Patent Publication Number: US-7582980-B2

Title: Drive apparatus for hybrid vehicle

Description:
This application is a continuation of application Ser. No. 10/498,828 filed Oct. 7, 2004 now U.S. Pat. No. 7,239,033 which is a 371 of PCT/IB02/05582 filed Dec. 23, 2002. 

   BACKGROUND OF THE INVENTION 
   1. Field of the Invention 
   The invention relates to a drive apparatus for a hybrid vehicle that is preferably used in a hybrid vehicle provided with an engine and an electric motor, which are two types of power sources having different characteristics, and which runs by using the driving power from these two power sources in a combination that is optimal for the conditions. 
   2. Description of the Related Art 
   In recent years a hybrid vehicle provided with an engine and an electric motor, which are two types of power sources having different characteristics, has been developed and put into practical use. In this hybrid vehicle, the strengths of each power source are used to compensate for the weaknesses of the other by using the driving power from the type types of power sources in a combination that is optimal for the conditions. As a result, the power performance of the vehicle is able to be sufficiently ensured and the fuel consumption rate and emission performance are able to be largely improved. 
   Various proposals have been made for the drive apparatus to be used in this type of hybrid vehicle. One proposal includes the use of a first motor generator, a power splitting mechanism portion, and a second motor generator. The first motor generator serves mainly as a generator. The power splitting mechanism portion includes a planetary gear set and divides the power generated by the engine into power for the first motor generator and power for the driven wheels. The second motor generator serves mainly as a motor and generates power to assist in driving the driven wheels. This power is different from the power that is from the engine. 
   In this drive apparatus, part of the power that has been split by the power splitting mechanism portion is transmitted mechanically to the driven wheel to rotate it, and the rest of the power that has been split is transmitted to the first motor generator. Using the power transmitted to the first motor generator, the first motor generator functions as a generator and generates electricity which is supplied to the second motor generator. Using this electricity, the second motor generator functions as a motor. The power generated by this second motor generator is added to the power that was split by the power splitting mechanism portion and transmitted to the driven wheel, thereby assisting the output of the engine in driving the driven wheel. 
   Also, as art relating to the layout of each of the component parts in the drive apparatus for a hybrid vehicle, art in which a first motor generator, a second motor generator, and a planetary gear set are arranged in-line is disclosed in Japanese Patent Application Laid-Open Publication No. 6-144020. This arrangement is advantageous in that the build, more particularly the outside diameter, becomes gradually smaller farther away from the engine, thereby enabling the entire apparatus to be made compact. 
   With the drive apparatus for a hybrid vehicle, it is conceivable to add a speed reducing mechanism portion to reduce the rotation speed and to increase the torque of the second motor generator which serves as the motor. With the drive apparatus disclosed in the aforementioned publication, however, a layout when this speed reducing mechanism portion is added to the planetary gear set as a power splitting mechanism portion is not shown in detail. Therefore, there is a desire for a drive apparatus in which the entire apparatus, including this speed reducing mechanism portion, can be made compact. 
   SUMMARY OF THE INVENTION 
   In view of the foregoing circumstance, it is an object of this invention to provide a drive apparatus for a hybrid vehicle in which a speed reducing mechanism portion is able to be mounted while making the entire apparatus compact. 
   Hereinafter, the method and effects for achieving the foregoing object shall be described. 
   A drive apparatus for a hybrid vehicle according to a first aspect of the invention to achieve the foregoing object is provided with a first motor generator which functions as one of a motor and a generator; a power splitting mechanism portion that divides power generated by an engine into power for the first motor generator and power for a driven wheel; a second motor generator which is arranged on a side of the first motor generator opposite the engine, which functions as one of a motor and a generator, which generates power to drive the driving wheel, this power being different from the power that is from the engine, and which has an outside diameter that is smaller than an outside diameter of the first motor generator; and a speed reducing mechanism portion which is arranged on a side of the second motor generator opposite the engine, which has an outer diameter that is smaller than an outside diameter of the second motor generator, and which reduces a rotation speed and increases a torque of the second motor generator. 
   According to the drive apparatus for a hybrid vehicle of the aforementioned construction, the power generated by the engine is divided into two by the power splitting mechanism portion. Part of the power is transmitted mechanically to the driven wheel so as to rotate it and the rest of the power is transmitted to the first motor generator. Using the power transmitted to the first motor generator, the first motor generator functions as a generator and generates electricity which is supplied to the second motor generator. Using this electricity, the second motor generator functions as a motor. The power generated by this second motor generator is added to the power that was split by the power splitting mechanism portion and transmitted to the wheels, thereby assisting the output of the engine in driving the driven wheel. 
   According to the drive apparatus for a hybrid vehicle, at least both of the motor generators and the speed reducing mechanism portion, from among the component parts, are arranged in the order of the first motor generator, the second motor generator, and the speed reducing mechanism portion from the side near the engine to the side away from the engine. In addition to the outside diameter of the second motor generator being smaller than the outside diameter of the first motor generator, the outside diameter of the speed reducing mechanism portion is also smaller than the outside diameter of the second motor generator. Therefore, by having the outside diameter of the power splitting mechanism portion be smaller than the outside diameter of the first motor generator, the drive apparatus takes on a conical shape in which the outside diameter thereof becomes increasingly small away from the engine. In this way, according to the invention described above, it is possible to incorporate the speed reducing mechanism portion into the drive apparatus while making the entire apparatus compact. 
   Furthermore, the mountability in the hybrid vehicle of this drive apparatus that has been made compact in this way is excellent. In particular, the shape of the entire drive apparatus for a hybrid vehicle is substantially the same as the shape of a typical automatic transmission with a torque converter and a gear change mechanism. Therefore, by designing the drive apparatus for a hybrid vehicle so that it is substantially the same size as the automatic transmission, the drive apparatus is able to be housed in a floor tunnel that already exists in vehicles for housing the automatic transmission. Therefore, it is possible to arrange the drive apparatus, instead of the automatic transmission, in this floor tunnel. 
   A drive apparatus for a hybrid vehicle according to another aspect of the invention has an outside shape that becomes increasingly narrow away from the engine, and is further provided with a core case in which to mount both of the motor generators and the power splitting mechanism portion, a case formed separate from the core case, in which to mount the speed reducing mechanism portion, and a joining portion with which to join the case to the core case. 
