JP2007062733A - Component for vehicle body and its induction hardening method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a component for vehicle and its induction hardening method capable of establishing a required strength distribution easily through a hardening process. <P>SOLUTION: A center pillar 10 as component for a vehicle body formed through press working is equipped with a middle top part 11 whose up-and-down direction is a longitudinal direction and a pair of side wings 12 both bending from the middle top part 11 toward inside the vehicle on both sides in the vehicle fore-and-aft direction of the middle top part 11 in such an arrangement that the bending direction is identical to the width direction, wherein the middle top part 11 and the side wings 12 are furnished with a hardened region Q due to the induction hardening with the outside contour shown by the two-dotted chain line 19 and also non-hardened regions, and the non-hardened region is furnished with a hole 18 formed at the time of press working prior to the induction hardening, in which the proportion of the hardened region Q and the non-hardened region varies along the longitudinal direction. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a car body part subjected to quenching treatment and an induction hardening method thereof, and can be applied to various car body parts such as a center pillar, a front bumper beam, a front side frame, and the like.

  A center pillar, which is a vehicle body part that forms part of the vehicle body and serves as a support between the front seat and the rear seat, is formed in a hat shape in cross section. Specifically, the center pillar has an intermediate top portion extending in the longitudinal direction that is the vertical direction, and both sides in a direction orthogonal to the longitudinal direction in the plane of the intermediate top portion, that is, on both sides in the vehicle front-rear direction. A pair of side wings that bend inward from the middle top to the inside of the vehicle, extend in the longitudinal direction and have the bending direction as the width direction, and a flange that extends in the vehicle front-rear direction away from the tips of these side wings; Consists of. The center pillar is formed in an elongated shape with a small width in the vehicle front-rear direction in order to secure a large field of view from the passenger compartment through the side door window glass. Great strength is required for countermeasures.

  As conventional measures for increasing the strength of the center pillar, it is known to provide the center pillar with a reinforcing force as a reinforcing material and to quench the center pillar.

  According to the former, the overall weight of the center pillar increases, which is against the demand for a reduction in the weight of the vehicle body, and therefore the latter is preferable. In the latter case, when quenching the center pillar, in order to effectively receive the load acting on the center pillar, the strength is increased at a place where a large strength is required, and the strength is small. It is desirable to carry out a quenching process that provides the required strength distribution at a sufficient strength at a sufficient portion.

  Japanese Patent Laid-Open No. 10-17933 is known as a conventional technique for performing such quenching treatment. In this prior art, the entire width of the center pillar in the longitudinal direction of the vehicle is hardened by an induction hardening device, and by this hardening treatment, the hardness distribution in the vertical direction becomes a distribution corresponding to the required strength distribution. In order to obtain such a hardness distribution, the moving speed is changed when the induction hardening apparatus is moved with respect to the center pillar for quenching treatment.

  In this prior art, the policy for obtaining the required strength distribution is to generate a hardness distribution corresponding to this strength distribution in the center pillar. To obtain the hardness distribution corresponding to the strength distribution, Advanced technology such as control technology considering various conditions such as material is required.

  An object of the present invention is to provide a vehicle body part such as a center pillar which can easily obtain a required strength distribution by quenching, and to provide an induction hardening method used for producing the vehicle body part. is there.

  The vehicle body part according to the present invention bends from the intermediate top to the same side on both sides of the intermediate top extending in the longitudinal direction and the direction perpendicular to the longitudinal direction in the plane of the intermediate top. A pair of side wings extending in the width direction and having the bending direction as a width direction, and at least one pair of the side wings is quenched from the intermediate top and the pair of side wings. A quenching region and a non-quenching region that is not quenched are provided, and the ratio of the quenching region and the non-quenching region in the width direction is a ratio for obtaining the required strength. It is a feature.

