JP6881405B2 - Lower body structure - Google Patents

Description

The present invention relates to a lower body structure of a vehicle, and more particularly to a lower body structure having a floor tunnel.

In vehicles such as FR (front engine / rear drive) type and 4WD (four-wheel drive) type automobiles, a propeller shaft extending in the front-rear direction of the vehicle may be provided in the power transmission path from the drive source to the drive wheels. .. The propeller shaft is usually arranged in a floor tunnel provided at the center of the vehicle body floor in the vehicle width direction. Further, for example, in a vehicle equipped with a so-called vertical power train, at least a part of a transmission may be arranged in a floor tunnel.

Further, in this type of vehicle, an undercover may be provided on the lower surface of the vehicle body floor in order to improve the aerodynamic performance of the vehicle. The undercover can rectify the airflow passing through the lower surface of the vehicle body floor when the vehicle is running.

For example, Patent Document 1 discloses an undercover that covers the lower surface of a floor excluding a floor tunnel.

JP-A-2018-12425

For example, a vehicle that drives a rear wheel is a vehicle that has a member that generates heat at the rear of the vehicle. In such a vehicle, for example, it is conceivable to cool the heating element arranged behind the fuel tank by using the running wind.

In a vehicle having an undercover attached to the lower surface of the vehicle body floor, in order to realize cooling by running wind for the heating element arranged behind the fuel tank, a new consideration should be given to the structure of the undercover and its surrounding configuration. Is required.

Therefore, an object of the present invention is to provide a lower body structure capable of improving the cooling effect on a heating element arranged behind the fuel tank.

In order to solve the above problems, the lower body structure according to the present invention is characterized by being configured as follows.

The invention according to claim 1 is a lower vehicle body structure including a vehicle body floor having a floor tunnel.
The vehicle body floor has step-up portions extending from below toward both sides of the floor tunnel.
The lower body structure
An undercover that covers the raised part from below,
The fuel tank located behind the undercover and
With a heating element located behind the fuel tank,
The fuel tank has a recess on the lower surface having a width smaller than the width between the raised portions in the vehicle width direction.
The recess opens downward and
The heating element is located behind the recess in the fuel tank .
In a cross-sectional view orthogonal to the vehicle front-rear direction, the space formed by the undercover and the vehicle body floor is communicated with the recess in the vehicle front-rear direction.

The invention according to claim 2 is the invention according to claim 1.
The length from the lower surface of the fuel tank to the upper end of the recess is shorter than the length from the undercover to the upper end of the floor tunnel.

The invention according to claim 3 is the invention according to claim 1 or 2.
Provided with an insulator fixed to the bottom surface of the fuel tank and covering the recess of the fuel tank from below.
The propeller shaft is located between the insulator and the fuel tank,
The exhaust pipe is located below the insulator.

The invention according to claim 4 is the invention according to claim 3.
The insulator projects upward in the recess of the fuel tank.

The invention according to claim 5
In a lower body structure with a body floor with a floor tunnel
The vehicle body floor has step-up portions extending from below toward both sides of the floor tunnel.
The lower body structure
An undercover that covers the raised part from below,
The fuel tank located behind the undercover and
With a heating element located behind the fuel tank,
The fuel tank has a recess on the lower surface having a width smaller than the width between the raised portions in the vehicle width direction.
The recess opens downward and
The heating element is located behind the recess in the fuel tank.
The front portion of the undercover is fixed so as to overlap with the subframe for the front suspension.

According to the first aspect of the present invention, since the undercover covers only the raised portion, it does not become large, and the aerodynamic performance of the vehicle can be improved in cooperation with the lower surfaces of the vehicle body floor on both sides thereof. In addition, the airflow that has passed through the space between the undercover, the step-up portion, and the floor tunnel has a higher flow velocity in the narrower fuel tank recess behind it and hits the heating element, thus improving the cooling effect of the heating element. Can be improved.

According to the second aspect of the present invention, the length of the airflow flow path in the fuel tank is shortened in the height direction in addition to the width direction, so that the volume of the airflow flow path can be made smaller. As a result, the flow velocity of the air flow can be increased, and the cooling effect of the heating element can be improved.