   According to this construction, when expanding the use of the drive apparatus to a wide variety of hybrid vehicles, if the specifications, such as those of the gear ratio of the speed reducing mechanism portion, can be conformed to the vehicle, the motor generators and the power splitting mechanism portion and the like can be used as they are as common parts. Here, the case in which the speed reducing mechanism portion is mounted is independent from the core case in which both of the motor generators and the power splitting mechanism portion are mounted, and these cases can be joined to, and separated from, one another. As a result, by preparing a unit part in which the speed reducing mechanism portion is mounted in the case for each type of hybrid vehicle, there only needs to be one type of unit (core unit) in which both of the motor generators and the power splitting mechanism portion are mounted in the core case, regardless of the type of the hybrid vehicle. Then, when assembling a plurality of kinds of the drive apparatuses in an assembly plant or the like, the unit part in which the particular speed reducing mechanism portion that matches the type of drive apparatus is simply selected and attached to the common core unit. 
   Further, a drive apparatus for a hybrid vehicle according to another aspect of the invention is further provided with a first connecting portion to electrically connect a first cable to the first motor generator, and a second connecting portion to electrically connect a second cable to the second motor generator. In addition, the power splitting mechanism portion is arranged between the first motor generator and the second motor generator and includes a planetary gear set which has a ring gear that has a smaller outside diameter than the outside diameters of the first motor generator and the second motor generator. The first connecting portion and the second connecting portion are provided in a space that exists toward the outside in the radial direction of the ring gear between the first motor generator and the second motor generator. 
   According to this construction, the power splitting mechanism portion is constructed with a planetary gear set arranged between the two motor generators. In addition, the outside diameter of the ring gear, which determines the outer shape of the entire planetary gear set, is smaller than the outside diameters of both of the motor generators. As a result, a space is created toward the outside in the radial direction of the ring gear between the two motor generators. According to this invention described above, a first connecting portion to electrically connect a first cable to the first motor generator is provided in this space. In addition, a second connecting portion to electrically connect a second cable to the second motor generator is also provided in this space. In this way, by providing both of the connecting portions together in the space between the motor generators, space is able to be used efficiently. As a result, both connecting portions are able to be arranged without losing compactness of the drive apparatus. 
   A drive apparatus for a hybrid vehicle according to another aspect of the invention is further provided with a drive case in which the first motor generator and the second motor generator are mounted, and which has an outside shape that becomes increasingly narrow away from the engine; a first outlet, which is provided in the drive case and which is formed curved away from the engine, and through which the first cable that is connected to the first motor generator is led out of the drive case; and a second outlet, which is provided in the drive case on a side of the first outlet opposite the engine and which is formed parallel to the first outlet, and through which the second cable that is connected to the second motor generator is led out of the drive case. 
   According to this construction, the first cable that is connected to the first motor generator is led out of the drive case through the first outlet. Also, the second cable that is connected to the second motor generator is led out of the drive case through the second outlet. Here, the first outlet and the second outlet are both provided in the drive case which becomes increasingly narrow away from the engine. Also, the second outlet is positioned on the side of the first outlet opposite the engine, i.e., in a location having a smaller diameter than the first outlet in the drive case. In addition, both the first outlet and the second outlet are curved away from the engine and parallel to each other. As a result, when the connection mates of both of the cables are provided on the side of the drive apparatus opposite the engine, both of the cables can be led out to the outside of the drive case together without interfering with one another and laid toward the connection mate. 
   Also, a drive apparatus for a hybrid vehicle according to another aspect of the invention is further provided with a drive case which has an outside shape that becomes increasingly narrow away from the engine and in which the first motor generator and the second motor generator are mounted; a first case which forms part of the drive case and which is provided with a first main portion fixed to the engine and a first housing portion formed within the first main portion, which houses the first motor generator; a second case which forms part of the drive case and which is joined to the first main portion; a first cover which is arranged on the engine side of the first generator within the first main portion and which covers the first motor generator; and a first fastening member that attaches a first flange formed on an outer edge portion of the first cover to the first housing portion. 
   According to this construction, in this drive apparatus, the drive case in which the motor generator is mounted has an outside shape that becomes increasingly narrow away from the engine. The first case that forms part of the drive case is fixed to the engine at the first main portion which is the outside portion (outer shell) of the first case. The motor generator is housed in the first housing portion formed within the first main portion. Also, the second case that forms part of the drive case, just as does the first case, is joined to the first main portion. 
   A cover, which covers the motor generator, is arranged within the first main portion. The cover is attached to the first housing portion by a first fastening member at a flange formed on an outer edge portion of the cover. Here, when the cover is not used, the size (outside diameter) in the radial direction of the first case is used as a reference. In this case, the outside diameter of the first case is actually determined only by the thickness of the first main portion. In contrast, when the cover is used, the outside diameter of the first case is determined by a width of the flange on the cover and a gap between the flange and the inside surface of the first main portion, in addition to the aforementioned thickness of the first main portion. 
   Regarding this point, according to the invention described above, the cover is arranged on the engine side of the motor generator within the first main portion. The outside diameter of the first main portion at this location is comparatively larger than the general outside diameter around the first main portion. In particular, the diameter of the first main portion at a location corresponding to the end portion on the engine side of the first housing portion is definitely larger than the diameter of the first main portion at a location corresponding to the end portion on the side of the first housing portion opposite the engine. The size relationship of the distance between the inside surface of the first housing portion and the inside surface of the first main portion is the same as described above. Therefore, because the distance tends to be larger than the sum of the width of the first flange on the first cover and the gap between the first flange and the first main portion, in this case, even if the first main portion does not extend outward in the radial direction, the first cover can still be arranged within the first main portion and attached to the first housing portion by the first fastening member. 
   In this way, it is possible to suppress the outside diameter of the first case from becoming larger with the first cover attached, and therefore maintain the original outer shape of the drive case, in which it becomes increasingly narrow away from the engine. This outer shape is similar to the outer shape of an automatic transmission provided with a torque converter and a gear change mechanism, which is housed in a vehicle having a front engine rear drive (i.e., FR) type drive system. As a result, it is possible to arrange the drive apparatus, instead of an automatic transmission, in a floor tunnel that ordinarily houses the automatic transmission, and thus improve mountability of the drive apparatus in the vehicle. 
   Also, the drive apparatus for a hybrid vehicle is further provided with a second main portion which is provided with the second case and which is joined to the first main portion; a second housing portion which is formed within the second main portion and which houses a second motor generator that functions as one of a motor and a generator; a second cover which is arranged on the engine side of the second motor generator within the second main portion and which covers the second motor generator; and a second fastening member that attaches a second flange formed on an outer edge portion of the second cover to the second housing portion. 
