CN217515303U - All-terrain vehicle - Google Patents

Abstract

The utility model discloses an all-terrain vehicle, include: a frame; the mounting frame assembly is at least partially arranged on the frame; the mounting bracket subassembly includes: the rear axle bracket is at least partially arranged on the frame and used for fixing at least part of the transmission assembly; the power supply bracket is at least partially arranged on the frame; the frame comprises a pillar, the pillar is arranged on the rear side of the frame, and the pillar is provided with a first connecting hole; the rear axle bracket is connected with the support column through the first connecting hole, and the power supply bracket is also connected with the support column through the first connecting hole. The utility model has the advantages that: the first connecting hole, the second connecting hole and the third connecting hole can be fixed through the same connecting piece, namely the mounting point of the rear axle support and the mounting point of the power supply support are integrated together, so that the assembly performance of the all-terrain vehicle is improved, and the number of parts of the all-terrain vehicle is reduced.

Description

All-terrain vehicle

Technical Field

The utility model relates to a vehicle field especially indicates an all-terrain vehicle.

Background

An all-terrain vehicle refers to a vehicle that can travel on any terrain, and can freely travel on terrains where ordinary vehicles are difficult to maneuver. The model of an atv has many uses and is not limited by road conditions, and therefore, an atv is a vehicle with good trailer performance.

At present, trailer power sockets of all-terrain vehicles are generally mounted at the tail of a vehicle, and a separate mounting point is required to be provided for mounting. The mounting mode can increase the mounting point of the all-terrain vehicle, and is not beneficial to improving the structural compactness and the space utilization rate of the all-terrain vehicle.

SUMMERY OF THE UTILITY MODEL

In order to solve the defects of the prior art, the utility model aims to provide an all-terrain vehicle which can integrate a rear axle bracket and a power supply bracket mounting point.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

an all-terrain vehicle comprising: a frame; the walking assembly is at least partially arranged on the frame and comprises a first walking wheel and a second walking wheel; the suspension assembly comprises a front suspension and a rear suspension, the first travelling wheel is connected with the frame through the front suspension, and the second travelling wheel is connected with the frame through the rear suspension; the power assembly is at least partially arranged on the frame; the transmission assembly is connected with the walking assembly and the power assembly; the mounting frame assembly is at least partially arranged on the frame; the mounting bracket subassembly includes: the rear axle bracket is at least partially arranged on the frame and used for fixing at least part of the transmission assembly; the power supply bracket is at least partially arranged on the frame; the frame comprises a pillar, the pillar is arranged on the rear side of the frame and is provided with a first connecting hole; the rear axle bracket is connected with the support column through the first connecting hole, and the power supply bracket is also connected with the support column through the first connecting hole.

Further, the axis of the first connection hole extends substantially in the fore-and-aft direction of the atv.

Furthermore, a second connecting hole is formed in the rear axle support, and the second connecting hole is connected with the first connecting hole through the same connecting piece.

Furthermore, a third connecting hole is formed in the power supply support, and the third connecting hole is connected with the first connecting hole through the same connecting piece.

Furthermore, the circle center of the first connecting hole, the circle center of the second connecting hole and the circle center of the third connecting hole are basically located on the same straight line.

Further, a bushing is disposed in the first connection hole.

Further, the power supply support comprises a first installation part, a connection part and a second installation part, the first installation part and the second installation part are connected through the connection part, and the first installation part is arranged on the upper side of the second installation part.

Further, the first mounting portion and the second mounting portion extend substantially in the up-down direction of the all-terrain vehicle, and the connecting portion extends substantially in the front-rear direction of the all-terrain vehicle.

Further, a third connecting hole is formed in the first mounting portion.

Furthermore, a fourth connecting hole and a lightening hole are formed in the second mounting portion, the lightening hole is formed in the center of the second mounting portion, and the fourth connecting hole is formed around the lightening hole.

Compared with the prior art, the utility model provides an all-terrain vehicle can be fixed first connecting hole, second connecting hole, third connecting hole through same connecting piece, is about to the mounting point of rear axle support and the mounting point of power support is integrated together to improve all-terrain vehicle's assembly nature, reduce all-terrain vehicle's spare part quantity.

Drawings

Fig. 1 is a schematic structural diagram of the all-terrain vehicle of the present invention.

Fig. 2 is a partial structural schematic diagram of the all-terrain vehicle of the present invention.

Fig. 3 is a schematic view of the frame structure of the all-terrain vehicle of the present invention.

Fig. 4 is a schematic structural diagram of the backrest mechanism of the all-terrain vehicle of the present invention.

Fig. 5 is a schematic structural diagram of the buffering mechanism of the all-terrain vehicle of the present invention.

Fig. 6 is a schematic view of the installation of the backrest mechanism and the frame of the all-terrain vehicle of the present invention.

Fig. 7 is a schematic view of the installation of the backrest mechanism and the locking mechanism of the all-terrain vehicle of the present invention.

Fig. 8 is a partially enlarged view of the point C in fig. 7 according to the present invention.

Fig. 9 is a schematic structural diagram of the locking mechanism of the all-terrain vehicle of the present invention.

Fig. 10 is a partial structural schematic view of the backrest mechanism of the all-terrain vehicle of the present invention.

Fig. 11 is a front view schematic structural diagram of the backrest mechanism of the all-terrain vehicle of the present invention.

Fig. 12 is a schematic structural view of the second mounting frame of the all-terrain vehicle of the present invention.

Fig. 13 is a first schematic structural diagram of a third mounting frame of the all-terrain vehicle of the present invention.

Fig. 14 is a second structural schematic diagram of the third mounting frame of the all-terrain vehicle of the present invention.

Fig. 15 is a schematic structural view of the fourth pillar and the sixth mounting bracket of the all-terrain vehicle of the present invention.

Fig. 16 is a schematic structural view of the power bracket of the all-terrain vehicle of the present invention.

Detailed Description

In order to make the technical solution of the present invention better understood by those skilled in the art, the technical solution of the present invention in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings.

As shown in fig. 1 and 2, atv 100 includes a frame 11, a walking assembly 12, a suspension assembly 13, a power assembly 14, a saddle assembly 15, a mounting frame assembly 16, a brake assembly 17, an electrical assembly 18, a footrest assembly 19, a fuel assembly 21, a heat sink assembly 22, a body cover 25, a transmission assembly 26, and a steering assembly 27. Suspension assembly 13 includes a front suspension 131 and a rear suspension 132 for connecting frame 11 and undercarriage assembly 12. Walking assembly 12 is at least partially disposed on frame 11, walking assembly 12 includes first road wheel 121 and second road wheel 122, first road wheel 121 connects to frame 11 through front suspension 131, second road wheel 122 connects to frame 11 through rear suspension 132, walking assembly 12 is used for the motion of atv 100. Power assembly 14 is at least partially disposed on frame 11 for providing power to ATV 100. A saddle assembly 15 is at least partially disposed on frame 11 for a user and/or passenger to ride. A mounting bracket assembly 16 is at least partially disposed on frame 11 for mounting or dismounting other components adapted to atv 100. Brake assembly 17 is disposed at least partially on frame 11 and at least partially on undercarriage assembly 12 for braking undercarriage assembly 12 and, thus, atv 100. An electrical assembly 18 is at least partially disposed on the frame 11 for providing electrical power. Specifically, electrical components 18 are disposed on frame 11 via mounting bracket assembly 16. A footrest assembly 19 is at least partially disposed on frame 11 for providing support to a user and/or passenger's foot. A fuel assembly 21 is disposed at least partially on the frame 11 for providing a source of motive power to the power assembly 14. Heat sink assembly 22 is at least partially disposed on frame 11 for dissipating heat from ATV 100. The body covering 25 is at least partially disposed on the frame 11, and the body covering 25 is at least partially disposed on the mounting bracket assembly 16. Transmission assembly 26 is at least partially disposed on frame 11, transmission assembly 26 is connected to running assembly 12, and transmission assembly 26 is further connected to power assembly 14 for transmitting power of power assembly 14 to running assembly 12, thereby driving running assembly 12. Steering assembly 27 is at least partially connected to power assembly 14 for changing gears of ATV 100. For clearly explaining the technical solution of the present invention, a front side, a rear side, a left side, a right side, an upper side, and a lower side as shown in fig. 1 are also defined.