According to the third aspect of the present invention, since the insulator that covers the recess of the fuel tank from below is provided, it is possible to introduce an air flow that flows between the undercover and the vehicle body floor into the space between the fuel tank and the insulator. it can. As a result, the propeller shaft located between the fuel tank and the insulator can be cooled.

According to the invention of claim 4, since the insulator projects from the lower side to the upper side of the concave portion of the fuel tank, the volume between the concave portion of the fuel tank and the insulator becomes small, and the flow velocity of the air flow can be further increased. ..

According to the fifth aspect of the invention, more air in the engine room above the subframe for the front suspension can be taken in more rearward along the upper surface of the undercover.

It is a perspective view which shows the vehicle which concerns on one Embodiment of this invention. It is a perspective view which shows the lower body structure which concerns on one Embodiment of this invention. FIG. 3 is a cross-sectional view taken along the line III-III of FIG. 2 when the lower vehicle body structure is viewed from the rear side of the vehicle. FIG. 2 is a sectional view taken along line IV-IV of FIG. 2 when the lower vehicle body structure is viewed from the rear side of the vehicle. It is a bottom view which shows the lower body structure which a cover was fixed. It is a schematic plan view which looked at the 1st under panel from the lower side of a vehicle body. It is a schematic plan view which looked at the 2nd under panel from the lower side of the vehicle body. It is a schematic plan view which looked at the insulator from the lower side of a car body. It is sectional drawing around the joint part of the 1st under panel and the subframe for a front suspension. FIG. 5 is a cross-sectional view taken along line XX of FIG. 5 when the lower vehicle body structure is viewed from the front side of the vehicle. FIG. 5 is a cross-sectional view taken along the line XI-XI of FIG. 5 when the lower vehicle body structure is viewed from the front side of the vehicle. FIG. 5 is a cross-sectional view taken along line XII-XII of FIG. 5 when the lower vehicle body structure is viewed from the front side of the vehicle. FIG. 5 is a cross-sectional view taken along line XIII-XIII of FIG. 5 when the lower vehicle body structure is viewed from the front side of the vehicle. FIG. 5 is a cross-sectional view taken along the line XIV-XIV of FIG. 5 when the lower vehicle body structure is viewed from the side of the vehicle. FIG. 5 is a cross-sectional view taken along the line XV-XV of FIG. 5 when the lower vehicle body structure is viewed from the side of the vehicle.

Hereinafter, the lower body structure according to the embodiment of the present invention will be described with reference to the accompanying drawings. In the following explanation, terms indicating directions such as "front", "rear", "right", "left", "up", and "down" are used for vehicles unless otherwise specified. It shall refer to each direction of the vehicle body when the traveling direction during forward traveling is "forward". Further, in the attached drawings, the symbol "X" is attached in the vehicle width direction, the symbol "Y" is attached in the vehicle front-rear direction, and the symbol "Z" is attached in the vehicle vertical direction.

[overall structure]
As shown in the perspective view of FIG. 1, the perspective view of FIG. 2, and the low-view view of FIG. 3, the automobile 1 provided with the lower body structure according to the present embodiment is a vehicle body floor constituting the floor surface of the vehicle interior space. 2. It includes a pair of side sills 4 extending in the vehicle front-rear direction Y along both sides of the vehicle body floor 2 in the vehicle width direction X, and a dash panel 10 arranged in front of the vehicle body floor 2. Each side sill 4 has a cross-section hat-like shape that is open to the outside in the vehicle width direction X.

The automobile 1 further includes a pair of hinge pillars 5 that stand up from the front ends of the left and right side sills 4 and extend in the vertical direction Z of the vehicle, and the dash panel 10 is erected between the pair of hinge pillars 5. The dash panel 10 partitions the vehicle interior space and the engine room ER in the vehicle front-rear direction Y.