   According to this construction, in this drive apparatus, the second case that forms part of the drive case, just as does the first case, is joined to the first main portion at the second main portion that is the outside portion (outer shell) of the second case. The second motor generator is housed in the second housing portion formed within the second main portion. 
   A second cover that covers the second motor generator is formed within the second main portion. This second cover is attached to the second housing portion by second fastening member at a second flange formed on an outer edge portion of the second cover. Here, when the cover is not used, the size (outside diameter) in the radial direction of the second case is used as a reference. In this case, the outside diameter of the second case is actually determined only by the thickness of the second main portion. In contrast, when the cover is used, the outside diameter of the second case is determined by a width of the second flange on the second cover and a gap between the second flange and the inside surface of the second main portion, in addition to the aforementioned thickness of the second main portion. 
   This drive apparatus for a hybrid vehicle is such that the second cover is arranged on the engine side of the second motor generator within the second main portion. The outside diameter of the second main portion in this location is comparatively larger than the general outside diameter around the second main portion. In particular, the outside diameter of the second main portion in the location corresponding to the end portion on the engine side of the second housing portion is definitely larger than the outside diameter of the second main portion at a location corresponding to the end portion on the side of the second housing portion opposite the engine. The size relationship of the distance between the inside surface of the second housing portion and the inside surface of the second main portion is the same as described above. Therefore, because the distance tends to be larger than the sum of the width of the second flange on the second cover and the gap between second flange and the inside surface of the second main portion, in this case, even if the second main portion does not extend outward in the radial direction, the second cover can still be arranged within the second main portion and attached to the second housing portion by the second fastening member. In this way, it is possible to suppress the outside diameter of the second case from becoming larger with the second cover attached, such that mountability of the drive apparatus in the vehicle is further improved. 
   In the drive apparatus for a hybrid vehicle, the speed reducing mechanism portion includes a planetary gear set and is arranged on the same axis as the axial center of the first motor generator, the second motor generator, and the power splitting mechanism portion. 
   According to this construction, the speed reducing mechanism portion can achieve a large reduction ratio because it includes a planetary gear set. Also, the size of the drive system in the radial direction is minimized by arranging the first motor generator, the second motor generator, the power splitting mechanism portion, and the speed reducing mechanism portion, which together make up the drive apparatus, on the same axis. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIG. 1  is a bottom view schematically showing a hybrid vehicle having a drive apparatus which is a first exemplary embodiment of the invention; 
       FIG. 2  is a cross-sectional view of the drive apparatus according to the first exemplary embodiment; 
       FIG. 3  is a side view of a core case of the drive apparatus as viewed from the output shaft side; 
       FIG. 4  is an expanded view of part of the drive apparatus shown in  FIG. 2 ; 
       FIG. 5  is an expanded view of part of the drive apparatus shown in  FIG. 2 ; and 
       FIG. 6  is an expanded view of part of the drive apparatus shown in  FIG. 2 . 
   

   DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
   Hereinafter, a first exemplary embodiment of the invention, in which a hybrid vehicle having a front engine rear drive (i.e., FR) type drive system has been implemented, will be described with reference to the drawings.  FIG. 1  is a block diagram schematically showing a hybrid vehicle  11  as seen from below. The hybrid vehicle  11  shown here is provided with two types of power sources, an engine  12  and an electric motor, which have different characteristics. The hybrid vehicle  11  runs by transmitting driving power to driven wheels  13  from these two power sources in a combination that is optimal for the conditions. In the figure, the front of the hybrid vehicle  11  is to the left and the rear is to the right. 
   Between the engine  12  and the driven wheels  13  are provided a drive apparatus  14 , a propeller shaft  15 , a differential  16 , and a pair of axle shafts  17  and the like. The drive apparatus  14  will be described in detail later. The propeller shaft  15  is a shaft that transmits output force from the drive apparatus  14  to the differential  16 . The differential  16  is a differential gear that divides power from the propeller shaft  15  and transmits it to both of the axle shafts  17 . Each axle shaft  17  is an axle that transmits the power divided by the differential  16  to the driven wheels  13 . 
   Among these parts, the drive apparatus  14  and the propeller shaft  15  are arranged in a floor tunnel  19  provided in a floor  18  of the hybrid vehicle  11 . The portion of the floor tunnel  19  in which the drive apparatus  14  is arranged is widest near the engine  12  and becomes increasingly narrow away from the engine  12 . In a vehicle having an FR type drive system such as this, the space in the floor tunnel  19  is used to house the drive apparatus  14  and the propeller shaft  15 . This space is narrower than the housing space in a vehicle having a different type of drive system such as a front engine front drive (i.e., FF) type system. 
   As shown in  FIG. 2 , a drive case  21  of the drive apparatus  14  includes a core case  22  which is formed of a first case  23  and a second case  24 , and a third case  25 . These cases  23  through  25  are arranged in order along an axial line L of a crankshaft  47 , which is an output shaft of the engine  12 , toward the side (the right side in  FIG. 2 ) away from the side near the engine  12  (the left side in  FIG. 2 ). 
   Referring to  FIG. 4 , the first case  23  includes a first main portion  23   a , which is the outside (outer shell) portion of the first case  23 , and a first housing portion  23   b  integrally formed with the inner portion of the first main portion  23   a . The first main portion  23   a  has a cylindrical outer shape and is fastened at an end portion thereof on the engine  12  side to the engine  12  with a fastening member, not shown, such as a bolt. The diameter (both outside diameter and inside diameter) of the first main portion  23   a  is greatest at the end portion on the engine  12  side and gradually decreases farther away from the engine  12  until the mid portion in the axial direction. The diameter of the first main portion  23   a  at the end portion on the driven wheel side is partly and slightly larger than the diameter of the mid portion in the axial direction in order to ensure space to attach a first cable  63 , to be described later. 
   The first housing portion  23   b  has a substantially cylindrical shape with one end closed, in which the inside diameter is substantially the same at any given location. The end portion of the first housing portion  23   b  on the engine side does not extend as far (toward the driven wheels  13  side) as the end portion of the first main portion  23   a  on the engine side. Also, the end portion of the first housing portion  23   b  on the driven wheel side does not extend as far (toward the engine  12  side) as the end portion of the first main portion  23   a  on the driven wheel side. The end portion of the first housing portion  23   b  is constructed with a first support wall  31  formed substantially orthogonal with respect to the axial line L at the end portion of the first housing portion  23   b  on the driven wheel side. 
