CN213057314U - Two-in-one scooter for children - Google Patents

Abstract

A two-in-one child scooter comprises a scooter body, a handle assembly and a connecting frame, wherein the upper surface of the scooter body is provided with a first cavity, the handle assembly is connected to the scooter body, the connecting frame is arranged on the handle assembly in an axial reciprocating sliding mode, the dual-purpose bearing mechanism comprises a turning plate assembly and a supporting piece, the turning plate assembly is transversely arranged, the front end of the turning plate assembly is rotatably arranged on the connecting frame, one end of the supporting piece is hinged with the turning plate assembly, the turning plate assembly is provided with a pedal surface provided with a second cavity and a riding surface opposite to the pedal surface, and the supporting piece can swing up and down to be; the dual-purpose bearing mechanism is under the slide state, turns over the board subassembly and holds in first cavity and pedal face up, and support piece sets up along horizontal and support piece holds in the second cavity, and dual-purpose bearing mechanism is under riding the seat state, turns over the board subassembly and hangs in first cavity top and make and ride the seat face up, and support piece sets up along vertical and its other end inserts and locates in first cavity. The utility model relates to a two unification children's scooter is difficult to lose the cushion accessory.

Description

Two-in-one scooter for children

Technical Field

The utility model relates to a scooter technical field especially relates to a two unification children's scooter that not only can stand and ride but also can ride and sit and slide.

Background

The scooter is a novel transportation tool integrating leisure, entertainment and walking, and has the advantages of small volume, light weight, moderate speed, low manufacturing cost, simple operation and the like. However, for beginners or younger children, the scooter is difficult to operate skillfully, and long-time standing riding is easy to fatigue, so that the beginners or the younger children fall down, and great potential safety hazards exist.

In order to solve the problem, chinese utility model patent that patent number is ZL201820983561.1 (the grant bulletin number is CN208439370U) discloses a dual-purpose scooter of rotation type, including switching portion, dual-purpose portion, straight-bar and the handle of taking advantage of carrying, dual-purpose portion of bearing includes the running-board, running-board front end fixedly connected with connecting rod, be equipped with one on the running-board and be used for pedal tread, can dismantle one side of the pedal tread back to pedal and be equipped with the cushion, the fixed spliced pole that is equipped with in the switching portion, spliced pole side is opened there are two mounting holes, is equipped with the elastic button in the mounting hole, the fixed adapter sleeve that is equipped with on the connecting rod, spliced pole and adapter sleeve rotate and be connected, are equipped with.

Above-mentioned dual-purpose scooter of rotation type is when the pedal face of running-board is up, the cushion is not installed, and this scooter supplies to stand as the scooter and rides, through rotatory 180 degrees and when installing the cushion in the running-board top with dual-purpose supporting part, this scooter supplies to ride and sits to slide as the scooter. However, when the service state of the scooter is switched, the rotary dual-purpose scooter needs to be detached or mounted with a cushion, the function switching operation is complicated, and the detached cushion is inconvenient to store and easy to lose, so that the rotary dual-purpose scooter needs to be improved.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that to foretell technical current situation and provide a two unification children's scooter, the cushion need not the installation or dismantles in the function switching operation, is difficult to lose the cushion accessory.

The utility model provides a technical scheme that above-mentioned technical problem adopted does: a two-in-one children scooter comprises:

a vehicle body;

a handle assembly connected to the vehicle body;

it is characterized by also comprising a step of,

the connecting frame is arranged on the handle assembly in an axially reciprocating sliding manner;

the dual-purpose bearing mechanism comprises a turning plate assembly and a supporting piece, wherein the turning plate assembly is transversely arranged, one end of the supporting piece is hinged with the turning plate assembly, the front end of the turning plate assembly is rotatably arranged on the connecting frame and can turn over by 180 degrees up and down, the turning plate assembly is provided with a pedal surface provided with a second cavity and a riding surface opposite to the pedal surface, the upper surface of the vehicle body is provided with a first cavity, and the supporting piece can swing up and down to be accommodated in the second cavity or the other end of the supporting piece is inserted into the first cavity;