The vehicle body floor 2 includes a bottom surface portion 3 and a floor tunnel 50 formed so as to bulge upward from the bottom surface portion 3. The floor tunnel 50 is provided so as to extend in the vehicle front-rear direction Y at the center of the vehicle body floor 2 in the vehicle width direction X. The cross-sectional shape of the floor tunnel 50 as viewed from the vehicle front-rear direction Y is a U-shape open downward.

An opening 50a for passing a shift lever (not shown) is provided on the upper surface of the floor tunnel 50. Reinforcing members 8 extending in the vehicle front-rear direction Y are joined to both sides of the upper surface of the floor tunnel 50 in the vehicle width direction X by welding, for example, thereby increasing the rigidity of the floor tunnel 50.

A pair of left and right floor frames 12 extending in the vehicle front-rear direction Y are joined to the lower surface of the bottom surface portion 3 (step-up portion 48) of the vehicle body floor 2, for example, by welding. Each floor frame 12 is arranged between the floor tunnel 50 and the side sill 4 in the vehicle width direction X. The floor frame 12 is connected to the front end portion of the side sill 4 via a torque box (not shown) extending in the vehicle width direction X.

Further, a pair of left and right first cross members 14 and a pair of left and right second cross members 16 are joined to the upper surface of the vehicle body floor 2 as floor cross members extending in the vehicle width direction X. Each first cross member 14 and each second cross member 16 are erected between the floor tunnel 50 and the side sill 4.

The left and right first cross members 14 are arranged at substantially the same positions as each other in the vehicle front-rear direction Y. The left and right second cross members 16 are arranged at substantially the same positions as each other in the vehicle front-rear direction Y, behind the first cross member 14.

The first cross member 14 includes a cross member main body 64 extending in the vehicle width direction, and first and second seat brackets 65 and 66 for supporting a pair of seat rails 99 and 100 in the seat slide mechanism. The cross member main body 64 and the first and second seat brackets 65 and 66 are, for example, stamped parts made of steel.

The cross member main body 64 is a member having a cross section hat-shaped open downward, and forms a closed cross section continuous with the vehicle body floor 2 in the vehicle width direction X. The vehicle width direction X inner end of the cross member main body 64 is arranged outside the vehicle width direction X with respect to the floor tunnel 50. A first seat bracket 65 is joined to the inner end of the cross member main body 64 in the vehicle width direction X, and the cross member main body 64 and the floor tunnel 50 are connected via the first seat bracket 65.

The vehicle width direction X outer end of the cross member main body 64 is joined to the side sill 4. The second seat bracket 66 is joined to the side sill 4 with the outer end portion of the cross member main body 64 in the vehicle width direction X in the vehicle width direction.

Further, a pair of left and right diagonal members 18 are joined to the upper surface of the vehicle body floor 2 by, for example, welding. The oblique member 18 is arranged in front of the first cross member 14 so as to extend in a direction inclined rearward toward the inside of the vehicle width direction X. The oblique member 18 is provided so as to connect the floor frame 12 and the side sill 4. The diagonal member 18 is a member having a cross section hat-shaped open downward, and forms a continuous closed cross section with the vehicle body floor 2 in the length direction of the diagonal member 18.

The automobile 1 in the present embodiment is, for example, an FR type automobile provided with a vertical power train. The power train of the automobile 1 includes an engine (not shown) as a drive source mounted in the engine room ER in front of the dash panel 10 and a transmission 24 (see FIG. 10) connected to the rear of the engine. I have.

The transmission 24 is, for example, a vertical automatic transmission and has an output shaft (not shown) extending in the vehicle front-rear direction Y. However, the transmission 24 may be a manual transmission. The rear end of the output shaft of the transmission 24 is connected to a propeller shaft 30 extending in the vehicle front-rear direction Y via a universal joint (not shown) (see FIG. 5). The rear end of the propeller shaft 30 is connected to the differential gear 32. As a result, the power of the engine can be transmitted to the rear wheel WR via the transmission 24, the propeller shaft 30, the differential gear 32, and the like. The differential gear 32 is a heating element that generates heat due to the frictional force of transmission of engine power.