   As shown in  FIGS. 5 and 6 , a second case  24  includes a second main portion  24   a  which forms the outside (outer shell) portion of the second case  24  and a second housing portion  24   b  integrally formed with the inner portion of the second main portion  24   a . The second main portion  24   a  has a substantially cylindrical external shape and is fastened at an end portion thereof on the engine side to the first main portion  23   a  with a fastening member, not shown, such as a bolt. The diameter (both outside diameter and inside diameter) of the second main portion  24   a  is greatest at the end portion on the side of the engine  12  and gradually decreases farther away from the engine  12  until the mid portion in the axial direction. 
   The second housing portion  24   b  has a substantially cylindrical shape with one end closed, and has a slightly smaller diameter than the first housing portion  23   b  described above. The inside diameter of the second housing portion  24   b  is substantially the same in any given location. The end portion of the second housing portion  24   b  on the engine side does not extend as far (toward the driven wheel  13  side) as the end portion of the second main portion  24   a  on the engine side. Also, the end portion of the second housing portion  24   b  on the driven wheel side is in substantially the same position with respect to the axial line L as the end portion of the second main portion  24   a  on the driven wheel side. The end portion of the second housing portion  24   b  is constructed with a second support wall  38  formed substantially orthogonal with respect to the axial line L at the end portion of the second housing portion  24   b  on the driven wheel side. 
   Referring to  FIG. 6 , the third case  25  has a conical shape in which the diameter (both outside diameter and inside diameter) becomes increasingly smaller farther away from the engine  12 . The third case  25  is fastened at an end portion thereof on the engine side to the second case  24  by a fastening member  26  such as a bolt. 
   The drive case  21  formed of the first through the third cases  23  through  25  in this way has an outer shape in that becomes increasingly narrow away from the engine  12 . This outer shape is similar to the outer shape of a typical automatic transmission provided with a fluid type torque converter and a gear change mechanism, which is housed in a vehicle having a FR type drive system. 
   Referring back to  FIG. 2 , a first motor generator (hereinafter referred to as “MG 1 ”), a power splitting mechanism portion  27 , a second motor generator (hereinafter referred to as “MG 2 ”) and a speed reducing mechanism portion  28  are arranged in-line on the axial line L in the drive case  21  in that order from the side near the engine  12  to the side away from the engine  12  (i.e., toward the driven wheels  13  side). The MG 1  and the MG 2  are both constructed of an electric motor, such as an alternating current synchronized motor, that can switch to function as either a generator or an electric motor depending on the conditions. During normal running of the vehicle, however, the MG 1  mainly serves as a generator that generates electricity by the power from the engine  12 . Further, the MG 2  mainly serves as a motor that generates power to assist the engine  12 . Phrased differently, when the MG 2  functions as a motor, it provides power that is used to assist the power of the engine  12  as necessary, and thus serves as an auxiliary power source to the engine  12  to increase the driving force of the vehicle. Of course, the MG 1  and MG 2  may, instead of both being able to function as both a generator and a motor, each have only one of those functions. 
   Next, the MG 1  and MG 2  will be described. Referring to  FIG. 4 , a first cover  29  is arranged substantially orthogonal to the axial line L and on the engine  12  side of the first housing portion  23   b  in the first case  23 . The first cover  29  is large enough to close off the open end of the first housing portion  23   b  on the engine side. A first flange  29   a  is formed on the outer edge portion of the first cover  29 , and this first flange  29   a  of the first cover  29  overlaps with the end portion of the first housing portion  23   b  on the engine side. Then, a first bolt  30  which is a first fastening member, of a plurality of bolts (only one bolt is shown in  FIG. 4 ) as first attaching means is inserted from the engine  12  side through the first flange  29   a  and screwed into the first housing portion  23   b . In this way, with the first cover  29  fastened to the first case  23 , a closed space is formed by the first housing portion  23   b  and the first cover  29  for housing the MG 1  and the like. 
   Here, in order to form a through hole for the first bolt  30  and ensure a predetermined strength, the first flange  29   a  must be of a certain width (i.e., have a certain thickness in the radial direction) w 1 . Also, in order to tighten and loosen the first bolt  30 , there must be a certain amount of space between the inside surface of the first flange  29   a  and the inside surface of the first main portion  23   a . For the sake of convenience in this description, this space or gap will be hereinafter be referred to as “gap g 1 ”. Regarding this, according to this exemplary embodiment, a distance D 1  between the inside surface of the end portion on the driven wheel side of the first housing portion  23   b  and the corresponding inside surface of the first main portion  23   a  is shorter than the sum of the width w 1  and the gap g 1 . However, the distance D 1  between the inside surface of the end portion on the engine side of the first housing portion  23   b  and the corresponding inside surface of the first main portion  23   a  is larger than the sum of the width w 1  and the gap g 1 . This is because while the inside diameter of the first housing portion  23   b  is substantially constant at any given location, the diameter of the first main portion  23   a  becomes smaller farther away from the engine  12 . Then, with the first cover  29  fastened to the first case  23 , a gap is formed between the inside surface of the first flange  29   a  and the inside surface of the first main portion  23   a.    
   The MG 1  is provided with a first stator  32  and a first rotor  33 . The first stator  32  is arranged near the inside surface of the first housing portion  23   b  and is fastened to the first support wall  31  by a fastening member  34  such as a bolt. Also, the first rotor  33  is rotatably supported with respect to both the center portion of the first cover  29  and the center portion of the first support wall  31  by a bearing  35 . Then, the first rotor  33  rotates by energizing a stator coil  36  of the first stator  32  in the MG 1  mounted in the first case  23 , as described above. 
   As shown in  FIGS. 5 and 6 , a second cover  37  is arranged substantially orthogonal to the axial line L and on the engine  12  side of the second housing portion  24   b  within the second case  24 . This second cover  37  is large enough to close off the open end of the second housing portion  24   b  on the engine side. On the outer edge portion of the second cover  37  is formed a second flange  37   a , which overlaps with the end portion of the second housing portion  24   b  on the engine side. Then, a second bolt  40  which is a second fastening member, of a plurality of bolts (only one bolt is shown in  FIG. 5 ) as second attaching means is inserted through the second flange  37   a  from the engine  12  side and screwed into the second housing portion  24   b . In this way, with the second cover  37  fastened to the second case  24 , a closed space is formed for housing the MG 2  and the like by the second housing portion  24   b  and the second cover  37 . 