  In this vehicle body part, a quenching region and a non-quenching region are provided in at least a pair of side wings of the intermediate top part and the pair of side wings, and a ratio between the quenching region and the non-quenching region in the width direction is requested. Therefore, the strength can be determined by setting the ratio between the quenching region and the non-quenching region. Therefore, the required strength distribution can be easily obtained. Moreover, the toughness according to the ratio of this non-hardening area | region with respect to a hardening area | region can also be ensured by a non-hardening area | region.

  In this vehicle body part, when the strength is not changed in the longitudinal direction of the vehicle body part and the strength distribution is uniform in the longitudinal direction, the ratio of the quenching area and the non-quenching area is If the strength does not have to be changed in the longitudinal direction and the strength is changed in the longitudinal direction of the vehicle body part to obtain a uniform strength distribution, the ratio of the quenching area to the non-quenched area is set to the length of the car body part. Change in the direction. In the case of the latter, you may provide the part into which the whole became the quenching area | region or the non-hardening area | region in some longitudinal directions of the components for vehicle bodies.

  Further, the quenching region may be provided also at the intermediate top, and when the quenching region is also provided at the intermediate top in this manner, the intermediate top in the entire direction perpendicular to the longitudinal direction in the plane of the intermediate top is provided. A quenching region may be provided over the entire surface, a quenching region may be provided only on both sides in this direction, and a non-quenching region may be provided between these quenching regions.

  According to the latter, the toughness of the vehicle body parts can be secured by the non-quenched region. It is also possible to form holes in this non-quenched region.

  Further, the vehicle body component according to the present invention bends from the intermediate top to the same side on both sides in the direction perpendicular to the longitudinal direction in the middle top extending in the longitudinal direction and in the plane of the middle top, In a vehicle body part including a pair of side wings extending in the longitudinal direction and having the bending direction as a width direction, at least an intermediate top of the intermediate top and the pair of side wings is quenched. A quenching area and a non-quenched non-quenched area are provided, and a ratio between the quenching area and the non-quenched area in the direction perpendicular to the longitudinal direction in the plane of the intermediate top is required. It is characterized by a ratio for obtaining strength.

  In this vehicle body part, at least an intermediate top portion of the intermediate top portion and the pair of side wing portions is provided with a quenching region and a non-quenching region, and these quenching in a direction perpendicular to the longitudinal direction in the plane of the intermediate top portion Since the magnitude of the strength is determined by setting the ratio between the area and the non-quenched area, the required strength distribution can be easily obtained by setting the ratio between the quenched area and the non-hardened area, Moreover, the toughness according to the ratio of this non-hardening area | region with respect to a hardening area | region can also be ensured by a non-hardening area | region.

  Also in this vehicle body part, by not changing the ratio of the quenching region and the non-quenching region in the longitudinal direction of the vehicle body component, the strength does not have to be changed in the longitudinal direction of the vehicle body component. The strength may be changed in the longitudinal direction of the vehicle body part by changing the ratio to the non-quenched region in the longitudinal direction of the vehicle body part. In the case of the latter, you may provide the part into which the whole became the quenching area | region or the non-hardening area | region in some longitudinal directions of the components for vehicle bodies.

  Moreover, the quenching area | region provided in an intermediate | middle top part is good only in the both sides of the direction orthogonal to the said longitudinal direction in the surface of this intermediate | middle top part, and is good also as a non-quenching area | region between these quenching areas.

  The toughness of the vehicle body parts can be secured by this non-quenched region. It is also possible to form holes in this non-quenched region.

  The first example of the vehicle body part that is quenched as described above is a center pillar. It is preferable that the quenching region provided in the center pillar is a portion of the center pillar corresponding to the window hole for arranging the window glass in the side door.

  According to this, in the center pillar, the side where the width dimension in the vehicle front-rear direction is small in order to secure a large field of view from the passenger compartment through the window glass of the side door, The required strength against collision can be given.

  Further, the quenching region of the center pillar may have a uniform intensity distribution from the upper part to the lower part, or may be a divergent region that continuously expands from the upper part to the lower part.