the dual-purpose bearing mechanism comprises a first cavity, a second cavity, a first turning plate assembly, a second turning plate assembly, a support piece, a second cavity, a support piece, a first support piece, a second support piece, a first support piece and a second support piece, wherein the first cavity is used for accommodating a pedal, the second cavity is used for accommodating the pedal, the first support piece is used for supporting the pedal, the second cavity is used for supporting the dual-purpose bearing mechanism, the second cavity is used for accommodating the pedal, the first cavity is used for accommodating the turning plate assembly, the second cavity is used for accommodating the support piece, the second cavity is used for accommodating the pedal, the first cavity.

The transverse direction refers to a direction extending from front to back on the whole, and can be a horizontal direction or a direction having a certain inclination relative to the horizontal direction; the longitudinal direction refers to a direction extending from top to bottom as a whole, and may be a vertical direction or a direction having a certain inclination with respect to the vertical direction.

The function switching locking structure comprises a first locking structure used for locking or unlocking the state that the supporting piece is accommodated in the second cavity, a second locking structure used for allowing the turning plate assembly to be separated from the first cavity when the dual-purpose bearing mechanism is in a sliding plate state, a third locking structure used for allowing the connecting frame to axially slide along the handle assembly when the dual-purpose bearing mechanism is in a riding state, and a fourth locking structure used for allowing the turning plate assembly to turn when the dual-purpose bearing mechanism is in the riding state.

When the two bearing mechanisms are switched from the sliding plate state to the riding state, the second locking structure is unlocked to allow the turning plate assembly to be separated from the first cavity, the connecting frame is moved upwards along the axial direction of the handle assembly to drive the dual-purpose bearing mechanism to move upwards in the axial direction and be suspended above the first cavity, the first locking structure is unlocked to allow the support piece to swing downwards until the other end of the support piece is inserted into the first cavity, the axial position of the dual-purpose bearing mechanism relative to the handle assembly is locked through the third locking structure, and the riding state of the dual-purpose bearing mechanism is locked through the fourth locking structure; when the two bearing mechanisms are switched to the sliding plate state from the riding state, the support piece is swung upwards to the support piece to be accommodated in the second cavity, the fourth locking structure is unlocked to allow the turnover plate assembly to turn over, then the support piece is locked to be accommodated in the second cavity through the first locking structure, the third locking structure is unlocked to allow the connecting frame to axially slide, then the connecting frame is moved downwards axially to drive the dual-purpose bearing mechanism to axially move downwards to be accommodated in the first cavity, and finally the turnover plate assembly is locked to be accommodated in the first cavity through the second locking structure, so that the switching is completed.

In order to be able to swing the support up and down when the flap assembly is suspended above the first cavity, the first locking structure comprises

The first slot is arranged at the end part of the other end of the supporting piece;

the threaded part is arranged at the front end of the turning plate component;

the threaded sleeve is in threaded connection with the threaded part and is arranged in the connecting frame in a manner of sliding back and forth;

the first locking piece is constrained on the threaded sleeve and can be arranged on the side wall of the second cavity in a penetrating manner in a front-back sliding manner, and the first locking piece can be inserted into the first slot;

and the first elastic piece is used for enabling the first locking piece to always have the tendency of being inserted into the first slot.

In order to make the constraint structure between the threaded sleeve and the first locking piece simpler, a cavity is arranged inside the threaded part, a connecting rod is arranged in the cavity in a penetrating mode in a sliding mode, the front end of the connecting rod is fixed with the threaded sleeve through a fastener, a limiting convex part is arranged at the rear end of the connecting rod, and a limiting blocking part which is abutted to the front surface of the limiting convex part is arranged on the first locking piece.

In order to lock the state that the flap assembly is accommodated in the first cavity or allow the flap assembly to be out of the first cavity, the second locking structure comprises

The second locking piece can be arranged on the side wall of the first cavity in a penetrating way in a reciprocating way;

the second slot is arranged on the side wall of the turning plate component and is used for the second locking piece to insert;

the second elastic piece enables the second locking piece to always have a movement trend of moving towards the first cavity;

the first key is hinged on the vehicle body and can swing up and down, and the downward swing of the first key can drive the second locking piece to be far away from the first cavity;

the first inserting part is convexly arranged on the bottom wall of the first concave cavity;

and the third slot is arranged on the riding surface of the turning plate component and is used for the first inserting part to insert.