The propeller shaft 30 is arranged in the floor tunnel 50. The propeller shaft 30 is supported on the lower surface of the floor tunnel 50. At least a part of the transmission 24 on the rear end side is also arranged in the floor tunnel 50.

The mount member 70 is fixed to the vehicle body floor 2 at the Y position in the vehicle front-rear direction that overlaps the upper surface portion 64a of the first cross member 14. As a result, the rear portion of the transmission 24 is supported by the vehicle body via the mount member 70. The front portion of the transmission 24 is supported by a vehicle body, for example, a subframe 34 for front suspension, via an engine and an engine mount (not shown).

[Body floor]
The configuration of the vehicle body floor 2 and its peripheral portion at the Y position in the vehicle front-rear direction in which the mount member 70 and the first cross member 14 are arranged will be described with reference to the cross-sectional view of FIG.

As shown in FIG. 3, the vehicle body floor 2 is composed of a tunnel panel 40 constituting the floor tunnel 50 and a pair of left and right bottom panels 42 forming the bottom surface portion 3. The tunnel panel 40 is arranged at the center of the vehicle width direction X between the left and right side sills 4. Each bottom panel 42 is provided so as to connect the tunnel panel 40 and the side sill 4.

The tunnel panel 40 and the bottom panel 42 are, for example, stamped parts made of steel. The tunnel panel 40 preferably has higher rigidity and strength than the bottom panel 42, whereby the rigidity and strength of the floor tunnel 50 can be improved.

The vehicle body floor 2 includes a pair of step-up portions 48 that connect the bottom plate portion 54, which is the bottom portion of the bottom surface portion 3, to the lower edge portion of the floor tunnel 50. The step-up portion 48 extends from below toward both sides of the floor tunnel 50, and floor tunnels on both sides of the floor tunnel 50 in the vehicle width direction at least in the arranged portions of the first and second cross members 14 and 16 of the vehicle body floor 2. Connected with 50.

The step-up portion 48 is composed of an upper-stage portion 51, a middle-stage portion 52, and a lower-stage portion 53. In the present embodiment, the rigidity can be increased by forming the step-up portion 48 in a three-stage configuration. The step-up portion 48 may have a structure of less than three steps or a structure of more than three steps. Further, the step-up portion 48 may not be formed in a stepped shape, or may have an inclined structure, for example.

Each upper portion 51 is provided so as to extend in the vehicle front-rear direction Y along the lower edge portion of the floor tunnel 50 from the front portion of the first cross member 14 to the rear portion of the second cross member 16. (See FIG. 2).

In this way, by providing the upper stage portion 51 between the bottom surface portion 3 on the vehicle body floor 2 and the lower edge portion of the floor tunnel 50, the boundary portion between the lower edge portion and the bottom surface portion 3 of the floor tunnel 50 is reinforced. Rigidity can be improved without separately providing a member.

As shown in FIG. 3, the upper portion 51 has a horizontal plate portion 51a extending outward in the vehicle width direction X from the lower end portion of the floor tunnel 50 and a vehicle width direction X downward from the outer end portion of the horizontal plate portion 51a. It is provided with a first inclined portion 51b extending in an outwardly inclined direction. The first inclined portion 51b may extend vertically downward.

As described above, at the boundary between the bottom surface portion 3 and the lower edge portion of the floor tunnel 50, the rigidity is increased by providing the upper stage portion 51 integrated with the vehicle body floor 2. As a result, in the vehicle front-rear direction Y region where the upper stage portion 51 is provided, reinforcement along the lower edge portion of the floor tunnel 50 is achieved without providing a reinforcing member separate from the vehicle body floor 2.

In the present embodiment, the horizontal plate portion 51a and the first inclined portion 51b of the upper stage portion 51 are formed of a part of the tunnel panel 40. The tunnel panel 40 further includes an extension portion 51c extending outward from the lower end portion of the first inclined portion 51b in the vehicle width direction X. The extension portion 51c is joined to the bottom panel 42 by welding, for example.

However, the upper portion 51 may be composed of a part of the bottom panel 42, or may be composed of a floor constituent member different from the tunnel panel 40 and the bottom panel 42.