   Here, in order to form a through hole for the second bolt  40  and ensure a predetermined strength, the second flange  37   a  must be of a certain width (i.e., have a certain thickness in the radial direction) w 2 . Also, in order to tighten and loosen the second bolt  40 , there must be a certain amount of space between the inside surface of the second flange  37   a  and the inside surface of the second main portion  24   a . For the sake of convenience in this description, this space or gap will be hereinafter be referred to as “gap g 2 ”. Regarding this, according to this exemplary embodiment, a distance D 2  between the inside surface of the end portion on the driven wheel side of the second housing portion  24   b  and the corresponding inside surface of the second main portion  24   a  is smaller than the sum of the width w 2  and the gap g 2 . However, the distance D 2  between the inside surface of the second housing portion  24   b  of the end portion on the engine side and the corresponding inside surface of the second main portion  24   a  is larger than the sum of the width w 2  and the gap g 2 . This is because while the inside diameter of the second housing portion  24   b  is substantially constant at any given location, the diameter of the second main portion  24   a  becomes increasingly smaller away from the engine  12 . Then, with the second cover  37  fastened to the second case  24 , a gap is formed between the inside surface of the second flange  37   a  and the inside surface of the second main portion  24   a.    
   The MG 2  is provided with a second stator  39  and a second rotor  41 . The second stator  39  has a slightly smaller outside diameter, and is longer, than the first stator  32  of the MG 1 . The second stator  39  is arranged near the inside surface of the second housing portion  24   b  and is fastened to the second support wall  38  by a fastening member  42  such as a bolt. Also, the second rotor  41  has a slightly smaller outside diameter, and is longer, than the first rotor  33  of the MG 1 . The second rotor  41  is rotatably supported with respect to both the center portion of the second cover  37  and the center portion of the second support wall  38  by a bearing  43 . Then, the second rotor  41  rotates by energizing a stator coil  44  of the second stator  39  in the MG 2  mounted in the second case  24 , as described above. 
   As shown in  FIG. 2 , an input shaft  45  is inserted through the center portion of first cover  29 , the first rotor  33 , and the first support wall  31  so as to be rotatable relative to each of these. This input shaft  45  is coupled via a transmission damper  46  to a crankshaft  47  which serves as the output shaft of the engine  12 . Similarly, a middle shaft  48  is inserted through the axial center portion of the second cover  37 , the second rotor  41 , and the second support wall  38  so as to be rotatable relative to each of these. Meanwhile, an output shaft  49  that has a larger diameter than the input shaft  45  and the middle shaft  48  is inserted into the third case  25 . This output shaft  49  is rotatably supported in the third case  25  by a bearing  51  and the like. The output shaft  49  is linked to the driven wheels  13  via the propeller shaft  15 , the differential  16 , and the axle shafts  17 , and the like. The middle shaft  48  is coupled to the output shaft  49  directly, to be described later. 
   The power splitting mechanism portion  27  is a mechanism for appropriately splitting the power from the engine  12  into vehicle driving force for directly driving the driven wheels  13  and generator driving force for operating the MG 1  to generate electricity. The power splitting mechanism portion  27  is disposed in the core case  22 , in a space between the MG 1  and the MG 2 . As shown in  FIG. 5 , the power splitting mechanism portion  27  includes a planetary gear set in which a sun gear  52 , a ring gear  53 , and a planetary carrier  54  having the same axial center are rotatably interlocked together. The sun gear  52  is interlocked, so as to be able to integrally rotate, with the first rotor  33  of the MG 1  on the input shaft  45 . The ring gear  53  has a smaller diameter than the outside diameter of the first stator  32  of the MG 1  and second stator  39  of the MG 2 , and is mounted to the end portion on the engine  12  side of the middle shaft  48 . The planetary carrier  54  is attached so as to be able to integrally rotate with the input shaft  45 . A pinion gear  55  is rotatably supported by the planetary carrier  54 . The pinion gear  55  is positioned between the sun gear  52  and the ring gear  53  and is rotatably meshed with both of the sun gear  52  and the ring gear  53 . 
   Then, with the power splitting mechanism portion  27  constructed in this way, power generated by the engine  12  and transmitted to the input shaft  45  is then transmitted to the first rotor  33  of the MG 1  via the planetary carrier  54 , the pinion gear  55 , and the sun gear  52 . Further, the power transmitted to the input shaft  45  is then transmitted to the ring gear  53  (i.e., the middle shaft  48 ) via the planetary carrier  54  and the pinion gear  55 . 
   In the power splitting mechanism portion  27  described above, the outside diameter of the ring gear  53  is smaller than the outside diameter of the MG 1  and the MG 2 . Therefore, a space S 1  and a space S 2  of a predetermined size are created between the MG 1  and the MG 2  in the core case  22 , toward the outside in the radial direction of the ring gear  53  of the power splitting mechanism portion  27 . 
   As shown in  FIG. 6 , the speed reducing mechanism portion  28  includes a planetary gear set in which a sun gear  56 , a ring gear  57 , and a planetary carrier  58  having the same axial center are rotatably interlocked together, which is similar to the power splitting mechanism portion  27 . The entire structure is then arranged within the third case  25 . The sun gear  56  is interlocked so as to be able to integrally rotate with the second rotor  41  of the MG 2 . The ring gear  57  is interlocked so as to be able to integrally rotate with the middle shaft  48  and the output shaft  49 . The planetary carrier  58  is fixed to the second support wall  38  of the second case  24 . On the planetary carrier  58 , a pinion gear  59  is rotatably supported. This pinion gear  59  is positioned between, and is meshed so as to be able to rotate (freely) with, the sun gear  56  and the ring gear  57 . Then, with the speed reducing mechanism portion  28  constructed in this way, rotation of the second rotor  41  of the MG 2  is transmitted to the output shaft  49  via the sun gear  56 , the pinion gear  59 , and the ring gear  57 . Speed reduction is accomplished by this transmission process. The rotation with increased torque due to this speed reduction is applied to the output shaft  49  to assist the driving force of the engine  12 . 
   As shown in  FIG. 2 , the MG 1  and the MG 2  are both connected to a high voltage battery  62  via an inverter  61 . The inverter  61  and the high voltage battery  62  are disposed farther to the rear in the forward-backward direction of the vehicle than the drive apparatus  14 . The inverter  61  is an apparatus that controls the current while converting the high voltage direct current from the high voltage battery  62  to alternating current for the MG 1  and the MG 2 . 
   A first cable  63  is used to electrically connect the MG 1  to the inverter  61 . Further, a second cable  64  is used to electrically connect the MG 2  to the inverter  61 . For the first cable  63  and the second cable  64 , a cable capable of withstanding high voltage is used. Further, the space S 1  in the core case  22  is used to connect the first cable  63  with the MG 1  and the second cable  64  with the MG 2 . 