In order to enable the other end of the supporting piece to be stably inserted into the first cavity when the dual-purpose bearing mechanism is in a riding state, the supporting piece is provided with a first surface capable of being hidden in the second cavity and a second surface always exposed on the turning plate assembly, the first slot is arranged on the first surface, and the first inserting part can be inserted into the first slot; the second surface of the supporting piece is provided with a fourth slot for the second locking piece to be inserted into, and the fourth slot is close to the end part of the other end of the supporting piece.

In order to position the axial position of the dual-purpose bearing mechanism when the flap assembly is suspended above the first cavity, the third locking structure comprises a second insertion part and a positioning hole for the second insertion part to be inserted, the second insertion part is arranged at the front end of the threaded sleeve and can be arranged on the front surface of the connecting frame in a penetrating manner in a front-back sliding manner, and the positioning hole penetrates through the peripheral wall of the handle assembly.

In order to be able to turn the flap assembly up and down when the flap assembly is suspended above the first cavity, the fourth locking structure comprises

The third locking piece can be arranged on the front surface of the turning plate component in a penetrating way in a front-and-back sliding way;

the lock hole penetrates through the connecting frame and is used for inserting the front end of the third locking piece;

the third elastic piece enables the third locking piece to always have a forward movement trend;

the second key can be arranged in front of and behind the lock hole in a penetrating way;

the fourth elastic piece enables the second key to always have a forward movement trend and be exposed on the front surface of the connecting frame;

the third locking piece is abutted to the connecting frame when the pedal face of the turning plate assembly faces upwards, the third locking piece and the lock hole are correspondingly arranged on two sides of the rotating axis of the turning plate assembly, and the front end of the third locking piece is inserted into the lock hole when the riding surface of the turning plate assembly faces upwards.

In order to enable the connecting frame to drive the dual-purpose bearing mechanism to axially move upwards along a preset track, a rib groove inserting and matching guide structure is arranged between the connecting frame and the handle assembly and comprises a convex rib and a guide groove, the convex rib is arranged on the inner side wall of the connecting frame and one of the outer peripheral wall of the handle assembly, and the guide groove is arranged on the inner side wall of the connecting frame and the other of the outer peripheral wall of the handle assembly.

In order to limit the range of the connecting frame moving upwards along the axial direction of the handle assembly, a stopping structure used for limiting the connecting frame moving upwards in the axial direction is further arranged between the connecting frame and the handle assembly and comprises a stopping convex part and a stopping groove for inserting the stopping convex part, the stopping convex part is arranged on the connecting frame, and the stopping groove is arranged on the peripheral wall of the handle assembly and has a downward opening.

In order to facilitate the storage of the scooter, the axial lower end of the handle assembly is provided with a joint part articulated with the scooter body, the joint part is provided with a switching locking structure for switching between the expansion state and the folding state of the handle assembly, the switching locking structure comprises

The fifth slot and the sixth slot are arranged in the circumferential direction of the joint part at intervals;

the fourth locking piece is arranged in the vehicle body in a reciprocating sliding mode, an operating part and a third inserting part are arranged on the fourth locking piece, the operating part is exposed out of the front portion of the vehicle body, and the third inserting part can be respectively inserted into the fifth slot and the sixth slot;

a fifth elastic member which makes the third insertion portion always have a movement tendency toward the joint portion;

in the unfolded state of the handle assembly, the handle assembly is substantially perpendicular to the vehicle body, the third insertion portion of the fourth locking piece is inserted into the fifth slot, in the folded state of the handle assembly, the handle assembly is substantially parallel to the vehicle body, and the third insertion portion of the fourth locking piece is inserted into the sixth slot.