As shown in fig. 3, the frame 11 includes a first pillar 111, a second pillar 112, a third pillar 113, a fourth pillar 114, an upper rail 115, and a lower rail 116, as one implementation. In the fore-aft direction of ATV 100, first leg 111 is disposed on the front side and fourth leg 114 is disposed on the rear side. The second and third support columns 112 and 113 are each disposed between the first and fourth support columns 111 and 114, and the second support column 112 is disposed on the front side of the third support column 113. In the up-down direction of atv 100, upper main beam 115 is disposed on the upper side, and lower main beam 116 is disposed on the lower side. The first column 111, the second column 112, the third column 113, and the fourth column 114 are disposed between the upper main beam 115 and the lower main beam 116. Specifically, the first pillar 111 includes a first pipe 1111, a second pipe 1112, and a first sheet metal member 1113. The second support column 112 includes a third tube 1121 and a fourth tube 1122. The third strut 113 includes a fifth tube member 1131, a sixth tube member 1132, a seventh tube member 1133, an eighth tube member 1134 and a second sheet metal member 1135. The fourth strut 114 includes a ninth tube 1141 and a tenth tube 1142. The upper main beams 115 include a first main beam 1151 and a second main beam 1152. The lower main beams 116 include a third main beam 1161 and a fourth main beam 1162. One end of the first pipe 1111 is connected with the first main beam 1151, the other end of the first pipe 1111 is connected with one end of the first sheet metal component 1113, and the other end of the first sheet metal component 1113 is connected with the third main beam 1161. One end of second tube 1112 is connected to second main beam 1152, the other end of second tube 1112 is connected to one end of first sheet metal component 1113, and the other end of first sheet metal component 1113 is connected to fourth main beam 1162. One end of the third tube 1121 is connected to the first main beam 1151, the other end of the third tube 1121 is connected to the third main beam 1161, one end of the fourth tube 1122 is connected to the second main beam 1152, and the other end of the fourth tube 1122 is connected to the third main beam 1161. One end of the fifth tube 1131 is connected to the first main beam 1151 and the other end of the fifth tube 1131 is connected to one end of the seventh tube 1133. One end of the sixth tube 1132 is connected to the first main rail 1151 and the other end of the sixth tube 1132 is connected to the other end of the seventh tube 1133. One end of the eighth tube 1134 is connected to the third main beam 1161, and the other end of the eighth tube 1134 is connected to the fourth main beam 1162. The seventh pipe member 1133 and the eighth pipe member 1134 are connected by a second sheet metal member 1135. One end of a ninth tube 1141 connects to the first main beam 1151 and the other end of the ninth tube 1141 connects to the third main beam 1161. One end of a tenth tube 1142 is connected to the second main beam 1152 and the other end of the tenth tube 1142 is connected to the fourth main beam 1162.

In this embodiment, along the left-right direction of ATV 100, first main beam 1151 is disposed on the left side of second main beam 1152, third main beam 1161 is disposed on the left side of fourth main beam 1162, first tube 1111 is disposed on the left side of second tube 1112, third tube 1121 is disposed on the left side of fourth tube 1122, fifth tube 1131 is disposed on the left side of sixth tube 1132, and ninth tube 1141 is disposed on the left side of tenth tube 1142. Along the up-down direction of atv 100, first pipe 1111 and second pipe 1112 all set up the upside of first sheet metal component 1113, first girder 1151 sets up the upside of third girder 1161, second girder 1152 sets up the upside of fourth girder 1162, seventh pipe 1133 sets up the upside of eighth pipe 1134, fifth pipe 1131 and sixth pipe 1132 all set up the upside of seventh pipe 1133, second sheet metal component 1135 sets up the downside of seventh pipe 1133 and sets up the upside of eighth pipe 1134. Through the arrangement, the first support column 111, the second support column 112, the third support column 113, the fourth support column 114, the upper main beam 115 and the lower main beam 116 form a basic frame of the frame 11, so that the strength of the frame 11 is improved, and the structures of the first support column 111, the second support column 112, the third support column 113, the fourth support column 114, the upper main beam 115 and the lower main beam 116 are optimized, namely pipe fittings are replaced by sheet metal structures, so that the number of the pipe fittings of the frame 11 is reduced, the weight of the all-terrain vehicle 100 is further reduced, and the light weight of the frame 11 and the all-terrain vehicle 100 is realized.

As one implementation, atv 100 includes a plane of symmetry 101 perpendicular to the left-right direction, and atv 100 is substantially symmetrically disposed about plane of symmetry 101. The frame 11 is arranged substantially symmetrically with respect to the plane of symmetry 101.

As shown in fig. 1, 4-6, as one implementation, the saddle block assembly 15 includes a saddle 151 and a backrest mechanism 152. Saddle 151 is at least partially disposed on frame 11, backrest mechanism 152 is at least partially disposed on frame 11, and backrest mechanism 152 is at least partially disposed on a rear side of saddle 151. The backrest mechanism 152 includes a backrest 1521, a seat cushion 1522, a frame 1523, a mounting bracket 1524, and a cushion mechanism 1525. A backrest 1521 is disposed at least partially over the framework 1523 for providing back support for the occupant. The seat cushion 1522 is disposed at least partially over the mounting bracket 1524 for providing body support for the occupant. The framework 1523 and the mounting bracket 1524 are connected by a cushioning mechanism 1525. The frame 1523 is used for mounting the backrest 1521, so that the backrest 1521 can be stably connected to the frame 1523. The mounting bracket 1524 is used for installing the cushion 1522, so that the cushion 1522 can be stably connected to the mounting bracket 1524.

As an implementation manner, the frame 1523 is provided with a plurality of first mounting points 1523a, and the plurality of first mounting points 1523a are used for mounting the backrest 1521. A plurality of first mounting points 1523a are disposed at least partially on opposite sides of frame 1523. The skeleton 1523 includes a first skeleton 1523b, a second skeleton 1523c, and a third skeleton 1523 d. The first skeleton 1523b and the second skeleton 1523c are connected by a third skeleton 1523 d. The first skeleton 1523b, the second skeleton 1523c, and the third skeleton 1523d are integrally formed. Specifically, the plurality of first mounting points 1523a are at least partially disposed on the left side and/or the right side of the first framework 1523b, the plurality of first mounting points 1523a are at least partially disposed on the left side and/or the right side of the second framework 1523c, and the plurality of first mounting points 1523a are at least partially disposed on the upper side and/or the lower side of the third framework 1523d, so that stable connection between the backrest 1521 and the framework 1523 is achieved.