As shown in FIG. 4, the middle stage portion 52 has a horizontal plate portion 52a extending in the vehicle width direction X and a second portion extending downward from the outer end portion of the horizontal plate portion 52a in a direction inclined outward in the vehicle width direction X. It is provided with two inclined portions 52b. The horizontal plate portion 52a of the middle stage portion 52 is joined to the upper surface of the extension portion 51c of the tunnel panel 40. As a result, the vehicle width direction X inner end of the horizontal plate portion 52a of the middle stage portion 52 is connected to the lower end portion of the first inclined portion of the upper stage portion 51 via the extension portion 51c.

As shown in FIG. 3, the lower stage portion 53 includes a horizontal plate portion 53a extending outward in the vehicle width direction X from the lower end portion of the second inclined portion 52b of the middle stage portion 52, and a vehicle width from the outer end portion of the horizontal plate portion 53a. Direction X A third inclined portion 53b extending in an upwardly inclined direction toward the outside is provided.

The lower end of the third inclined portion 53b of the lower portion 53 is connected to the inner end portion of the bottom plate portion 54 in the vehicle width direction X. The jointed portion 55 is provided so as to extend upward from the outer end portion of the bottom plate portion 54. The jointed portion 55 is joined to the side surface of the side sill 4 on the vehicle interior side by, for example, welding.

As described above, the bottom plate portion 54 is arranged at substantially the same height as the bottom portion 4a of the side sill 4 in the vehicle vertical direction Z. Since the bottom plate portion 54 has a function of undercovering the automobile 1 and has the same height as the bottom portion 4a of the side sill 4, the ground clearance can be maintained on both side portions.

However, the cross-sectional shape of the vehicle body floor 2 on the lines III-III of FIG. 2 is not limited to the above configuration shown in FIG. 3, and can be changed as appropriate. For example, the middle stage portion 52 may be formed in a plurality of stages or may be omitted. Further, in the present embodiment, the bottom plate portion 54 is arranged at a position substantially the same height as the jointed portion 55, but may be arranged at a position higher than the joined portion 55.

Further, the floor frame 12 is connected along the step-up portion 48. Since the floor frame 12 extending in the front-rear direction is connected to the step-up portion 48, it is possible to prevent the floor frame 12 extending in the front-rear direction from protruding downward from the vehicle body floor 2. As a result, the rigidity of the vehicle body floor 2 and the minimum ground clearance can be ensured.

The first seat bracket 65 is joined to the outer side surface of the floor tunnel 50 by, for example, welding at the inner end portion in the vehicle width direction X, and is joined to the upper surface portion 64a of the cross member main body 64 at the outer end portion in the vehicle width direction X. They are joined by welding, for example. As a result, the upper surface portion 64a of the cross member main body 64 is connected to the floor tunnel 50 via the first seat bracket 65.

The vehicle width direction X inner end portion of the second seat bracket 66 is joined to the upper surface portion 64a of the cross member main body 64 by, for example, welding. The outer end portion of the second seat bracket 66 in the vehicle width direction X is joined to the upper surface portion 4b of the side sill 4 by, for example, welding.

The mount member 70 that supports the transmission 24 is, for example, a cast part made of an aluminum alloy. The mount member 70 is a connecting member that connects the step-up portions 48 on both sides of the floor tunnel 50 facing the floor tunnel 50. The mount member 70 includes a base portion 71 extending in the vehicle width direction X. The base portion 71 has a butterfly-shaped overall shape when viewed from the vehicle vertical direction Z. The base portion 71 has a curved shape so as to bulge downward from the vehicle when viewed from the vehicle front-rear direction Y.

Both ends of the base portion 71 in the vehicle width direction X are fixed portions 72 fixed to the vehicle body floor 2. Each fixed portion 72 is provided with a plurality of bolt holes that penetrate the fixed portion 72 in the vehicle vertical direction Z. The fixed portion 72 is fixed to the upper portion 51 of the vehicle body floor 2 and the cross member main body 64 and the first seat bracket 65 arranged on the upper side of the upper portion 51 by using bolts 94 inserted into the bolt holes. Will be done. Therefore, the mount member 70 connects the upper portions 51 to each other.

