 1,12-diaminododecane was used as a thermoplastic polymer; and the number of glass cloths to be disposed in the cavity  12  (the content of the glass cloth) was changed as shown in Table 2.  
     Example 11  
      The same thermoplastic polymer as that of Example 7 was mixed with glass fibers “CS03BC273” manufactured by Asahi Fiber-Glass Co., Ltd. (1 mm in fiber length) as single fibers instead of the glass cloths of Examples 7 to 10 to prepare the thermoplastic polymer composition  160 . The amount of glass fibers to be added was set in such a manner that the content of the glass fibers in the thermoplastic polymer composition 160 would be 19 vol %. At first, the thermoplastic polymer composition  160  was injected into the mold  11  placed in a magnetic field having a magnetic flux density of 10 tesla. The resultant was heated and pressurized at 310° C. for 15 minutes, and was then slowly cooled to room temperature. Thereby, the thermoplastic polymer composite formed article  10  having a thickness of 2 mm was obtained. The directions of the lines of magnetic force M were aligned with the thickness direction of the formed article. Next, both surfaces of the thermoplastic polymer composite formed article  10  were plated with copper to form the conductive layers  14   a  and  14   b.  The thermoplastic polymer composite formed article  10  having the conductive layers  14   a  and  14   b  was patterned in the same manner as in Example 1 to produce the printed wiring board  20 .  
     Comparative Example 4  
      A thermoplastic polymer composition  160  identical to that of each of Examples 7 to 9 was used to produce a printed wiring board containing neither fiber cloth nor fiber. The same copper foil as that of Example 7 was used as a conductive layer. At first, copper foil (the conductive layer  14   a ) was disposed on the bottom surface of the cavity  12  of the mold  11 . After that, the thermoplastic polymer composition  160  preliminarily molded into a sheet of 2 mm in thickness was disposed on the foil to be parallel to the bottom surface of the cavity  12 . Then, another copper foil (the conductive layer  14   b ) was disposed on the composition. The mold was heated and pressurized at 310° C. for 15 minutes with no magnetic field applied, and was then slowly cooled to room temperature to produce a laminate of 2 mm in thickness. Next, the laminate was used to produce a printed wiring board in the same manner as in Example 1.  
     Comparative Example 5  
      The thermoplastic polymer composition  160  identical to that of each of Examples 7 to 9 was used to produce a printed wiring board containing neither fiber-cloth nor fiber. The same copper foil as that of Example 7 was used as a conductive layer. At first, copper foil (the conductive layer  14   a ) was disposed on the bottom surface of the cavity  12  of the mold  11 . After that, the thermoplastic polymer composition  160  preliminarily molded into a sheet of 2 mm in thickness was arranged on the foil to be parallel to the bottom surface of the cavity  12 . Then, another copper foil (the conductive layer  14   b ) was disposed on the composition. After that, the mold-was heated and pressurized at 310° C. for 15 minutes in a magnetic field having a magnetic flux density of 10 tesla, and was then slowly cooled to room temperature to produce a laminate of 2 mm in thickness. The directions of the lines of magnetic force M were aligned with the thickness direction of the laminate. Next, the laminate was used to produce a printed wiring board in the same manner as in Example, b  7 .  
     Comparative Example 6  
      A printed wiring board was produced in the same manner as in Example 9 using a thermoplastic polymer composition and a glass cloth composed of the same materials in the same amounts as those of Example 9 except that no magnetic field was applied upon molding.  
      As for the thermoplastic polymer composite formed article portion of each of the printed wiring boards produced in Examples 7 toll and Comparative Examples 4 to 6, the degree of orientation α of the thermoplastic polymer, and thermal expansion coefficients in the direction along the surface of the printed wiring board and in the thickness direction of the printed wiring board were measured in the same manners as those described above with respect to Examples 1 to 6 and Comparative Example 2. The degree of orientation ay in each of Comparative Examples 4 and 6 could not be calculated because no peak was observed in the X-ray diffraction intensity distribution of a test piece of the each of these Comparative Examples.  