As an implementation manner, the mounting bracket 1524 is provided with a plurality of second mounting points 1524a, and the plurality of second mounting points 1524a are used for mounting the seat cushion 1522. A number of second mounting points 1524a are provided on either side of the mounting bracket 1524. The mounting bracket 1524 includes a first bracket 1524b, a second bracket 1524d, a third bracket 1524e and a fourth bracket 1524 f. First leg 1524b extends generally in the fore-aft direction of ATV 100, second leg 1524d extends generally in the fore-aft direction of ATV 100, third leg 1524e extends generally in the left-right direction of ATV 100, and fourth leg 1524f extends generally in the left-right direction of ATV 100. A plurality of second mounting points 1524a are at least partially disposed on the first bracket 1524b, and a plurality of second mounting points 1524a are at least partially disposed on the second bracket 1524d, so as to realize stable connection between the seat cushion 1522 and the mounting bracket 1524. Specifically, a first connecting member 1524h is disposed on the first bracket 1524b, and a second connecting member 1524j is disposed on the second bracket 1524 d. A plurality of third mounting points 1524k are disposed on the first connector 1524h and the second connector 1524j, respectively. A plurality of third mounting points 1524k are used for mounting the seat cushion 1522, thereby realizing the stable connection of the seat cushion 1522 and the first connecting piece 1524h, and the stable connection of the seat cushion 1522 and the second connecting piece 1524 j. Among them, the first connector 1524h may be disposed on the left/right side of the first bracket 1524b, and the second connector 1524j may be disposed on the left/right side of the second bracket 1524 d. Specifically, the third bracket 1524e is at least partially disposed between the first bracket 1524b and the second bracket 1524d, one end of the third bracket 1524e is connected to the first bracket 1524b, and the other end of the third bracket 1524e is connected to the second bracket 1524 d; fourth support 1524f is at least partially disposed between first support 1524b and second support 1524d, and one end of fourth support 1524f is connected to first support 1524b, and the other end of fourth support 1524f is connected to second support 1524 d. With the above arrangement, the structure of the mounting bracket 1524 can be more stable, and thus the structure of the backrest mechanism 152 can be more stable. In addition, the fourth bracket 1524f is also used for mounting the buffer mechanism 1525. In the present embodiment, the first bracket 1524b, the second bracket 1524d and the third bracket 1524e are all provided with lightening holes, and the lightening holes are used for lightening the mounting bracket 1524, so that the lightening of the all-terrain vehicle 100 is improved.

As one implementation, the buffering mechanism 1525 includes a limiting member 1525a and a buffering member 1525 n. The limiting member 1525a is disposed on the fourth bracket 1524f and is used for limiting a rotation angle of the framework 1523. The position-limiting member 1525a includes a first position-limiting member 1525b, a second position-limiting member 1525c, a third connecting member 1525e and a fourth connecting member 1525g, and the buffering member 1525n is disposed on the fourth support 1524f and at least partially disposed between the first position-limiting member 1525b and the second position-limiting member 1525 c. The buffering member 1525n has elasticity, and the buffering member 1525n is used for providing elastic buffering, so that the impact force of the backrest 1521 on the passenger is reduced. Through the arrangement, when the all-terrain vehicle 100 runs, the backrest mechanism 152 can provide elastic buffering through the buffering piece 1525n, so that the impact force of the backrest mechanism 152 on passengers is reduced, and the comfort and the safety of the all-terrain vehicle 100 are improved. In addition, the buffer 1525n and the fourth bracket 1524f may be connected by bolts, rivets, or welding. Specifically, the connection mode of the buffer member 1525n and the fourth support 1524f can be adjusted according to actual requirements.

The third connecting member 1525e is used to connect the first limiting member 1525b and the first framework 1523b, and the third connecting member 1525e is rotatably connected to the first limiting member 1525 b. The fourth connecting member 1525g is used for connecting the second limiting member 1525c and the second framework 1523c, and the fourth connecting member 1525g is rotatably connected to the second limiting member 1525 c. Specifically, one end of the third connecting member 1525e is provided with a first receiving groove 1525f, one end of the first framework 1523b is at least partially disposed in the first receiving groove 1525f, and the first framework 1523b is connected to the first receiving groove 1525 f; one end of the fourth connecting member 1525g is provided with a second receiving groove 1525h, one end of the second framework 1523c is at least partially disposed in the second receiving groove 1525h, and the second framework 1523c is connected with the second receiving groove 1525 h. The connection mode of the first frame 1523b and the first receiving groove 1525f may be welding, and the connection mode of the second frame 1523c and the second receiving groove 1525h may be welding. Specifically, a fourth mounting point 1525k is disposed in each of the first receiving groove 1525f and the second receiving groove 1525h, and a fifth mounting point 1525m is disposed on each of the first limiting member 1525b and the second limiting member 1525 c. The fourth mounting point 1525k and the fifth mounting point 1525m are used for the rotational connection between the first limiting member 1525b and the third connecting member 1525e, and the fourth mounting point 1525k and the fifth mounting point 1525m are also used for the rotational connection between the second limiting member 1525c and the fourth connecting member 1525 g.

In this embodiment, a limiting groove 1525d is disposed on the first limiting member 1525b, and a limiting piece 1525j is disposed at the other end of the third connecting member 1525 e; a limiting groove 1525d is formed in the second limiting member 1525c, and a limiting piece 1525j is formed at the other end of the fourth connecting member 1525 g. The limiting piece 1525j is at least partially disposed in the limiting groove 1525d, and the limiting groove 1525d is used for limiting the moving range of the limiting piece 1525j, so as to control the rotating range of the third connecting piece 1525e relative to the first limiting piece 1525b, and control the rotating range of the fourth connecting piece 1525g relative to the second limiting piece 1525c, and further control the rotating range of the backrest 1521 and the framework 1523. The limiting groove 1525d includes a first limit position and a second limit position. The first extreme position is at least partially rearward of the second extreme position in the fore-aft direction of ATV 100. When the limiting piece 1525j abuts against the first limit position, the framework 1523 is at a first angle relative to the mounting bracket 1524; when the limiting piece 1525j abuts against the second limiting position, the framework 1523 is at a second angle relative to the mounting bracket 1524. The first angle and the second angle constitute a rotation angle α. That is, the framework 1523 rotates relative to the mounting bracket 1524 between a first angle and a second angle. Through the setting, the rotation angle alpha of the backrest 1521 and the framework 1523 can be limited in a certain rotation range, so that the backrest 1521 and the framework 1523 are buffered and rotated, and meanwhile, the safety of the backrest 1521 and the framework 1523 is improved. Specifically, the rotation angle α is 0 ° or more and 60 ° or less. In the present embodiment, the rotation angle α is 0 ° or more and 15 ° or less. It is understood that the rotation angle α may be equal to or greater than 0 ° and equal to or less than 10 °.

Specifically, the damping mechanism 1525 further includes a damping rod 1525 r. The buffer rod 1525r is at least partially arranged between the third connector 1525e and the fourth connector 1525g, one end of the buffer rod 1525r is connected with the third connector 1525e, and the other end of the buffer rod 1525r is connected with the fourth connector 1525 g. In this embodiment, one end of the buffer rod 1525r is welded to the third connector 1525e, and the other end of the buffer rod 1525r is welded to the fourth connector 1525 g. The cushion member 1525n includes a mounting portion and a connecting portion that are integrally formed. The mounting portion is used for connecting the buffering member 1525n and the fourth bracket 1524f, and the connecting portion is abutted or contacted with the buffering rod 1525 r. In this embodiment, the connecting portion has elasticity so that the connecting portion can rotate relative to the mounting portion under the urging force of the bumper bar 1525 r. In the fore-and-aft direction of atv 100, bumper bar 1525r is disposed at the front side of the connecting portion, so that the connecting portion rotates relative to the mounting portion under the action of bumper bar 1525 r.