  According to the latter, it is possible to increase the strength of a portion that receives a large side collision load from another vehicle or the like, and to effectively absorb the collision energy at a portion where the strength above the portion gradually decreases. In addition, since the quenching area continuously expands and there is no portion that changes rapidly, and therefore the intensity distribution does not change rapidly, the center pillar breaks when it receives a collision load from another vehicle. You can prevent songs and so on.

  The center pillar in which the portion corresponding to the window hole for arranging the window glass in the side door is quenched may be provided with lean forces at the upper and lower portions of the quenching region. According to the lean force provided at the upper part of the quenching area, it is possible to secure a large bonding strength with the roof portion of other members forming the vehicle body, and according to the lean force provided at the lower part of the quenching area, the strength of the attachment portion of the side door hinge is secured. Can be increased.

  In addition, depending on the type of vehicle in which the center pillar in which the portion corresponding to the window glass arrangement window hole in the side door is quenched as described above is used, one of the reinforcements provided at the upper and lower portions of the quenching region is used. The lean force, for example, the upper lean force may be omitted.

  The center pillar may be provided with a lean force having the same or substantially the same length as the longitudinal range of the center pillar provided with the quenching region. According to this, although the weight of the whole center pillar increases, the overall strength of the center pillar can be increased by an amount corresponding to the strength of the quenching process, compared to the center pillar having the same overall weight.

  A second example of a body part to be quenched is a front bumper beam. It is preferable that the quenching area of the front bumper beam is increased at the left and right coupling portions where the front ends of the left and right front side frames are coupled, and gradually decreased toward the central portion between the left and right.

  According to this, when a slight collision load is applied to the central part of the front bumper beam that has an overall shape bow shape with the central part between the left and right protruding forward, the central part is not so strong and tough. It can be received effectively, and a large impact load can be received effectively at the left and right joints where the strength is increased and the front side frames are joined.

  A third example of the body part to be quenched is a front side frame in which a front end portion is coupled to a front bumper beam. It is preferable that the quenching region of the front side beam is increased at the front end portion and the retracted portion at a position retracted from the front end portion and is decreased at the intermediate portion therebetween.

  According to this, when a large impact load from the front bumper beam is applied to the front side frame, the middle part with low strength becomes a buckling point where buckling occurs, and the collision energy is effectively absorbed by the front side frame by this buckling point. it can.

  In addition to the above, the car body part to be quenched may be a side sill joined to the left and right ends of the front floor, a rear side frame, or a rear side frame reinforcement. Further, when the center pillar is provided with the lean force, the lean force may be used, and the vehicle body part to which the present invention is applied may be any vehicle body part.

  Further, the quenching apparatus for quenching the body parts may be an induction quenching apparatus, a laser quenching apparatus, a gas flame quenching apparatus, or any type of quenching apparatus.

  The induction hardening method for a vehicle body part according to the present invention is the same as the above. First, the intermediate top extending in the longitudinal direction and the same side from the intermediate top on both sides in the direction perpendicular to the longitudinal direction in the plane of the intermediate top And a pair of side wings extending in the longitudinal direction and having the bending direction as a width direction, and manufacturing the vehicle body part. A hole is formed in an intermediate portion on both sides in a direction orthogonal to the longitudinal direction in the plane of the top portion, and then both sides of the intermediate top portion in a direction orthogonal to the longitudinal direction in the plane of the intermediate top portion are induction-hardened. It is characterized by quenching with an apparatus.

  According to this induction hardening method, when it is necessary to provide a hole in the intermediate top part at the intermediate part on both sides in the direction orthogonal to the longitudinal direction in the plane of the intermediate top part, this hole is formed during the production of the vehicle body part. After that, since the both sides of the intermediate top in the direction perpendicular to the longitudinal direction in the plane of the intermediate top are quenched by the induction hardening device, the place to be hardened is out of the place where the hole is formed. become. For this reason, the quenching energy does not concentrate around the hole, and it is possible to eliminate the occurrence of uneven quenching.

  In this induction hardening method, when the vehicle body part is a steel plate product manufactured by press forming, the hole is formed by punching during press forming.