   More specifically, as shown in  FIG. 5 , a first connecting portion  65  is provided on the first support wall  31 . Here, this first connecting portion  65  is formed with a protruding portion that protrudes from an upper portion of the first support wall  31  toward the MG 2  side. Then, the stator coil  36  of the MG 1  and a first connecting terminal  68  of the first cable  63  are electrically connected at the first connecting portion  65 . Similarly, a second connecting portion  66  is provided on the second cover  37 . Here, this second connecting portion  66  is formed with a protruding portion that protrudes from an upper portion of the second cover  37  toward the MG 1  side. Then, the stator coil  44  of the MG 2  and a second connecting terminal  71  of the second cable  64  are electrically connected at the second connecting portion  66 . 
   As shown in  FIGS. 3 and 5 , a first outlet  67  is mounted to the core case  22  on the driven wheels  13  side of the MG 1 . Then, the first connecting terminal  68  is fed through the first outlet  67  and led out of the core case  22 . Also, a second outlet  69 , similar to the first outlet  67 , is mounted to the core case  22  on the driven wheels  13  side of the first outlet  67 . Then, the second connecting terminal  71  is fed through the second outlet  69  and led out of the core case  22 . The first outlet  67  and the second outlet  69  are formed curved away from the engine  12  and parallel to each other. 
   Further, as shown in  FIG. 2 , an oil pump  72  is provided to supply oil to sliding parts, e.g., between the input shaft  45  and the first rotor  33 , and between the middle shaft  48  and the second rotor  41 , and the like, in the drive case  21 . From among the spaces between the MG 1  and the MG 2  in the core case  22 , this oil pump  72  is provided in the space S 2  below the power splitting mechanism portion  27 , and is attached to the lower portion of the second cover  37 . Also, an oil sump  73  is provided on the lower portion of the second case  24 , and an oil strainer  74  that filters oil drawn in from the oil pump  72  is disposed within this oil sump  73 . 
   The drive apparatus  14  of the construction described above operates as described below, for example, according to the running conditions of the hybrid vehicle  11 . 
   &lt;During Take Off and Low Speed Running&gt; 
   In a region where the rotation of the driven wheels  13  is slow and there is a high load on the engine, such that the engine efficiently is low, such as during take off and when running at low speeds, the engine  12  stops operating and power is supplied to the MG 2  from the high voltage battery  62 . The second rotor  41  of the MG 2  rotates and that rotation is transmitted to the output shaft  49  via the sun gear  56 , the pinion gear  59 , and the ring gear  57  of the speed reducing mechanism portion  28 . The rotation of the output shaft  49  is then transmitted to the driven wheels  13  through the propeller shaft  15  and the like. In this way, the driven wheels  13  are driven by only the power from the MG 2 . At this time, the first rotor  33  in the MG 1  is idling. 
   &lt;During Normal Running&gt; 
   During normal running, the engine  12  is operated and power therefrom is transmitted to the driven wheels  13  after being split into two paths by the power splitting mechanism portion  27 . One of the paths transmits the power input to the input shaft  45  to the pinion gear  55  and the ring gear  53 . The power transmitted along this path is transmitted to the output shaft  49  via the middle shaft  48 . The other path transmits power to the generator to drive it so as to generate electricity. More specifically, this path transmits the power input to the input shaft  45  to the first rotor  33  of the MG 1  via the pinion gear  55  and the sun gear  52 . The first rotor  33  is rotated and power is generated by the MG 1  by this power transmission. The generated electric power is supplied to the MG 2 , which is then used as an auxiliary power source to the engine  12 . That is, the second rotor  41  of the MG 2  is rotated and that rotation is then transmitted to the output shaft  49  after being decelerated by the speed reducing mechanism portion  28 . Then, the driven wheels  13  are driven by the power transmitted through both of these paths and ultimately output from the output shaft  49 . 
   &lt;During High Load&gt; 
   Operation when running under a high load is the same as during normal running except that electric power is also supplied to the MG 2  by the high voltage battery  62 . As a result, the assist power provided by the MG 2  is further increased. 
   &lt;During Deceleration and Braking&gt; 
   When decelerating and braking, the MG 2  is driven by rotation of the driven wheels  13 . In this case, the MG 2  functions as a generator, regenerating electricity. Kinetic energy from decelerating the vehicle is converted into electrical energy and recovered (i.e., stored) in the high voltage battery  62 . 
   The following effects are obtained from the exemplary embodiment described in detail above. 
   (1) In the drive apparatus  14 , the MG 1 , the power splitting mechanism portion  27 , the MG 2 , and the speed reducing mechanism portion  28  are arranged in-line in that order from the side near the engine  12  to the side away from the engine  12 . Furthermore, the outside diameter of the MG 2  is made smaller than the outside diameter of the MG 1 , the outside diameter of the power splitting mechanism portion  27  is made smaller than the outside diameter of the MG 1  and the MG 2 , and the outside diameter of the speed reducing mechanism portion  28  is made smaller than the outside diameter of the MG 2 . As a result, the outside diameter of the drive apparatus  14  becomes increasingly smaller away from the engine  12 . Also, the drive apparatus  14  has a conical shape and is compact. In this way, according to this exemplary embodiment, the speed reducing mechanism portion  28  is able to be incorporated into the drive apparatus  14  while the apparatus on the whole is able to be made compact. 
   Furthermore, the mountability in the hybrid vehicle  11  of this drive apparatus  14  that has been made compact in this way is excellent. In particular, the foregoing shape is substantially the same as the shape of a typical automatic transmission with a fluid type torque converter and a gear change mechanism, which is mounted in a conventional vehicle having an FR type drive system. Therefore, by designing the drive apparatus  14  so it that is substantially the same size as the automatic transmission, the drive apparatus  14  is able to be housed in the floor tunnel  19  that already exists in vehicles for housing an automatic transmission. Therefore, it is possible to arrange the drive apparatus  14 , instead of the automatic transmission, in this floor tunnel  19 . Phrased differently, the automatic transmission, as well as the drive apparatus  14 , are able to be housed in an identical floor  18  that includes the floor tunnel  19 , so the same floor  18  can be used. Therefore, it is not necessary to newly design a floor tunnel to house the drive apparatus  14  in addition to the existing floor tunnel that houses the automatic transmission. 