See FIG. The second cross member 16 includes a cross member main body 84 extending in the vehicle width direction, and first and second seat brackets 85 and 86 for supporting a pair of seat rails 99 and 100 in the seat slide mechanism. The cross member main body 84 and the first and second seat brackets 85 and 86 are, for example, stamped parts made of steel.

The cross member main body 84, the first and second seat brackets 85 and 86 of the second cross member 16 are parts corresponding to the cross member main body 64 and the first and second seat brackets 65 and 66 of the first cross member 14. Yes Since it has the same function, detailed description will be omitted.

The third cross member 90 has a flat plate-like overall shape extending in the vehicle width direction X when viewed from the vehicle vertical direction Z. Both ends of the third cross member 90 in the vehicle width direction X are fixed portions 92 fixed to the vehicle body floor 2. Each fixed portion 92 is provided with a plurality of bolt holes that penetrate the fixed portion 92 in the vehicle vertical direction Z. The fixed portion 92 is fixed to the upper stage portion 51 of the vehicle body floor 2 and the cross member main body 84 arranged so as to be overlapped on the upper side of the upper stage portion 51 by using bolts 93 inserted into the bolt holes.

[undercover]
Next, with reference to the low view of FIG. 5, the perspective views of FIGS. 6, 7, and 8, the first and second undercovers 102 and 104 attached to the vehicle body floor 2 and the first insulator 106 explain. The first and second undercovers 102 and 104 cover the lower side of the mount member 70 so as to be continuous with the bottom plate portion 54 of the vehicle body floor 2 outside the step-up portion 48 in the vehicle width direction.

The first undercover 102 has a substantially L-shaped overall shape. Through holes 102a, 102b, 102d for fixing are provided along the outer peripheral edge of the first undercover 102. Further, the first undercover 102 is formed with grooves 102e and 102f extending in the front-rear direction. The grooves 102e and 102f are open downward and extend in the front-rear direction. The grooves 102e and 102f extending in the front-rear direction rectify the airflow passing under the first undercover 102, so that the aerodynamic performance can be further improved.

The second undercover 104 has a shape in which the central portion in the vehicle width direction X bulges downward. A through hole 104a for fixing is provided on the right edge of the second undercover. Further, a through hole 104b for fixing is provided at the front side edge portion of the second undercover. Further, a through hole 104d for fixing is provided on the left edge portion of the second undercover.

The first insulator 106 is provided with through holes 106a, 106b, 106c for fixing along the outer peripheral edge of the first insulator 106. Further, the first insulator 106 has a U-shaped tunnel 106d open downward. The tunnel 106d extends in the front-rear direction. An exhaust pipe 36 is housed in the tunnel 106d.

As shown in the cross-sectional view of FIG. 9, a through hole 34a is provided at the rear end of the subframe 34. The through hole 102a of the first undercover 102 and the through hole 34a of the subframe 34 are fixed with a fixing tool such as a bolt 96, for example. Similarly, the through hole 104b of the second undercover 104 and the through hole 34a of the subframe 34 are fixed with a fixing tool such as a bolt 96.

In this way, the lower surface of the subframe 34 is placed and fixed on the upper surfaces of the first and second undercovers 102 and 104. Since the front parts of the first and second undercovers 102 and 104 are fixed so as to overlap with the subframe 34 for the front suspension, they are taken into the engine room ER through the front grill FG (see FIG. 1). More outside air can be introduced on the first and second undercovers 102, 104.

As shown in the cross-sectional view of FIG. 10, the first and second undercovers 102 and 104 are fixed to the bottom panel 42 via a U-shaped bracket 107. Bolts are inserted into the through holes 102d of the first undercover 102 and the through holes 104d of the second undercover and fixed to the lower end 107a of the bracket 107. The first insulator 106 is also fixed to the bottom panel 42 via the bracket 107. A bolt is inserted into the through hole 106b of the first insulator 106 and fixed to the lower end of the bracket 107. The upper end portion 107b of the bracket 107 is fixed to the horizontal plate portion 51a extending from the tunnel panel 40.