In the present embodiment, the buffer rod 1525r includes a first position where the buffer rods 1525r abut against each other and a second position where the buffer rods 1525n contact each other. When the buffering rod 1525r is located at a first position relative to the buffering member 1525n, the acting force of the buffering member 1525n on the buffering rod 1525r is a first acting force; when the buffering rod 1525r is located at the second position relative to the buffering member 1525n, the acting force of the buffering member 1525n on the buffering rod 1525r is the second acting force. The first force is greater than the second force. When the framework 1523 is at a first angle relative to the mounting bracket 1524, the buffer rod 1525r is at a second position where the buffer member 1525n is in contact with each other; when the frame 1523 is at a second angle relative to the mounting bracket 1524, the bumper bar 1525r is at a first position abutting against the bumper 1525 n. Through the setting, can realize the change of spacing piece 1525j and spacing groove 1525 d's butt position through buffer rod 1525r and buffer 1525n cooperation to make the relative installing support 1524's of skeleton 1523 angle change, and then inject back 1521 and skeleton 1523's turned angle alpha in certain rotation range.

As an implementation manner, one end of the third bracket 1524e is provided with a first clamping piece 1524c, and the other end of the third bracket 1524e is also provided with a first clamping piece 1524 c. One end of the fourth bracket 1524f is provided with a second clamping piece 1524g, and the other end of the fourth bracket 1524f is also provided with a second clamping piece 1524 g. Specifically, the first fastener 1524c is disposed on the lower side of the third bracket 1524e, and the second fastener 1524g is disposed on the lower side of the fourth bracket 1524 f. The first clip member 1524c is disposed at the front side of the second clip member 1524 g.

As shown in fig. 6, the mount assembly 16 includes a first mount 161, and the first mount 161 extends substantially in the left-right direction. First mount 161 is at least partially disposed between first main beam 1151 and second main beam 1152, with one end of first mount 161 attached to first main beam 1151 and the other end of first mount 161 attached to second main beam 1152. The first mounting bracket 161 is used to mount the backrest mechanism 152. Specifically, first mounting frame 161 includes a first mount 1611, a second mount 1612, a third mount 1613, and a first body 1614. First mount 1611, second mount 1612, and first body 1614 are all disposed on upper main beam 115. The third mount 1613 is disposed on the first body 1614. Specifically, a first mounting element 1611 and a second mounting element 1612 are disposed on first main beam 1151. A first mounting element 1611 and a second mounting element 1612 are also provided on second main beam 1152. The first body 1614 is at least partially disposed between the first main beam 1151 and the second main beam 1152. First mounting element 1611 is disposed forward of second mounting element 1612 in the fore-aft direction of atv 100. The first and second mounting sections 1611 and 1612 are spaced apart by a first distance in the front-rear direction, and the first and second clip members 1524c and 1524g are spaced apart by a second distance in the front-rear direction. The first distance and the second distance are substantially the same. Through the setting, can make first joint piece 1524c and first installed part 1611 joint, make second joint piece 1524g and second installed part 1612 joint to it is more convenient to make the connection of installing support 1524 and frame 11, and then realizes the connection of back mechanism 152 and frame 11, improves the dismouting convenience of back mechanism 152.

In this embodiment, the first clamping member 1524c may be a limiting steel wire, and the second clamping member 1524g may be a limiting pin. First mounting member 1611 is provided with a first mounting groove 1611a, and first mounting groove 1611a may be provided as an inclined groove. The second mounting member 1612 is provided with a mounting hole 1612 a. The first mounting groove 1611a includes a first end and a second end. Along the front-back and up-down directions of ATV 100, the first end is open, the opening is disposed upward, and the first end is located at the rear side of the second end. In actual installation, the position limiting steel wire can be clamped in from the opening of the first end until the position limiting steel wire abuts against the second end, that is, the position limiting steel wire can be clamped in the first installation groove 1611a from the opening of the first installation groove 1611 a. Through the setting, can make first installed part 1611 have the guide effect through the first mounting groove 1611a that sets up to the inclined groove to be convenient for spacing steel wire and the joint of first mounting groove 1611a, improve spacing steel wire's dismouting convenience. Second joint piece 1524g inserts in the mounting hole 1612a to realize the grafting of second joint piece 1524g and mounting hole 1612a, and through second joint piece 1524g and mounting hole 1612a, realize first mounting bracket 161 spacing to back mechanism 152. In the present embodiment, the first mounting element 1611 may be formed by welding two sheet metal parts together. Through above-mentioned setting, can increase the area of contact of first installed part 1611 and first joint spare 1524c to effectively prevent the wearing and tearing of first installed part 1611 and first joint spare 1524c, improve the life of first installed part 1611 and first joint spare 1524 c.

As shown in fig. 7-9, as one implementation, the backrest mechanism 152 further includes a locking mechanism 1526. A lock mechanism 1526 is disposed at least partially underneath the seat cushion 1522 and is coupled to the seat cushion 1522, and the lock mechanism 1526 is disposed at least partially over and coupled to the fourth bracket 1524 f. Specifically, a sixth mounting point 1524m and a seventh mounting point 1524n are disposed on the fourth support 1524 f. A sixth mounting point 1524m is at least partially disposed between the first retaining member 1525b and the second retaining member 1525c, and the sixth mounting point 1524m is configured to connect the fourth bracket 1524f and the locking mechanism 1526. Seventh mounting point 1524n is disposed forward of fourth bracket 1524f and forward of sixth mounting point 1524m, in the fore-aft direction of ATV 100. A seventh mounting point 1524n is used to connect the fourth bracket 1524f and the locking mechanism 1526. Through the above arrangement, the locking mechanism 1526 and the fourth bracket 1524f can be stably connected, so that the stability of the backrest mechanism 152 is improved, and the safety of the all-terrain vehicle 100 is further improved. An eighth mounting point 1522a and a plurality of ninth mounting points 1522b are provided on the underside of the seat cushion 1522. The eighth mounting point 1522a is disposed forward of the ninth mounting points 1522b, and the eighth mounting point 1522a and the ninth mounting points 1522b are disposed substantially along the same straight line. An eighth mounting point 1522a and a plurality of ninth mounting points 1522b are used to connect the seat cushion 1522 and the lock mechanism 1526. Through the above arrangement, the locking mechanism 1526 and the seat cushion 1522 can be stably connected, so that the stability of the backrest mechanism 152 is improved, and the safety of the all-terrain vehicle 100 is improved.

In one implementation, a third mount 1613 is disposed at least partially between the two second mounts 1612, the third mount 1613 being configured to couple to a locking mechanism 1526 to couple the mounting bracket 1524 to the first mount 161. The locking mechanism 1526 includes an unlocking device 1526a, a transmission 1526b and a locking device 1526 g. A transmission 1526b is provided between the unlocking means 1526a and the locking means 1526g for connecting the unlocking means 1526a and the locking means 1526 g. A transmission 1526b is connected to the underside of the seat cushion 1522 by a number of ninth mounting points 1522 b. The transmission 1526b is connected to the fourth bracket 1524f via a seventh mounting point 1524 n. Specifically, seventh mounting point 1524n can weld with fourth support 1524f, and seventh mounting point 1524n can be the sheet metal component that is provided with first draw-in groove, and transmission 1526b and seventh mounting point 1524n pass through first draw-in groove joint, and the dismouting of transmission 1526b of being convenient for improves transmission 1526 b's assembling nature. The ninth mounting points 1522b may be integrally formed with the seat cushion 1522, the ninth mounting points 1522b may be plastic members provided with second clamping grooves, and the transmission device 1526b and the ninth mounting points 1522b are clamped by the second clamping grooves. Through the setting, the integral type processing of ninth mounting point 1522b and cushion 1522 both can be convenient for, improve machining efficiency, transmission 1526 b's dismouting of can also being convenient for improves transmission 1526 b's assemblability.