The present invention described above can be applied to the case where a vehicle body part is manufactured from a steel plate having an arbitrary tensile strength. This tensile strength may be 441.29925 N / mm class ² , 490.3325 N / mm class ² , 588.399 N / mm class ² , 686.4655 N / mm class ² , or 784.532 N / mm class ² .

However, if a steel sheet with a tensile strength of 441.29925 N / mm grade ² is used as the material for the body parts, this tensile strength is not so high, so products with complicated shapes can be manufactured by press working. Even if the vehicle body part to be manufactured has a complicated shape, the vehicle body part can be manufactured in a predetermined manner by pressing.

Further, when a steel sheet having a tensile strength of 441.29925 N / mm grade ² is used as a material for vehicle body parts, the quenching temperature is a relatively low temperature of 900 ° C. or less, for example, in the range of 750 ° C. to 900 ° C. In particular, if the temperature is in the range of 800 ° C. to 850 ° C., the galvanized layer of the galvanized steel sheet is not destroyed at this quenching temperature, and a predetermined strength by quenching can be secured. While using a galvanized steel plate effective for rust as a material of a vehicle part, the strength required for a vehicle body part can be obtained.

    According to the present invention, it is possible to achieve an effect that a required strength distribution can be easily provided in a vehicle body part by a quenching process.

  Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows a left side body 1 of left and right side bodies of a four-wheel vehicle to which a center pillar, which is a vehicle body part according to an embodiment of the present invention, is applied. The side body 1 is formed by joining an outer panel on the vehicle outer side and an inner panel on the vehicle inner side, and as shown in FIG. 2 which is a cross-sectional view taken along line S2-S2 of FIG. A center pillar 10 according to this embodiment is disposed in an internal space 4 formed by center pillar portions 2A and 3A between the front seat and the rear seat in the panel 2 and the inner panel 3.

  The center pillar 10 includes an intermediate top 11 extending in the vertical direction, which is the longitudinal direction, and intermediate tops on both sides in a direction perpendicular to the vertical direction in the plane of the intermediate top 11, that is, on both sides in the vehicle front-rear direction. 11 from a pair of side wing parts 12 that are bent inward of the vehicle, extend in the vertical direction and have the bending direction as a width direction, and a flange part 13 that extends in the vehicle front-rear direction away from the tip of the side wing parts 12. Become. Therefore, the center pillar 10 has a hat-shaped cross section.

  3 shows a front view of the center pillar 10 as a whole. In FIG. 3, the outer panel 2 is removed and the inner panel 3 is shown. Enlarged portions 14 and 15 bulging in the vehicle front-rear direction are formed at the upper and lower ends of the center pillar 10, and therefore the overall shape of the center pillar 10 is substantially I-shaped. The center pillar 10 incorporated between the outer panel 2 and the inner panel 3 has upper and lower enormous portions 14 and 15 formed on the roof portion and floor portion of the outer panel 2 and the roof portion 3C and floor portion 3D of the inner panel 3. Further, the flange portion 13 shown in FIG. 2 is joined to the flange portion 2B of the center pillar portion 2A of the outer panel 2 and the flange 3B of the center pillar portion 3A of the inner panel 3 by spot welding, respectively. The panel 2 and the inner panel 3 are coupled.

  Further, as shown in FIG. 3, lean forces 16 and 17 are arranged at the upper part of the center pillar 10 and at a substantially central part in the vertical direction or a part slightly below this, and these leans are arranged. The forces 16 and 17 are joined to the center pillar 10 by spot welding.

  As shown in FIG. 2, a hole 18 is formed in the intermediate top portion 11 of the center pillar 10, and a plurality of the holes 18 are provided in the longitudinal direction of the intermediate top portion 11 as shown in FIG. 3. When these holes 18 are immersed in an electrodeposition coating solution for electrodeposition coating of the side body 1 manufactured with the outer panel 2, the inner panel 3, the center pillar 10, the reinforcements 16 and 17, and other necessary parts. The electrodeposition coating liquid that has entered the inner space 4 formed by the center pillar portions 2A and 3A of the outer panel 2 and the inner panel 3 is applied to the narrow gap 5 between the center pillar portion 2A of the outer panel 2 and the center pillar 10. The inner pillar 2A of the outer panel 2 can be reliably infiltrated in a predetermined manner.