Compared with the prior art, the utility model has the advantages of: the dual-purpose bearing mechanism is in a sliding plate state, the turning plate component is accommodated in the first cavity to enable the pedal surface to face upwards, the supporting piece is transversely arranged and accommodated in the second cavity, the dual-purpose bearing mechanism is driven to move upwards along the axial direction of the handle component through the axial sliding connecting frame to enable the turning plate component to be suspended above the first cavity, then the turning plate component is turned upwards and downwards to enable the riding seat surface of the turning plate component to face upwards, the supporting plate is longitudinally arranged through the vertical swinging of the supporting piece and the other end of the supporting piece is inserted in the first cavity, so that the dual-purpose bearing mechanism is in the riding state, at the moment, the turning plate component forms a seat cushion in the riding state of the scooter, the supporting piece forms support legs of the seat cushion in the riding state of the scooter, the seat cushion does not need to be independently disassembled or assembled when the two-in-one function of the scooter is switched, accessories are not easy, and the utility model discloses a children's scooter turns over the pedal face of board subassembly and rides the seat through independent setting, and turn over board subassembly switching function through the upset, can make the seat of riding that turns over the board subassembly remain clean all the time, and allow to carry out different adaptability designs respectively to the pedal face that turns over the board subassembly and the seat of riding, if set up the great friction surface of coefficient of friction on the pedal face, set up the cushion on riding the seat, the curved surface that adapts to children's buttock shape etc., promote children's scooter's use and experience.

Drawings

Fig. 1 is a three-dimensional structure diagram of an embodiment of the present invention (in a state where a handle assembly is unfolded and a dual-purpose carrying mechanism is in a sliding plate state);

FIG. 2 is a longitudinal cross-sectional view of FIG. 1;

FIG. 3 is an enlarged view taken at A in FIG. 2;

FIG. 4 is an enlarged view at B in FIG. 2;

fig. 5 is a partial structural view of a second locking structure in an embodiment of the present invention;

FIG. 6 is an enlarged view at C of FIG. 2;

FIG. 7 is a schematic structural view of a fourth locking structure of FIG. 1;

FIG. 8 is an enlarged view taken at D in FIG. 6;

fig. 9 is a perspective view of the embodiment of the present invention (with the handle assembly unfolded and the dual-purpose supporting mechanism riding);

fig. 10 is a perspective view of the embodiment of the present invention (in another aspect, in a state where the lower handle assembly is unfolded and the dual-purpose carrying mechanism is in a riding state);

FIG. 11 is a longitudinal cross-sectional view of FIG. 9;

FIG. 12 is an enlarged view at E in FIG. 11;

FIG. 13 is an enlarged view at F of FIG. 11;

FIG. 14 is a schematic structural view of the fourth locking structure of FIG. 9;

FIG. 15 is an enlarged view at G of FIG. 14;

fig. 16 is a perspective view of the embodiment of the present invention (the handle assembly is folded);

fig. 17 is a longitudinal sectional view of fig. 16.

Detailed Description

The present invention will be described in further detail with reference to the following embodiments.

Fig. 1-17 show a preferred embodiment of the present invention.

The two-in-one child scooter in the embodiment comprises a scooter body 1, a handle assembly 2, a connecting frame 3, a dual-purpose bearing mechanism, a function switching locking structure, an opening and closing switching locking structure and other main structures. In this embodiment, the lateral direction refers to a direction extending from front to back as a whole, and may be a horizontal direction or a direction having a certain inclination with respect to the horizontal direction; the longitudinal direction refers to a direction extending from top to bottom as a whole, and may be a vertical direction or a direction having a certain inclination with respect to the vertical direction.