      Furthermore, a through-hole reliability test was conducted on each of the printed wiring boards. Each of the printed wiring boards  2  was immersed in silicone oil at 260° C. for 5 seconds and in 2-propanol at 20° C. for 20 seconds in conformance with JIS-C5012. This operation was defined as one cycle. The cycle was repeated, and the number of cycles at which cracking, peeling, or breaking of wiring occurred was counted.  
      Table 2 shows the measured values and test results of the printed wiring boards produced in Examples 7 to 11 and Comparative Examples 4 to 6.  
                           TABLE 2                                          Comparative           Example   Example                                                     7   8   9   10   11   4   5   6                                                             Content of glass cloth (vol %)   3.7 (4)     6.5 (7)     6.5 (7)     5.6 (6)     —   —   —   6.5 (7)         (Number of glass cloths)       Content of glass fibers (vol %)   —   —   —   —   19   —   —   —       Magnetic flux density (tesla)   10   10   5   10   10   0   10   0       Degree of orientation α   0.82   0.82   0.78   0.81   0.83   —   0.90   —       Thermal expansion coefficient   6   10   22   25   28   181   −1   127       in thickness direction (10 −6 /K)       Thermal expansion coefficient   35   20   13   29   27   44   178   13       in direction along surface (10 −6 /K)       Through-hole reliability   196   263   254   260   258   59   23   33       (Number of cycles)                  
 
      As is apparent from the results shown in Table 2, in each of Examples 7 to 10, each of the thermal expansion coefficients in the direction along the surface of the wiring board in which a glass cloth extended and in the thickness direction in which the molecular chains of the thermoplastic polymer were oriented exhibited a lower value (35×10 −6 /K or less). In Example 5, in which a glass single fiber was used, as well, the thermal expansion coefficient in the direction along the surface of the wiring board as well as that in the thickness direction in which the molecular chains of the thermoplastic polymer was oriented exhibited a lower value (28×10 −6 /K or less). The reason for this is probably as follows. Each major axis of the glass fibers in the thermoplastic polymer composition  160  were oriented in the direction along the bottom surface of the cavity  12  of the mold  11 , that is, the direction along the surface of the laminate owing to a flow of the composition  160  caused by injecting the composition  160  into the cavity  12 . Even when a magnetic field was applied in the thickness direction of the laminate thereafter, the glass fiber was hardly influenced by the magnetic field because of its small anisotropic diamagnetic susceptibility χ a , and hence the oriented state was maintained.  
      Accordingly, in a printed wiring board obtained in each of Examples 7 to 11, the difference between the thermal expansion coefficients in the direction along the surface and in the thickness direction is at most 29×10 −6 /K (Example 1). This shows that a printed wiring board composed of a thermoplastic polymer composite formed article in which thermal expansion coefficients are controlled to be small in both the direction along the surface of the wiring board and in the thickness direction was obtained in these embodiments. In addition, each of the printed wiring boards of Examples 7 to 11 had better through-hole reliability than that of each of the printed wiring boards of Comparative Examples 4 to 6.  
      On the other hand, in Comparative Example 4, the thermal expansion coefficient in the direction along the surface showed a relatively lower value, but the thermal expansion coefficient in the thickness direction showed a higher value. In Comparative Example 5, the thermal expansion coefficient in the thickness direction in which the molecular chains of the thermoplastic polymer were oriented showed an extremely lower value, but the thermal expansion coefficient in the direction along the surface showed a higher value. In Comparative Example 6, the thermal expansion coefficient in the direction along the surface in which a glass cloth expanded showed a lower value, but the thermal expansion coefficient in the thickness direction showed a higher value. In addition, none of the printed wiring boards of Comparative Examples 4 to 6 provided sufficient through-hole reliability.