In the above, the center pillar 10 is manufactured by transfer-pressing a galvanized steel sheet having a thickness of 1.0 mm, 1.2 mm, 1.4 mm, or 1.6 mm and a tensile strength of 441.29925 N / mm ² grade, During manufacturing by this transfer press process, the hole 18 is formed by punching.

  FIG. 4 is an enlarged view of a main part of the center pillar 10 in which the holes 18 are formed as described above, showing an enlarged portion to be quenched. A quenching region Q whose outer contour is indicated by a two-dot chain line 19 is provided between the lean forces 16 and 17 while partially overlapping the lean forces 16 and 17. 5 is a sectional view taken along line S5-S5 in FIG. 4, FIG. 6 is a sectional view taken along line S6-S6 in FIG. 4, and FIG. 7 is a sectional view taken along line S7-S7 in FIG. The quenching region Q is provided in the intermediate top 11 and the pair of side wings 12 so that the quenching region Q continuously expands from the top to the bottom in the intermediate top 11 and the pair of side wings 12. It has become an endless area.

  Moreover, as FIG. 4 shows, the hardening area | region Q is provided in the part of the center pillar 10 corresponding to the window hole for arrangement | positioning of the window glass 20 (refer FIG. 3) provided in the side door of a vehicle.

  In the present embodiment, there are two quenching regions Q in the vehicle front-rear direction, and the region in the intermediate top 11 of these quenching regions Q is orthogonal to the longitudinal direction of the center pillar 10 in the plane of the intermediate top 11. Are provided on both sides in the vehicle direction, in other words, on both sides in the vehicle front-rear direction, and these regions are continuous with the regions in the respective side wings 12 in the quenching region Q.

  The holes 18 shown in FIG. 4 are provided between regions formed on both sides in the vehicle front-rear direction of the intermediate top portion 11 among the two quenching regions Q provided separately in the vehicle front-rear direction.

  The intermediate top portion 11 and the pair of side wing portions 12 are non-quenched regions that are not quenched except the quenched region Q. As described above, the quenching region Q has a divergent shape that continuously expands from the top to the bottom. On the contrary, the non-quenching region has a tapered shape that continuously decreases from the top to the bottom. . Therefore, the intermediate top portion 11 and the pair of side wing portions 12 have a quenching region Q and a non-quenching region, and the ratio of the quenching region Q and the non-quenching region in the vehicle front-rear direction from the top to the bottom in the intermediate top portion 11. It changes in the longitudinal direction of the center pillar 10 so that the ratio of the quenching region Q increases as it shifts, and the ratio of the quenching region Q and the non-quenched region in the width direction of the side blades 12 also in the pair of side blades 12. However, it changes in the longitudinal direction of the center pillar 10 so that the ratio of the quenching region Q increases as it moves from the upper part to the lower part.

  The quenching region Q described above is formed by manufacturing the center pillar 10 from the above-described galvanized steel sheet by transfer press processing and forming the holes 18 during the manufacturing, and then quenching the center pillar 10 with an induction hardening device. The

  FIG. 8 shows an outline of the induction hardening apparatus 30. The induction hardening device 30 includes an oscillating device 31 and a pair of coil parts 32 in the vehicle front-rear direction that are connected to the oscillating device 31 and set on the center pillar 10 or face-to-face with the center pillar 10. The center pillar 10 can be provided with the above-described quenching region Q by setting the shape and the like of these coil portions 32 provided for each quenching region Q formed separately in the vehicle longitudinal direction in the center pillar 10. .

  As a result of the quenching process by the induction hardening device 30, the center pillar 10 is provided with the quenched region Q that has been quenched as shown in FIGS. 4 to 7.