   (2) When expanding the use of the drive apparatus  14  to a wide variety of hybrid vehicles  11 , if the specifications, such as those of the gear ratio of the speed reducing mechanism portion  28 , can be conformed to the vehicle, the MG 1 , the MG 2 , and the power splitting mechanism portion  27  and the like can be used as they are as common parts. Here, the third case  25  in which the speed reducing mechanism portion  28  is mounted is independent from the core case  22  in which the MG 1 , the MG 2 , and the power splitting mechanism portion  27  are mounted. These cases  22  and  25  can be joined to, and separated from, one another. As a result, by preparing a unit part in which the speed reducing mechanism portion  28  is mounted in the third case  25  for each type of hybrid vehicle  11 , there only needs to be one type of unit (core unit) in which the MG 1 , the MG 2 , and the power splitting mechanism portion  27  are mounted in the core case  22 , regardless of the type of the hybrid vehicle  11 . Then, when assembling a plurality of kinds of the drive apparatuses  14  in an assembly plant or the like, the unit part in which the particular speed reducing mechanism portion  28  that matches the type of drive apparatus  14  is simply selected and attached to the common core unit. As a result, the work of changing to a different speed reducing mechanism portion  28  with a different gear ratio becomes easier. 
   (3) Because the power splitting mechanism portion  27  includes a planetary gear set, and the ring gear  53 , which determines the overall size of that gear set, has a smaller outside diameter than the MG 1  and the MG 2 , the space S 1  and the space S 2  are created toward the outside in the radial direction of the ring gear  53  between the MG 1  and the MG 2 . Of these spaces, the space S 1  is used as a space in which to house the first connecting portion  65  for electrically connecting the first cable  63  to the stator coil  36  of the MG 1 . In addition, the space S 1  is also used as a space to house the second connecting portion  66  for electrically connecting the second cable  64  to the stator coil  44  of the MG 2 . By having both the first connecting portion  65  and the second connecting portion  66  in the space S 1  between the MG 1  and the MG 2  in this way, space can be used efficiently. Further, the space S 2  is used to house the oil pump  72 , so space is used efficiently as well. Therefore, by using these spaces S 1  and S 2 , the connecting portions  65  and  66  and the oil pump  72  can be housed without losing the compactness of the drive apparatus  14 . 
   (4) The first connecting terminal  68  which is connected to the stator coil  36  of the MG 1  is led out of the drive case  21  through the first outlet  67 . The second connecting terminal  71  which is connected to the MG 2  is also led out of the drive case  21  through the second outlet  69 . Here, the first outlet  67  and the second outlet  69  are both provided in the drive case  21  which becomes increasingly narrow away from the engine  12 . Also, the second outlet  69  is positioned on the side of the first outlet  67  opposite the engine  12 , i.e., in a location having a smaller outside diameter than the first outlet  67  in the drive case  21 . In addition, both the first outlet  67  and the second outlet  69  are curved away from the engine  12  and parallel to each other. As a result, in this exemplary embodiment in which the inverter  61 , which is the connection mate of both of the cables  63  and  64 , is arranged behind the drive apparatus  14  in the forward-backward direction of the vehicle, both the cables  63  and  64  can be led out of the drive case  21  together without interfering with one another and laid toward the inverter  61 . 
   (5) It is also conceivable to provide a transmitting mechanism on the outside of the MG 2  for transmitting rotation of the ring gear  53  of the power splitting mechanism portion  27  to the output shaft  49 . In this case, for example, a shaft other than the input shaft  45  and the output shaft  49  is provided parallel to these shafts, and a rotation transmitting part such as a gear or the like is provided on each shaft. The shaft in this case corresponds to a counter shaft used in a manual transmission. As a result, rotation from the input shaft  45  is able to be transmitted to the output shaft  49  via the shaft (i.e., counter shaft), the gears or the like. On the other hand, because gears are used, there is a drawback of noise and vibration being generated when the gears mesh. 
   In contrast, according to this exemplary embodiment, the middle shaft  48  for transmitting rotation of the ring gear  53  to the output shaft  49  is integrally provided with the ring gear  53 . Then this middle shaft  48  is inserted through the second rotor  41  of the MG 2  and coupled to the ring gear  57  of the output shaft  49 . This obviates the need for the aforementioned counter shaft. Because noise and vibration resulting from the meshing of gears is not generated, the noise and vibration characteristics are improved. 
   (6) The torque after speed reduction by the speed reducing mechanism portion  28  is larger than before speed reduction. Therefore, the parts that transmit the increased torque must be very strong. According to this exemplary embodiment, the output shaft  49  is larger in diameter than the input shaft  45  and the middle shaft  48  in order to meet this requirement. 
   Here, if the speed reducing mechanism portion  28  was arranged on the engine  12  side of the MG 2 , the output shaft  49 , which is large in diameter, would be inserted through the MG 2 , thus requiring that the diameter of the MG 2  be larger, which would increase the overall size of the drive apparatus  14 . In contrast, according to this exemplary embodiment, the speed reducing mechanism portion  28  is arranged on the driven wheels  13  side of the MG 2 , as described above. As a result, the shaft (i.e., the middle shaft  48 ) that is inserted through the MG 2  does not have to be of a large diameter, so an increase in size of the MG 2  and the drive apparatus  14  is able to be avoided. 
   (7) Because the outside diameter of the MG 2  is smaller than the outside diameter of the MG 1 , a space is created beneath the MG 2 . The oil sump  73  is incorporated into this space. As a result, an increase in size of the drive apparatus  14  due to the incorporation of the oil sump  73  is able to be kept to a minimum. In other words, the oil sump  73  is able to be provided without sacrificing the mountability of the drive apparatus  14 . 
   (8) The first support wall  31  and the first cover  29  of the first case  23  rotatably support the first rotor  33 , as well as form a closed space for housing the MG 1  and the like. Also, the second support wall  38  and the second cover  37  of the second case  24  rotatably support the second rotor  41 , as well as form a closed space for housing the MG 2  and the like. It is therefore possible to suppress foreign matter from getting into the first housing portion  23   b  and the second housing portion  24   b  and causing poor operation with respect to rotation and the like of the first rotor  33  and the second rotor  41 . As a result, the MG 1  and the MG 2  are able to maintain their functions as a motor or generator well, and are thus able to be highly reliable. 
   (9) The first cover  29  is arranged on the engine  12  side (i.e., on the end portion on the engine side of the first housing portion  23   b ) of the MG 1  inside the first main portion  23   a . The diameter of the first main portion  23   a  in this location is comparatively larger than the general outside diameter around the first main portion  23   a . In particular, the diameter of the first main portion  23   a  in this location is definitely larger than the diameter of the first main portion  23   a  at a location corresponding to the end portion on the driven wheel side of the first housing portion  23   b . The size relationship of the distance D 1  between the inside surface of the first housing portion  23   b  and the inside surface of the first main portion  23   a  is the same as described above. Therefore, because the distance D 1  is larger than the sum of the width w 1  of the first flange  29   a  and the gap g 1  between first flange  29   a  and the first main portion  23   a , even if the first main portion  23   a  does not extend outward in the radial direction, the first cover  29  can still be arranged within the first main portion  23   a  and fastened to the first housing portion  23   b  by the first bolt  30 . 