The unlocking device 1526a is connected with the eighth mounting point 1522a, and the unlocking device 1526a is used for controlling the locking device 1526g through the transmission device 1526b, so that the locking device 1526g is unlocked or locked. A locking device 1526g is coupled to the third mounting element 1613, and the locking device 1526g is configured to couple the mounting bracket 1524 to the first mounting bracket 161, thereby coupling the first mounting bracket 161 to the backrest mechanism 152. Specifically, the locking device 1526g may be a hook, the third mounting element 1613 may be a snap ring, and the unlocking device 1526a controls a rotation angle of the hook through the transmission device 1526b, so as to lock or unlock the hook and the snap ring. Through the above arrangement, the connection between the backrest mechanism 152 and the first mounting bracket 161 can be more stable, and the convenience in mounting and dismounting the backrest mechanism 152 can be improved. In this embodiment, the locking mechanism 1526 includes a first state and a second state. In the first state, the locking device 1526g and the third mounting element 1613 are locked, i.e., the first state refers to a locked state of the locking mechanism 1526. In the second state, the locking device 1526g and the third mounting element 1613 are unlocked, i.e., the second state refers to the unlocked state of the locking mechanism 1526.

As one implementation, the transmission 1526b includes a first connection portion 1526c, a transmission portion 1526d, a second connection portion 1526e and an elastic member 1526 f. The first connection portion 1526c is connected to the unlocking device 1526 a. The transmission portion 1526d is used for connecting the first connection portion 1526c and the second connection portion 1526 e. The second connecting portion 1526e is used for connecting the transmission portion 1526d and the elastic member 1526 f. Specifically, one end of the first connecting portion 1526c is connected to the unlocking device 1526a, the other end of the first connecting portion 1526c is connected to one end of the transmission portion 1526d, the other end of the transmission portion 1526d is connected to one end of the second connecting portion 1526e, the other end of the second connecting portion 1526e is connected to one end of the elastic member 1526f, and the other end of the elastic member 1526f is connected to the locking device 1526 g. The elastic member 1526f may be a spring. Through the arrangement, the unlocking device 1526a can control the locking device 1526g to be unlocked or locked through the transmission device 1526b, so that the stable connection between the locking mechanism 1526 and the third mounting piece 1613 is realized, the stable connection between the backrest mechanism 152 and the first mounting frame 161 is further realized, the disassembly and assembly of the backrest mechanism 152 are facilitated, and the assembly performance of the backrest mechanism 152 is improved.

In this embodiment, when the locking mechanism 1526 is in the second state, the user can pull the unlocking device 1526a by hand, the unlocking device 1526a drives the transmission portion 1526d through the first connecting portion 1526c, and the transmission portion 1526d pulls the elastic member 1526f through the second connecting portion 1526e, so that the elastic member 1526f pulls the locking device 1526g, and the locking device 1526g is unlocked. At this time, the elastic member 1526f is in a stretched state. When the user releases the unlocking means 1526a, the locking mechanism 1526 returns to the first state due to the restoring force of the elastic member 1526 f. In this case, the backrest mechanism 152 may be connected to the first mounting frame 161 or may be in a detached state. When the backrest mechanism 152 is in the detached state, the locking mechanism 1526 is also in the locked state, i.e., the locking mechanism 1526 is in the first state.

As shown in fig. 10 and 11, as one implementation, the seat cushion 1522 is provided with an unlocking groove 1522e and a second mounting groove 1522 f. The opening of the unlocking groove 1522e is arranged at the front side of the seat cushion 1522, and the unlocking groove 1522e can be used for the hand of a user to enter the interior of the seat cushion 1522, so that the user can conveniently control the unlocking device 1526 a. The opening of second mounting groove 1522f is disposed in front of seat pad 1522, and saddle 151 is at least partially disposed in second mounting groove 1522f, thereby reducing the clearance between saddle 151 and seat pad 1522, being favorable for improving the mounting stability of backrest mechanism 152, and making the structure of all-terrain vehicle 100 more compact. The unlocking groove 1522e and the second mounting groove 1522f communicate, and the unlocking groove 1522e is disposed on the upper side of the second mounting groove 1522 f.

As shown in fig. 9 and 10, in the present embodiment, the unlocking means 1526a includes an unlocking handle 1526h and a connecting plate 1526 j. The unlocking handle 1526h is used for unlocking the locking device 1526g, and the connecting plate 1526j is used for connecting the unlocking handle 1526h and the transmission device 1526 b. The unlocking handle 1526h may be a pull rod, a pull belt, or the like. The unlock handle 1526h includes an unlocked position. When the unlocking handle 1526h is a pull rod, the unlocking handle 1526h and the connecting plate 1526j are integrally formed, the pull rod extends substantially in the left-right direction of the all-terrain vehicle 100, and the pull rod is substantially cylindrical. The distance between the axis of the tie rod and the front side of the uppermost end of the unlocking slot 1522e in the front-rear direction of the atv 100 is L. The distance between the axis of the drawbar and the uppermost front side of the unlocking slot 1522e in the up-down direction of the atv 100 is H. Wherein, the position that the axis of pull rod is located is the unblock position. In this embodiment, in the front-rear direction of the atv 100, if the unlocking handle 1526h is at least partially located at the front side of the unlocking slot 1522e, L is a negative number; the unlocking handle 1526h is at least partially located at the rear side of the unlocking slot 1522e, and L is a positive number. The value range of L is more than or equal to-20 mm and less than or equal to 150 mm. In the up-down direction of the all-terrain vehicle 100, if the unlocking handle 1526H is at least partially positioned at the upper side of the unlocking groove 1522e, H is a negative number; h is a positive number if the unlocking knob 1526H is at least partially located on the lower side of the unlocking slot 1522 e. The value range of H is more than or equal to-20 mm and less than or equal to 20 mm. Specifically, the value range of L is more than or equal to 10mm and less than or equal to 110mm, and the value range of H is more than or equal to-15 mm and less than or equal to 15 mm. In the present embodiment, L has a value range of 30mm or more and 80mm or less, and H has a value range of-10 mm or more and 10mm or less. Through the above arrangement, the locking mechanism 1526 can be made to avoid other parts on the seat cushion 1522, so that the space utilization rate of the seat cushion 1522 is improved, and the space utilization rate of the all-terrain vehicle 100 is further improved.

It is understood that when the unlocking handle 1526h is a pull strap or the like, the connection point between the unlocking handle 1526h and the connecting plate 1526j is a connection point. Wherein, the position of the connecting point is the unlocking position. The distance between the attachment point and the uppermost front side of the unlocking slot 1522e in the front-rear direction of the atv 100 is L'. The distance between the attachment point and the uppermost front side of the unlocking slot 1522e in the up-down direction of the atv 100 is H'. The value ranges of L 'and L are basically consistent, and the value ranges of H' and H are basically consistent. Through the above arrangement, the locking mechanism 1526 can be made to avoid other parts on the seat cushion 1522, so that the space utilization rate of the seat cushion 1522 is improved, and the space utilization rate of the all-terrain vehicle 100 is further improved.