  According to the embodiment described above, the intermediate top portion 11 and the pair of side wing portions 12 of the center pillar 10 are provided with the quenching region Q and the non-quenched region, and the intermediate top portion 11 has the quenching region Q and the non-quenched region in the vehicle longitudinal direction. Since the strength of the center pillar 10 is determined by the ratio of the quenching region Q and the non-quenching region in the width direction of the side wing part 12 in the side wing part 12 depending on the ratio to the region, the strength of the center pillar 10 as requested is determined. These ratios can be set, and the strength distribution in the longitudinal direction of the center pillar 10 can be easily set by determining the ratio between the quenching region Q and the non-quenching region in the longitudinal direction of the center pillar 10.

  Further, the quenching region Q provided in the center pillar 10 is a portion corresponding to the window hole for arranging the window glass 20 provided in the side door, and this portion secures a large field of view from the vehicle interior in the center pillar 10. For this purpose, the width in the longitudinal direction of the vehicle is small. However, since a quenching region is provided in this portion, a sufficient strength against a load of a side collision with another vehicle or a wall can be imparted to this portion.

  Further, since the portion below the quenching region Q is reinforced by the reinforcing beam incorporated in the side door portion below the window glass 20, the portion below the quenching region Q with respect to the collision load by this reinforcing beam is used. The strength is ensured and the quenching region Q is widened from the upper part to the lower part of the center pillar 10, so that the strength of the part that receives a large side collision load from other vehicles is increased. In addition, the collision energy can be effectively absorbed in the portion above the portion where the strength is gradually reduced and the toughness is gradually increased by the expansion of the non-quenched region.

  In addition, the quenching region Q is continuously changed, and is not abruptly changed. Therefore, there is no place where the strength is suddenly changed by the quenching process. It is possible to prevent the center pillar 10 from being bent when receiving a collision load or the like.

  Since the center pillar 10 is provided with lean forces 16 and 17 above and below the quenching region Q, the outer panel 2 and the inner panel 3 that form the vehicle body by the lean force 16 above the quenching region Q. A large joint strength with the roof portion can be secured, and the strength of the attachment portion of the side door hinge can be increased by the lean force 17 below the quenching region Q. Further, the lean forces 16 and 17 can prevent the strength of the center pillar 10 from rapidly decreasing at the upper and lower ends of the quenching region Q.

  Further, in the quenching region Q provided in the center pillar 10, the region in the intermediate top portion 11 is provided separately on both sides in the vehicle front-rear direction in the intermediate top portion 11, and is a non-quenching region in the middle portion on both sides. As described above, the hole 18 necessary for the electrodeposition coating is formed in the portion, and even if the quenching region Q is provided in the center pillar 10 by the induction hardening operation performed after the hole 18 is formed, the quenching region Q is Since it is provided on both sides in the vehicle front-rear direction in the intermediate top portion 11 that is disengaged from the location of the hole 18, induction hardening energy is concentrated around the hole 18 and quenching unevenness does not occur.

Further, the center pillar 10 is manufactured by pressing a steel sheet having a tensile strength of 441.29925 N / mm ² grade. Since this tensile strength is so large, the center pillar 10 having a complicated shape is formed in a desired shape. In addition, the quenching temperature when quenching the steel sheet having this tensile strength may be a relatively low temperature of 900 ° C. or less, for example, a temperature in the range of 750 ° C. to 900 ° C. Is a temperature within a range of 800 ° C. to 850 ° C., at this temperature, the galvanized layer of the galvanized steel sheet is not destroyed and a predetermined strength by quenching can be secured. Therefore, as a material of the center pillar 10, The strength required for the center pillar 10 can be obtained while using a galvanized steel sheet effective for rust.

  FIG. 9 shows an embodiment in which a lean force 40 having a length that is the same as or substantially the same as the longitudinal range of the center pillar 10 provided with the quenching region Q is joined to the center pillar 10 by spot welding. According to this embodiment, the total weight of the center pillar 10 increases by the amount of the lean force 40, but the strength is increased by providing the quenching region Q in the center pillar 10 when compared with the center pillar having the same total weight. The advantage that the overall strength of the center pillar 10 can be increased by that amount.