   In this way, it is possible to suppress the outside diameter of the first case  23  from becoming larger with the first cover  29  attached, and therefore maintain the original outer shape of the drive case  21 , in which it becomes increasingly narrow away from the engine  12 . This outer shape is similar to the outer shape of an automatic transmission provided with a torque converter and a gear change mechanism, which is housed in a vehicle having a FR type drive system. As a result, it is possible to arrange the drive apparatus  14 , instead of the automatic transmission, in the floor tunnel  19 , and improve mountability of the drive apparatus  14  in the vehicle. 
   (10) The diameter of the first main portion  23   a  increases closer to the engine  12 . Therefore, even in the first main portion  23   a , a sufficiently wide space is created around the first cover  29 , and particularly around the first flange  29   a , arranged near the engine  12 . This space facilitates the operation of loosening and tightening the first bolt  30  when detaching and attaching the first cover  29 . 
   (11) The second cover  37  is arranged on the engine  12  side (i.e., on the end portion on the engine side of the second housing portion  24   b ) of the MG 2  within the second main portion  24   a . The diameter of the second main portion  24   a  in this location is comparatively larger than the general outside diameter around the second main portion  24   a . In particular, the diameter of the second main portion  24   a  in this location is definitely larger than the diameter of the second main portion  24   a  at a location corresponding to the end portion on the driven wheel side of the second housing portion  24   b . The size relationship of the distance D 2  between the inside surface of the second housing portion  24   b  and the inside surface of the second main portion  24   a  is the same as described above. Therefore, because the distance D 2  is larger than the sum of the width w 2  of the second flange  37   a  and the gap g 2  between second flange  37   a  and the second main portion  24   a , even if the second main portion  24   a  does not extend outward in the radial direction, the second cover  37  can be arranged within the second main portion  24   a  and fastened to the second housing portion  24   b  by the second bolt  40 . In this way, it is possible to suppress the outside diameter of the second case  24  from becoming larger with the second cover  37  attached, and therefore maintain the original outer shape of the drive case  21 , in which it becomes increasingly narrow away from the engine  12 . Accordingly, together with the effect of (2) above, mountability of the drive apparatus  14  in the vehicle is further improved. 
   (12) The diameter of the second main portion  24   a  increases closer to the engine  12 . Therefore, even in the second main portion  24   a , a sufficiently wide space is created around the second cover  37 , and particularly around the second flange  37   a , arranged near the engine  12 . This space facilitates the operation of loosening and tightening the second bolt  40  when detaching and attaching the second cover  37 . 
   This invention can be implemented with other exemplary embodiments described as follows.
         The MG 1  and the MG 2  may each also be able to perform both a regenerative operation and a powering operation, or either one of the two. Accordingly, a VR type (variable reluctance type) synchronous motor, a vernier motor, a direct current motor, an induction motor, a superconducting motor, a step motor, or the like may also be used instead of an alternating current synchronous motor of the type used in the foregoing exemplary embodiment.   The drive apparatus according to the invention is not limited to a FR type driving system, but may also be applied to a hybrid vehicle having another type of driving system such as a front engine front drive (FF) driving system.   In the foregoing exemplary embodiment, the planetary carrier  58  of the speed reducing mechanism portion  28  is fixed. Alternatively, however, the ring gear  57  may be fixed to the third case  25  or the like.   The second flange  37   a  may be formed over the entire circumference of the outer edge portion of the second cover  37 , or only on a portion thereof.       

   The technical ideas that can be understood from these exemplary embodiments, as well as their effects, shall now be described. 
   (A) In the drive apparatus for a hybrid vehicle according to any one of claims  1  through  4 , the power splitting mechanism portion includes the planetary gear set which has a ring gear with an outer diameter smaller than the motor generator and which is arranged between the motor generators. The oil pump to supply oil to sliding parts is provided in a space that is outward in the radial direction from the ring gear between the motor generators. 
   According to the foregoing construction, the oil pump is able to be incorporated without losing the compactness of the drive apparatus by efficiently using the space between the two motor generators. 
   (B) In the drive apparatus for a hybrid vehicle according to any one of claims  1  through  4  or aforementioned (A), the oil sump is further provided beneath the second motor generator. 
   According to this construction, an increase in size of the drive apparatus due to the arrangement of the oil sump is able to be kept to a minimum. 
   (C) In the drive apparatus for a hybrid vehicle according to claim  5  or claim  6 , the first fastening member includes a first bolt that is inserted through the first flange and screwed into the first housing portion. 
   (D) In the drive apparatus for a hybrid vehicle according to claim  7  or claim  8 , the first fastening member includes a first bolt that is inserted through the first flange and screwed into the first housing means. 
   According to (C) and (D), the first cover can be reliably fastened to the end portion on the engine side of the first housing portion by the first bolt. 
   (E) In the drive apparatus for a hybrid vehicle according to claim  6 , the second fastening member includes the second bolt that is inserted through the second flange and screwed into the second housing portion. 
   (F) In the drive apparatus for a hybrid vehicle according to claim  6 , the second fastening member includes the second bolt that is inserted through the second flange and screwed into the second housing means. 
   According to (E) and (F), the second cover can be reliably fastened to the end portion on the engine side of the second housing portion by the second bolt. 
   (G) In the drive apparatus for a hybrid vehicle according to any one of claims  5  or  8  or aforementioned (C) to (F), the first housing portion has a cylindrical shape and is provided with a support wall on the end portion on the side opposite the engine. That support wall is on the side of the motor generator opposite the engine and closes off that end portion. 
   According to this construction, the support wall and the first cover close off both end portions of the first housing portion so as to suppress foreign matter from getting into the first housing portion and causing poor operation of the first motor generator. 
   (H) In the drive apparatus for a hybrid vehicle according to claim  6 ,  8 , the aforementioned (D) or (F), the second housing portion has a cylindrical shape and is provided with second support wall on the end portion on the side opposite the engine. That second support wall is on the side of the second motor generator opposite the engine and closes off that end portion. 
   According to this construction, the second support wall and the second cover close off both end portions of the second housing portion so as to suppress foreign matter from getting into the second housing portion and causing poor operation of the second motor generator.