As shown in fig. 12, as one implementation, the mounting bracket assembly 16 includes a second mounting bracket 162, the second mounting bracket 162 being at least partially disposed on the frame 11 and coupled to the frame 11. The second mounting bracket 162 has adjustability, and can adjust the assembly tolerance of the parts of the all-terrain vehicle 100, thereby fixing the parts of the all-terrain vehicle 100 and improving the assembly stability of the all-terrain vehicle 100. Specifically, the second mounting bracket 162 may be disposed on the seventh pipe 1133 for fixing the fuel assembly 21. A second mounting bracket 162 may also be provided on mounting bracket assembly 16 for securing the remaining components of atv 100. With the above arrangement, stable connection of the components of the all-terrain vehicle 100 can be achieved. The second mounting bracket 162 includes an adjuster 1621 and a second body 1622. An adjustment member 1621 is disposed at least partially on second body 1622 for adjusting assembly tolerances of components of atv 100. The second body 1622 is at least partially disposed on the frame 11 for connecting the frame 11 and the second mounting bracket 162. Specifically, the second body 1622 includes a first mounting portion 1622a, a first fixing portion 1622b, and an adjusting portion 1622 d. The adjusting portion 1622d is disposed on the first mounting portion 1622a, and the adjusting portion 1622d and the first mounting portion 1622a are integrally formed. The first fixing portion 1622b may be welded to one end of the first mounting portion 1622 a. In this embodiment, the adjusting portion 1622d may be configured as a mounting groove, and the adjusting member 1621 is disposed in the mounting groove, so that the adjusting member 1621 may slide in the adjusting portion 1622d, thereby facilitating adjustment of assembly tolerance of the components of the all-terrain vehicle 100. The first mounting portion 1622a is used for connecting the frame 11 and the second body 1622, and the first fixing portion 1622b is used for fixing the components of the all-terrain vehicle 100. Specifically, one end of the first mounting portion 1622a is connected to the first fixing portion 1622b, and the other end of the first mounting portion 1622a is connected to the frame 11. The adjusting part 1622d is used for disposing the adjusting member 1621, and the adjusting part 1622d and the adjusting member 1621 are connected in a sliding manner, that is, the adjusting member 1621 can slide in the adjusting part 1622 d. Through the arrangement, when the parts of the all-terrain vehicle 100 are installed, the position of the adjusting piece 1621 can be adjusted in real time according to the installation condition of the parts, so that the stable installation of the parts is realized, and the assembly performance of the all-terrain vehicle 100 is improved.

As one implementation, the adjusting member 1621 includes a second mounting portion 1621a and a second fixing portion 1621 b. The second mounting portion 1621a is at least partially disposed on the adjustment portion 1622d, and the second mounting portion 1621a and the adjustment portion 1622d are slidably coupled, i.e., the second mounting portion 1621a can slide in the adjustment portion 1622 d. Second fixing portion 1621b is disposed substantially parallel to first fixing portion 1622b to facilitate fixing of components of atv 100. Specifically, a first mounting hole 1622c is formed on the first fixing portion 1622b, a second mounting hole 1621c is formed on the second fixing portion 1621b, and a cross-sectional area of the first mounting hole 1622c is larger than that of the second mounting hole 1621 c. In this embodiment, the second mounting hole 1621c is substantially circular in cross-section. The second mounting bracket 162 includes a first projection plane 1623 perpendicular to an axis of the second mounting hole 1621 c. Along the axial direction of the second mounting hole 1621c, the projection of the first mounting hole 1622c on the first projection plane 1623 is a first projection plane, and the projection of the second mounting hole 1621c on the first projection plane 1623 is a second projection plane. The area of the first projection surface is larger than that of the second projection surface, and the second projection surface is positioned in the first projection surface, namely the first projection surface completely covers the second projection surface. Through the arrangement, when the parts of the all-terrain vehicle 100 have assembly errors, the relative positions of the second mounting part 1621a and the first mounting part 1622a can be adjusted in real time, so that the parts of the all-terrain vehicle 100 can be better mounted through the second mounting hole 1621c, and the assembly performance of the parts of the all-terrain vehicle 100 is improved.

In this embodiment, the first mounting hole 1622c may be a through hole, and only the cross-sectional area of the first mounting hole 1622c needs to be larger than that of the second mounting hole 1621 c. The second mounting hole 1621c may be a threaded hole for facilitating fixing of the components of the all-terrain vehicle 100 by bolts or the like; second mounting hole 1621c may also be a through hole to facilitate securing components of atv 100 via an interference fit or the like.

When the second mounting hole 1621c is a threaded hole, the lower surface of the second fixing portion 1621b is provided with a first nut, the lower surfaces of the first and second fixing portions 1621b may be fixed by welding or the like, and the second mounting hole 1621c penetrates through the second fixing portion 1621b and the first nut, so that it is convenient to fix the components of the all-terrain vehicle 100 by bolts or the like. The lower surface of the second fixing portion 1621b refers to a surface of the second fixing portion 1621b away from the first mounting hole 1622 c.

As one implementation, the second mounting portion 1621a and the second fixing portion 1621b are integrally formed. Both ends of the second fixing portion 1621b are provided with second mounting portions 1621 a. The adjusting part 1622d includes a first mounting groove and a second mounting groove. The first mounting groove and the second mounting groove are arranged substantially in parallel. The second mounting portion 1621a of one end of the second fixing portion 1621b is at least partially disposed in the first mounting groove. The second mounting portion 1621a at the other end of the second fixing portion 1621b is at least partially disposed in the second mounting groove.

Specifically, the first mounting portion 1622a includes a first side plate 1622e, a second side plate 1622f, and a first main plate 1622 g. One side of the first side plate 1622e is connected to one side of the first main plate 1622g, and the first side plate 1622e and the first main plate 1622g are substantially vertically disposed. One side of the second side plate 1622f is connected to the other side of the first main plate 1622g, and the second side plate 1622f and the first main plate 1622g are substantially vertically disposed. The adjusting portion 1622d is disposed on the first side plate 1622e and the second side plate 1622f, that is, a first mounting groove is disposed on the first side plate 1622e, and a second mounting groove is disposed on the second side plate 1622 f. The first mounting plate is disposed substantially perpendicular to the first side plate 1622e and the second mounting plate is disposed substantially perpendicular to the second side plate 1622 f. Through the arrangement, the first mounting plate can better slide in the first mounting groove, and the second mounting plate can better slide in the second mounting groove, so that the assembly tolerance of the parts of the all-terrain vehicle 100 can be adjusted conveniently, and the assembly performance of the all-terrain vehicle 100 is improved.

In the present embodiment, the first side plate 1622e, the second side plate 1622f, and the first main plate 1622g are all provided with lightening holes, which facilitates the lightening of the second mounting bracket 162, and thus the lightening of the all-terrain vehicle 100. In addition, still be provided with a plurality of mounting point on the first mainboard 1622g, the mounting point is used for connecting first mainboard 1622g and frame 11 to make the connection of second mounting bracket 162 and frame 11 more stable.

As shown in fig. 13 and 14, the mount assembly 16 further includes a third mount 163, as one implementation. The third mounting bracket 163 is disposed at least partially on the frame 11 for fixing components of the atv 100 and limiting the rotation or movement of the components of the atv 100, thereby fixing and limiting the components of the atv 100. Specifically, the third mounting bracket 163 includes a third mounting portion 1631 and a first limiting portion 1632. The first limiting portion 1632 is at least partially disposed on the third mounting portion 1631, and the third mounting portion 1631 is at least partially disposed on the frame 11 and connected to the frame 11. The third mounting portion 1631 and the first limiting portion 1632 may be integrally formed; the first limiting portion 1632 may also be connected to the third mounting portion 1631 by welding, screwing, or the like, so that the first limiting portion 1632 and the third mounting portion 1631 are stably connected. In this embodiment, the third mounting bracket 163 may be formed separately, i.e., the third mounting bracket 163 may be provided as a separate component for connecting the components of the ATV 100 and the frame 11. Third mounting bracket 163 may also be coupled to other mounting bracket assemblies 16 for coupling other mounting bracket assemblies 16 to components of atv 100. In this case, the third mounting bracket 163 and the other mounting bracket assembly 16 may be integrally formed, or may be connected by welding, bolting, or the like. Wherein the third mounting bracket 163 is disposed on the frame 11 and coupled to the frame 11 when the third mounting bracket 163 is separately molded. When the third mounting bracket 163 is coupled to the other mounting bracket assembly 16, the third mounting bracket 163 is at least partially disposed on the other mounting bracket assembly 16, and the third mounting bracket 163 is coupled to the frame 11 via the other mounting bracket assembly 16.