As shown in the cross-sectional view of FIG. 11, the first undercover 102 and the first insulator 106 are fixed to the third cross member 90 and the bottom panel 42 via a Z-shaped bracket 105. Bolts 98 are inserted into the through holes 102d of the first undercover 102 and the through holes 106c of the first insulator 106, and the first undercover 102 and the first insulator 106 are fixed to the lower end portion 105a of the bracket 105. The upper end 105b of the bracket 105 is fixed to the third cross member 90 and the upper 51 of the bottom panel 42 by, for example, a fixing tool such as a bolt.

As shown in the cross-sectional view of FIG. 12, the first undercover 102 is fixed to the mount member 70 by inserting a bolt 95 into a through hole 102 g provided in the groove 102e. Since the first undercover 102 is fixed to the mount member 70, the mounting rigidity of the first undercover 102 can be ensured without lowering the position of the first undercover 102. Thereby, the vibration of the first undercover 102 can be reduced.

Further, since the first undercover 102 and the mount member 70 are fixed in the groove 102e of the first undercover 102 through which the airflow passes, the vibration of the first undercover 102 due to the rectification of the airflow can be suppressed.

The left edge of the first undercover 102 is fixed to the floor frame 12 extending in the front-rear direction by inserting a bolt into the through hole 102d, for example. Further, the right edge portion of the second undercover is also fixed to the floor frame 12 extending in the front-rear direction by inserting a bolt into the through hole 104a, for example. Since the floor frame 12 is fixed to the lower portion 53, the first and second undercovers 102 and 104 cover between the lower portions 53. Since the mount member 70 connects the upper portions 51, the downward protrusion of the mount member 70 can be accommodated in the first and second undercovers 102 and 104.

[Fuel tank]
As shown in the cross-sectional view of FIG. 13, the fuel tank 108 is supported by the bottom portion 4a of the side sill 4 via the support member 110. The fuel tank 108 is made of resin. The fuel tank 108 is arranged behind the first and second undercovers 102 and 104. A differential gear 32 is arranged behind the fuel tank 108. A recess 108a that opens downward and extends in the front-rear direction is formed in the central portion of the fuel tank 108 in the vehicle width direction X. The recess 108a has a first recess 108aa and a second recess 108ab. The first recessed portion 108aa covers the upper part of the propeller shaft 30. The depth of the second recessed portion 108ab from the lower surface of the fuel tank 108 is shallower than that of the first recessed portion 108aa.

The width Wa of the recess 108a in the vehicle width direction is smaller than the width Wb between the step-up portions 48 (see FIG. 12). As a result, the airflow that has passed through the space between the first and second undercovers 102 and 104 and the step-up portion 48 and the floor tunnel 50 has a flow velocity in the recess 108a of the narrower fuel tank 108 behind it. Since it is raised and hits the differential gear 32, the cooling effect of the differential gear 32 can be improved.

The length Ha (FIG. 13) from the lower surface of the fuel tank 108 to the upper end of the recess 108a is shorter than the length Hb (FIG. 12) from the first and second undercovers 102 and 104 to the upper end of the floor tunnel 50. As a result, when the volume through which the wind passes between the first and second undercovers 102 and 104 and the floor tunnel 50 shifts to the volume from the lower surface of the fuel tank 108 to the upper end of the recess 108a, in addition to the width direction, Since the length is shortened in the height direction as well, the volume through which the wind passes can be made smaller, and the flow velocity of the airflow can be increased.

A second insulator 112 is arranged between the recess 108a and the exhaust pipe 36. The second insulator 112 is fixed to the bottom surface of the fuel tank 108 and covers the recess 108a of the fuel tank 108 from below. The propeller shaft 30 is located between the second insulator 112 and the fuel tank 108, and the exhaust pipe 36 is located below the second insulator 112. As a result, the airflow that has passed through the upper parts of the first and second undercovers 102 and 104 is narrowed in the vertical direction by the second insulator 112 so that the airflow flows between the second insulator 112 and the fuel tank 108. Since it is configured, the flow velocity of the air flow can be further increased.