  In this embodiment, the lean force 40 may be provided in the center pillar 10 as a member different from the lean forces 16 and 17 shown in FIGS. 3 and 4, and the upper and lower portions that also serve as the lean forces 16 and 17. You may provide in the center pillar 10 as a member with a long dimension. Further, the lean forces 16 and 17 may be overlapped and joined to the lean force 40 having a long vertical dimension.

  FIGS. 10-18 shows embodiment at the time of applying a hardening process to a front bumper beam and a front side frame. FIG. 10 is a perspective view before the front bumper beam 50 and the pair of left and right front side frames 60 are coupled, FIG. 11 is a plan view after the coupling, and FIG. 12 is a side view after the coupling. 13 is a sectional view taken along line S13-S13 in FIG. 11, FIG. 14 is a sectional view taken along line S14-S14 in FIG. 11, FIG. 15 is a sectional view taken along line S15-S15 in FIG. FIG. 17 is a sectional view taken along line S17-S17 in FIG. 12, and FIG. 18 is a sectional view taken along line S18-S18 in FIG.

  As shown in FIGS. 10 to 12, the front end portions of the pair of left and right front side frames 60 are formed on the left and right sides of the front bumper beam 50 that has an overall shape bow shape with the center portion in the longitudinal direction projecting forward. The front bumper beam 50 is coupled by welding or a fastener such as a bolt. These front side frames 60 are coupled to the left and right side bodies and the dashboard panel in the engine room of the FF four-wheel vehicle.

  As shown in FIGS. 10 and 13 to 15, the front bumper beam 50 includes a front surface portion 51 that is an intermediate top portion extending in the longitudinal direction that is the left-right direction of the vehicle, and the front surface portion 51. The upper surface portion 52 and the lower surface portion 53 which are a pair of side wing portions which are bent toward the rear of the vehicle on both sides in the direction perpendicular to the longitudinal direction of the vehicle, in other words, on both upper and lower sides, The upper surface portion 52 and the rear surface portion 54 connecting the rear end portions of the lower surface portion 53, and the upper surface portion 52, the lower surface portion 53, and the rear surface portion 54, like the front surface portion 51, extend in the longitudinal direction of the front bumper beam 50. The length extends over the entire length of the front bumper beam 50.

  A quenching region Q provided in the front bumper beam 50 is shown in FIG. 11 in which the outer contour of the region Q on the upper surface portion 52 is indicated by a two-dot chain line 55, and changes in the region Q in the longitudinal direction of the front bumper beam 50 are illustrated in FIGS. As shown in FIG. 15, the size is increased at the coupling portions on both the left and right sides where the tip portions of the pair of left and right front side frames 60 are coupled, and gradually decreases toward the center between the left and right.

  When the quenching region Q is in this way, when a slight collision load is applied to the central portion of the front bumper beam 50 having an overall shape bow shape in which the central portion between the left and right protrudes forward, the strength is increased. However, in the center portion where the toughness is increased by the non-quenched region instead, the slight collision load can be effectively received. On the other hand, the large impact load is increased by the quenching region Q that is larger than the non-quenched region, and can be effectively received at the left and right joints to which the front side frame 60 is joined.

  As shown in FIG. 10 and FIGS. 16 to 18, the front side frame 60 includes a web portion 61 that is an intermediate top portion that extends in the longitudinal direction, which is the vehicle front-rear direction, and the web portion 61 within the plane. Flange portions 62 and 63 which are bent inward of the vehicle on both sides in a direction orthogonal to the longitudinal direction of the vehicle, in other words, both on the upper and lower sides, and are formed as a pair of upper and lower side wings with the bending direction as the width direction. These flange portions 62 and 63 extend in the longitudinal direction of the front side frame 60 in the same manner as the web portion 61.