It can be understood that the third mounting portion 1631 is provided with a third mounting hole 1633, and the third mounting hole 1633 is used for connecting parts of the all-terrain vehicle 100, so that the third mounting hole 1633 and the first limiting portion 1632 fix the parts of the all-terrain vehicle 100 at the same time, and the mounting stability of the all-terrain vehicle 100 is further improved. The third mounting hole 1633 may also serve as a connection point between the frame 11 and the third mounting frame 163, so as to integrate mounting points of other components of the atv 100 and the frame 11, that is, to integrate a plurality of mounting points on the third mounting frame 163, thereby simplifying the structure of the third mounting frame 163, making the structure of the third mounting frame 163 more compact, and improving the structural compactness of the mounting frame assembly 16.

In one implementation, at least a portion of the components of atv 100 and first limiting portion 1632 are in surface contact and/or line contact. Through the arrangement, the first limiting portion 1632 can limit the parts of the all-terrain vehicle 100 more stably, so that the parts of the all-terrain vehicle 100 are limited from rotating or moving, the abrasion of the parts of the all-terrain vehicle 100 is reduced, and the service life of the parts of the all-terrain vehicle 100 is prolonged. In addition, through the arrangement, the assembly performance of the parts of the all-terrain vehicle 100 can be improved, and the parts of the all-terrain vehicle 100 can be conveniently mounted or dismounted.

As one implementation, when the third mounting bracket 163 is a separate part, the third mounting bracket 163 includes a fourth mounting portion 1634 and a second stopper portion 1635. The second limiting portion 1635 is at least partially disposed on the fourth mounting portion 1634, and the second limiting portion 1635 may be integrally formed with the fourth mounting portion 1634, or may be connected to the fourth mounting portion 1634 by welding or bolting. The second limiting portion 1635 may be a first protruding block, the first protruding block at least includes a first plane, the components of the atv 100 at least includes a second plane, and the first plane and the second plane are abutted to make at least a part of the components of the atv 100 form surface contact with the first limiting portion 1632, so that the second limiting portion 1635 can limit the components of the atv 100. Specifically, the fourth mounting portion 1634 is further provided with a fourth mounting hole 1636, and the fourth mounting hole 1636 is used for connecting parts of the all-terrain vehicle 100, so that the fourth mounting hole 1636 and the second limiting portion 1635 fix the parts of the all-terrain vehicle 100 at the same time, and the mounting stability of the all-terrain vehicle 100 is further improved. In this embodiment, the fourth mounting hole 1636 may also be used to connect the fourth mounting portion 1634 and the frame 11, that is, the fourth mounting hole 1636 may be used as a mounting hole for a component of the all-terrain vehicle 100 and a connection hole for connecting the frame 11, so as to integrate a plurality of mounting points, thereby achieving stable connection between the third mounting frame 163 and the frame 11. In addition, by integrating the mounting points, the volume of the third mounting bracket 163 is saved, thereby improving the compactness of the third mounting bracket 163 and thus the compactness of the atv 100.

In the present embodiment, the fourth mounting portion 1634 includes a first plate and a second plate. The first and second plates are substantially vertically disposed and integrally formed, so that the fourth mounting portion 1634 can be better connected to the frame 11, and the stability of the fourth mounting portion 1634 is improved. Specifically, a fourth mounting hole 1636 and a second limiting portion 1635 are provided on the first plate.

As one implementation, the brake assembly 17 includes a three-way mechanism 171 and a brake pipe (not shown in the figures). Brake fluid is filled in the brake pipeline. The three-way mechanism 171 is communicated with the brake pipes, and is used for connecting a plurality of brake pipes and shunting the brake fluid in the brake pipes. When the third mounting bracket 163 is a separate component, the component provided on the third mounting bracket 163 may be the three-way mechanism 171. The three-way mechanism 171 and the third mounting bracket 163 are connected through the fourth mounting hole 1636, and the three-way mechanism 171 and the third mounting bracket 163 are abutted through the second limiting part 1635, so that the three-way mechanism 171 is fixed and limited.

It can be understood that the second limiting portion 1635 may also be a first protrusion, a first limiting hole is disposed on a component of the all-terrain vehicle 100, and the first limiting hole is sleeved on the first protrusion, so that at least a part of the component of the all-terrain vehicle 100 and the first limiting portion 1632 form surface contact, and the second limiting portion 1635 can limit the component of the all-terrain vehicle 100. Specifically, the contour of the outer surface of the first protrusion is substantially identical to the contour of the inner surface of the first limiting hole, so that the outer surface of the first protrusion is substantially attached to the inner surface of the first limiting hole, and the first limiting hole is in surface contact with the first limiting portion 1632. In this embodiment, the first protrusion may be a cylinder, and the first position-limiting hole is sleeved on the cylinder, so that the first position-limiting hole and the cylinder form a surface contact. Wherein, the inner surface of the first limit hole refers to the inner wall of the first limit hole; the shape of the first protrusion can also be a cuboid, a cone and the like, and the requirement that the outline of the outer surface of the first protrusion is basically consistent with the outline of the inner surface of the first limiting hole can be met.

As one implementation, when the third mounting bracket 163 is connected to the other mounting bracket assembly 16, the third mounting bracket 163 includes a fifth mounting portion 1637 and a third limiting portion 1638. The third limiting portion 1638 is at least partially disposed on the fifth mounting portion 1637, and the third limiting portion 1638 may be integrally formed with the fifth mounting portion 1637, or may be connected to the fifth mounting portion 1637 by welding or bolting. The third limiting portion 1638 may be a second protrusion, so that the third limiting portion 1638 limits the components of the atv 100. Specifically, the fifth mounting portion 1637 is further provided with a fifth mounting hole 1639, and the fifth mounting hole 1639 is used for connecting parts of the all-terrain vehicle 100, so that the fifth mounting hole 1639 and the third limiting portion 1638 fix the parts of the all-terrain vehicle 100 at the same time, and the mounting stability of the all-terrain vehicle 100 is further improved. In this embodiment, the fifth mounting hole 1639 may also be used to connect the fifth mounting hole 1639 and the frame 11, that is, the fifth mounting hole 1639 may be used as a mounting hole for a component of the all-terrain vehicle 100 and a connection hole for connecting the frame 11, so as to achieve integration of multiple mounting points.

In the present embodiment, the electrical component 18 is provided with a sixth mounting hole 181 and a second stopper hole 182. The sixth mounting hole 181 and the fifth mounting hole 1639 may be connected by bolts, welding, or the like, thereby connecting the electrical component 18 and the third mounting bracket 163. Specifically, the second limiting hole 182 is sleeved on the third limiting portion 1638, that is, the second limiting hole 182 is sleeved on the second protrusion, so that the second limiting hole 182 and the third limiting portion 1638 are fixed, and the third limiting portion 1638 fixes and limits the electrical component 18. Specifically, the second protrusion may be a hemisphere, the cross section of the second limiting hole 182 is substantially circular, and the diameter of the cross section of the second limiting hole 182 is substantially the same as the diameter of the second protrusion, so that the second limiting hole 182 and the second protrusion form a line contact, and the second protrusion and the second limiting hole 182 are more stably sleeved. In this embodiment, the second protrusion may have other shapes, and it is only necessary that the second protrusion and the second limiting hole 182 form a line contact.