The second insulator 112 projects upward in the recess 108a of the fuel tank 108. Since the second insulator 112 projects upward from below the recess 108a of the fuel tank 108 toward the second recess 108ab, the volume between the recess 108a of the fuel tank 108 and the second insulator 112 becomes smaller, and the volume becomes smaller and rearward. The flow velocity of the flowing airflow can be further increased.

The airflow flowing backward from the engine room ER will be described with reference to the cross-sectional views of FIGS. 14 and 15. As shown in FIG. 14, the bottom plate portion 54 of the bottom panel 42 extends at substantially the same height in the front-rear direction from the joint portion with the dash panel 10. On the other hand, the stepped bottom panel 42 extends substantially downward from the joint with the dash panel 10 toward the rear. The heights of the first undercover 102 and the first insulator 106 in the front-rear direction are substantially the same. Therefore, the flow path from the engine room ER to the fuel tank 108 extends rearward while being narrowed in volume in the vertical direction. As a result, the flow velocity of the airflow flowing between the bottom panel 42 and the first undercover 102 can be increased as it flows backward. As a result, since the airflow flows into the recess 108a of the fuel tank 108 with the flow velocity increased, the cooling effect of the fuel tank 108 and the differential gear 32 arranged behind the fuel tank can be improved.

Although the present invention has been described above with reference to the above-described embodiments, the present invention is not limited to the above-described embodiments.

For example, in the above-described embodiment, the example of the differential gear 32 as a heating element arranged behind the fuel tank 108 has been described, but the present invention is not limited to this. The present invention can also be applied when other members requiring cooling are arranged behind the fuel tank 108.

As described above, according to the present invention, in a vehicle having a member that generates heat at the rear of the vehicle, the heat generating member can be cooled more effectively. Therefore, an automobile provided with this type of heat generating member. It may be suitably used in the manufacturing industry field.

2 Body floor 30 Propeller shaft 32 Differential gear 34 Subframe 36 Exhaust pipe 48 Step-up part 50 Floor tunnel 102 1st undercover 104 2nd undercover 108 Fuel tank 108a Recess 112 2nd insulator

Claims (5)

In a lower body structure with a body floor with a floor tunnel
The vehicle body floor has step-up portions extending from below toward both sides of the floor tunnel.
The lower body structure
An undercover that covers the raised part from below,
The fuel tank located behind the undercover and
With a heating element located behind the fuel tank,
The fuel tank has a recess on the lower surface having a width smaller than the width between the raised portions in the vehicle width direction.
The recess opens downward and
The heating element is located behind the recess in the fuel tank .
In a cross-sectional view orthogonal to the vehicle front-rear direction, the space formed by the undercover and the vehicle body floor is communicated with the recess in the vehicle front-rear direction.
Lower body structure. The length from the lower surface of the fuel tank to the upper end of the recess is shorter than the length from the undercover to the upper end of the floor tunnel.
The lower body structure according to claim 1. Provided with an insulator fixed to the bottom surface of the fuel tank and covering the recess of the fuel tank from below.
The propeller shaft is located between the insulator and the fuel tank,
The exhaust pipe is located below the insulator,
The lower body structure according to claim 1 or 2. The insulator projects upward in the recess of the fuel tank.
The lower body structure according to claim 3. In a lower body structure with a body floor with a floor tunnel
The vehicle body floor has step-up portions extending from below toward both sides of the floor tunnel.
The lower body structure
An undercover that covers the raised part from below,
The fuel tank located behind the undercover and
With a heating element located behind the fuel tank,
The fuel tank has a recess on the lower surface having a width smaller than the width between the raised portions in the vehicle width direction.
The recess opens downward and
The heating element is located behind the recess in the fuel tank.
The front part of the undercover is fixed so as to overlap with the subframe for the front suspension.
Lower body structure.

Images