  The quenching region Q provided in the front side frame 60 having such a shape is shown in FIG. 12 in which the outer contour of the region Q in the web portion 61 is indicated by a two-dot chain line 64, and the region in the longitudinal direction of the front side frame 60. As shown in FIGS. 16 to 18 showing the change of Q, the front end portion coupled to the front bumper beam 50 and the retreating portion at a position retreated from the front end with a space apart from the front end portion are large, and there is an intermediate between them. The part is getting smaller.

  According to this, when a large collision load from the front bumper beam 50 is applied to the front side frame 60, an intermediate portion where the strength between the tip portion and the retracted portion is small can be a buckling point where buckling occurs. By this buckling point, a large collision energy can be effectively absorbed by the front side frame 60.

  The present invention can be used for quenching vehicle body parts such as center pillars.

1 is a perspective view showing a left side body of left and right of a four-wheeled vehicle to which a center pillar that is a vehicle body part according to an embodiment of the present invention is applied. It is the S2-S2 sectional view taken on the line of FIG. It is the whole center pillar front view shown by the relationship with an inner panel among the outer panel and inner panel which form the side body of FIG. It is the principal part enlarged view of the center pillar which expanded and showed the part processed by hardening. FIG. 5 is a cross-sectional view taken along line S5-S5 of FIG. FIG. 6 is a sectional view taken along line S6-S6 of FIG. It is the S7-S7 line sectional view of Drawing 4. It is a perspective view which shows the outline | summary of the induction hardening apparatus when set to a center pillar. It is a figure similar to FIG. 2 which shows embodiment which provided the lean force over the range of the longitudinal direction of the center pillar provided with the quenching area | region in the center pillar. It is a perspective view which shows the state before couple | bonding a front bumper beam and a pair of left and right front side frames. It is a top view which shows after combining a front bumper beam and a pair of right and left front side frames. It is a side view which shows after combining a front bumper beam and a pair of right and left front side frames. It is the S13-S13 sectional view taken on the line of FIG. It is the S14-S14 sectional view taken on the line of FIG. It is the S15-S15 sectional view taken on the line of FIG. It is the S16-S16 sectional view taken on the line of FIG. It is the S17-S17 sectional view taken on the line of FIG. It is the S18-S19 sectional view taken on the line of FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Center pillar 11 Middle top part 12 Side wing part 20 Side door wind glass 30 Induction hardening apparatus 32 Coil part 50 Front bumper beam 51 Front part which is a middle top part 52 Upper surface part which is a side wing part 53 Lower surface part which is a side wing part 60 Front side frame 61 Web part 62 which is an intermediate top part, 63 Upper and lower flange parts which are side wing parts Q Quenching area

Claims (2)

An intermediate top that extends in the longitudinal direction and bends to the same side from the intermediate top on both sides in a direction perpendicular to the longitudinal direction in the plane of the intermediate top, extends in the longitudinal direction, and extends the bending direction. In a vehicle body part made of a press-molded product having a pair of side wings in the width direction,
The intermediate top and the pair of side wings are provided with a quenching region induction-hardened and a non-quenched non-quenched region, and the quenching region in the intermediate top is the surface in the plane of the intermediate top. It is on both sides in the direction perpendicular to the longitudinal direction, and between these quenching regions in the intermediate top portion is the non-quenching region, and holes formed in the non-quenching region at the time of the press molding before the induction hardening. And a ratio of the quenching region and the non-quenching region is changed in the longitudinal direction. First, an intermediate top that extends in the longitudinal direction, and bends to the same side from the intermediate top on both sides in a direction orthogonal to the longitudinal direction in the plane of the intermediate top, extends in the longitudinal direction and A vehicle body part including a pair of side wings with the bending direction as a width direction is manufactured by press molding,
At the time of manufacturing, a hole is formed in the intermediate top on both sides in the direction perpendicular to the longitudinal direction in the plane of the intermediate top,
Next, a region of the intermediate top portion in which the hole is not formed on both sides of the intermediate top portion in a direction orthogonal to the longitudinal direction in the plane of the intermediate top portion is quenched by an induction hardening device. Induction hardening method.

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