It is understood that the third position-limiting portion 1638 may also be a second protrusion, the second protrusion includes at least a third plane, the component of the atv 100 includes at least an edge, and the third plane of the second protrusion abuts against the edge of the component of the atv 100, so that the component of the atv 100 and the third position-limiting portion 1638 form a line contact, thereby facilitating the position limitation of the component of the atv 100 by the second position-limiting portion 1635. Specifically, the edge of the component of the all-terrain vehicle 100 may be one edge of the component of the all-terrain vehicle 100, the joint between the third plane and the fifth mounting portion 1637 is the first abutting position, and the edge of the component of the all-terrain vehicle 100 abuts against the first abutting position, so that the edge of the component of the all-terrain vehicle 100 abuts against the third plane of the second bump, and the edge of the component of the all-terrain vehicle 100 forms a line contact with the third limiting portion 1638.

As shown in fig. 15 and 16, mount assembly 16 further includes, as one implementation, a sixth mount 169. Sixth mounting bracket 169 is disposed at least partially on frame 11 and drive assembly 26 is disposed at least partially on frame 11 via sixth mounting bracket 169. Specifically, sixth mount 169 includes rear axle support 1691 and power support 1692. Rear axle bracket 1691 is disposed at least partially on frame 11 for securing at least a portion of drive assembly 26. Power bracket 1692 is at least partially disposed on frame 11 for securing a power outlet. The power receptacle is disposed at least partially on the power bracket 1692 for providing an output interface for trailer power.

In this embodiment, rear axle bracket 1691 is disposed at least partially on fourth strut 114 and power bracket 1692 is also disposed at least partially on fourth strut 114. Rear axle bracket 1691 is disposed on the front side of fourth pillar 114 and power bracket 1692 is disposed on the rear side of fourth pillar 114 in the fore-aft direction of atv 100. Specifically, the ninth pipe 1141 has a first connection hole 1143, and the tenth pipe 1142 has a first connection hole 1143. First attachment aperture 1143 extends substantially in the fore-aft direction of atv 100. A bushing is provided in the first connection hole 1143, thereby improving the friction resistance and the lifespan of the first connection hole 1143. The rear axle bracket 1691 is provided with a second coupling hole 1691a, and the power supply bracket 1692 is provided with a third coupling hole 1692 a. The second coupling hole 1691a is coupled to the first coupling hole 1143, and the third coupling hole 1692a is coupled to the first coupling hole 1143, thereby stably coupling the rear axle bracket 1691 to the fourth support 114 and stably coupling the power supply bracket 1692 to the fourth support 114. The positions of first connecting hole 1143, second connecting hole 1691a and third connecting hole 1692a are basically consistent, namely, the circle center of first connecting hole 1143, the circle center of second connecting hole 1691a and the circle center of third connecting hole 1692a are basically located on the same straight line, so that first connecting hole 1143, second connecting hole 1691 and third connecting hole 1692a can be fixed through the same connecting piece, that is, the mounting point of rear axle support 1691 and the mounting point of power support 1692 are integrated together, thereby improving the assembly performance of all-terrain vehicle 100, reducing the number of parts of all-terrain vehicle 100 and further realizing the light weight of all-terrain vehicle 100. In the present embodiment, the first coupling hole 1143, the second coupling hole 1691a, and the third coupling hole 1692a may be fixed by the same bolt. The first connecting hole 1143, the second connecting hole 1691a and the third connecting hole 1692a are fixed as follows: the bolts pass through the third connecting hole 1692a, the first connecting hole 1143 and the second connecting hole 1691a in sequence and are fixed by nuts, so that the fourth supporting column 114, the rear axle support 1691 and the power supply support 1692 are stably connected.

It can be understood that the bolts may also be fixed by nuts after passing through the second connecting holes 1691a, the first connecting holes 1143, and the third connecting holes 1692a in sequence, thereby achieving stable connection of the fourth supporting column 114, the rear axle bracket 1691, and the power supply bracket 1692.

In one implementation, the power bracket 1692 includes a first mounting portion 1692b, a connecting portion 1692c, and a second mounting portion 1692d thereon. The first mounting portion 1692b and the second mounting portion 1692d are connected by a connecting portion 1692 c. Specifically, the first mounting portion 1692b is disposed on the upper side of the second mounting portion 1692d in the up-down direction of the atv 100. The first and second mounting portions 1692b and 1692d extend substantially in the up-down direction of the atv 100, and the connecting portion 1692c extends substantially in the front-rear direction of the atv 100. The lower end of the first mounting portion 1692b is connected to the front end of the connecting portion 1692c, and the upper end of the second mounting portion 1692d is connected to the rear end of the connecting portion 1692 c. The first mounting portion 1692b, the connecting portion 1692c, and the second mounting portion 1692d are integrally formed. In the present embodiment, the first mounting portion 1692b is provided with third coupling holes 1692a, and the second mounting portion 1692d is provided with fourth coupling holes 1692e and lightening holes 1692 f. A lightening hole 1692f is provided at a central position of the second mounting portion 1692d, and a fourth coupling hole 1692e is provided around the lightening hole 1692 f. The lightening holes 1692f are used to reduce the weight of the second mounting portion 1692d, thereby achieving a light weight of the all-terrain vehicle 100. The fourth coupling hole 1692e is for coupling a power socket.

It will be understood that modifications and variations are possible to those skilled in the art in light of the above teachings and that all such modifications and variations are considered to be within the purview of the invention as set forth in the appended claims.

Claims (10)

1. An all-terrain vehicle comprising:

a frame;

the walking assembly is at least partially arranged on the frame and comprises a first walking wheel and a second walking wheel;

a suspension assembly including a front suspension and a rear suspension, the first road wheel being connected to the frame through the front suspension, the second road wheel being connected to the frame through the rear suspension;

a power assembly at least partially disposed on the frame;

the transmission assembly is connected with the walking assembly and the power assembly;

a mount assembly at least partially disposed on the frame;

it is characterized in that the preparation method is characterized in that,

the mount assembly includes:

the rear axle bracket is at least partially arranged on the frame and used for fixing at least part of the transmission assembly;

a power bracket at least partially disposed on the frame;

the frame comprises a strut, the strut is arranged on the rear side of the frame, and the strut is provided with a first connecting hole;

the rear axle support is connected with the support column through the first connecting hole, and the power supply support is also connected with the support column through the first connecting hole.

2. The all-terrain vehicle of claim 1, characterized in that the axis of the first connection hole extends substantially in a fore-aft direction of the all-terrain vehicle.

3. The all-terrain vehicle of claim 1, characterized in that a second attachment hole is provided in the rear axle bracket, the second attachment hole and the first attachment hole being connected by the same connector.

4. The all-terrain vehicle of claim 3, characterized in that a third attachment hole is provided in the power source bracket, the third attachment hole and the first attachment hole being connected by the same connector.

5. The all-terrain vehicle of claim 4, characterized in that a center of the first connection hole, a center of the second connection hole, and a center of the third connection hole are substantially collinear.

6. The all-terrain vehicle of claim 1, characterized in that a bushing is disposed in the first connection aperture.

7. The all-terrain vehicle of claim 4, characterized in that the power bracket comprises a first mounting portion, a connecting portion, and a second mounting portion, the first mounting portion and the second mounting portion being connected by the connecting portion, the first mounting portion being disposed on an upper side of the second mounting portion.

8. The all-terrain vehicle of claim 7, characterized in that the first mounting portion and the second mounting portion extend substantially in an up-down direction of the all-terrain vehicle, and the connecting portion extends substantially in a front-to-rear direction of the all-terrain vehicle.

9. The all-terrain vehicle of claim 7, characterized in that the first mounting portion is provided with the third attachment aperture.

10. The all-terrain vehicle of claim 7, characterized in that the second mounting portion is provided with a fourth attachment hole and a lightening hole, the lightening hole being provided at a central position of the second mounting portion, the fourth attachment hole being provided around the lightening hole.

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