As shown in fig. 9, the vehicle body 1 is disposed in the lateral direction, and the upper surface of the vehicle body 1 is provided with a first cavity 11. As shown in fig. 6, the handle assembly 2 has a rectangular shape at least in part in cross section, and a joint portion 24 is provided at an axially lower end of the handle assembly 2, and the joint portion 24 is hinged to the front portion of the vehicle body 1 via a rotating shaft. As shown in fig. 1 and 9, the connecting frame 3 is slidably disposed on the handle assembly 2 in an axially reciprocating manner. The dual purpose load bearing mechanism in this embodiment includes a flap assembly 41 and a support 42. As shown in fig. 1-2 and fig. 9-11, the flap assembly 41 is disposed along the transverse direction, the front end of the flap assembly 41 is rotatably disposed on the connecting frame 3 and can be turned up and down 180 °, the flap assembly 41 has an opposing pedal surface 41a and a riding surface 41b, and the pedal surface 41a is provided with a second cavity 411. One end of the supporting member 42 is hinged in the second cavity 411, and the supporting member 42 can swing up and down to be accommodated in the second cavity 411 (see fig. 1) or the other end thereof is inserted in the first cavity 11 (see fig. 9-11). The function switching locking structure is used for switching a sliding plate state and a riding state of the dual-purpose bearing mechanism, when the dual-purpose bearing mechanism is locked by the function switching locking structure in the sliding plate state, the flap plate assembly 41 is accommodated in the first cavity 11, the pedal surface 41a faces upwards, the supporting piece 42 is transversely arranged, the supporting piece 42 is accommodated in the second cavity 411 (see fig. 1-2), when the dual-purpose bearing mechanism is locked by the function switching locking structure in the riding state, the flap plate assembly 41 is suspended above the first cavity 11, the riding surface 41b faces upwards, the supporting piece 42 is longitudinally arranged, and the other end of the supporting piece 42 is inserted into the first cavity 11 (see fig. 9-11).

The function switching lock structure includes a first lock structure for locking or unlocking a state in which the support member 42 is accommodated in the second cavity 411, a second lock structure for allowing the flap assembly 41 to escape from the first cavity 11 in a state in which the dual purpose carriage is in a slide state, a third lock structure for allowing the link frame 3 to slide axially along the handle assembly 2 in a state in which the dual purpose carriage is in a riding state, and a fourth lock structure for allowing the flap assembly 41 to be flipped in a state in which the dual purpose carriage is in a riding state.

As shown in fig. 3 and 8, the first locking structure includes a first insertion groove 421, a threaded portion 412, a threaded sleeve 52, a first locking member 51, and a first elastic member 53. The first insertion groove 421 is provided at the other end portion of the support member 42 (see fig. 3, 8, and 13); a threaded portion 412 is provided at the front end of the flap assembly 41 (see fig. 3, 8, 12 and 15); the threaded sleeve 52 is in threaded connection with the threaded part 412 and is arranged in the connecting frame 3 in a manner of sliding back and forth (see fig. 3, 8, 12 and 15), namely, the threaded sleeve 52 cannot rotate around the axis of the threaded sleeve; the screw portion 412 has a cavity therein, a connecting rod 54 is slidably inserted in the cavity, the front end of the connecting rod 54 is fixed to the threaded sleeve 52 through a fastener, the rear end of the connecting rod 54 is provided with a limit protrusion 541, the first locking member 51 is provided with a limit stop 511 abutting against the front surface of the limit protrusion 541, so that the first locking member 51 is constrained on the threaded sleeve 52 and slidably inserted in the side wall of the second cavity 411 in the front-back direction (see fig. 3, 8, 12 and 15), and the first locking member 51 can be inserted into the first slot 421 (see fig. 3 and 8); the first elastic member 53 is a spring and makes the first locking member 51 always have a tendency to be inserted into the first insertion groove 421 (see fig. 8).

As shown in fig. 4, the second locking structure includes a second locking member 61, a second slot 413, a second elastic member 62, a first button 63, a first insertion portion 111, and a third slot 414. Wherein, the second locking piece 61 is reciprocally movably arranged on the side wall of the first cavity 11 (see fig. 4); the second slot 413 is disposed on the rear sidewall of the flap assembly 41 and is used for inserting the second locking member 61 (see fig. 4); the second elastic element 62 is a spring and always gives the second locking element 61 a tendency to move towards the first cavity 11 (see figure 4); the first key 63 is provided with a connecting part 631 and a pushing part 632, the connecting part 631 is arranged on one side of the first key 63 and connected with the vehicle body 1 to enable the first key 63 to swing up and down, the pushing part 632 is a notch with a backward opening, and the second locking part 61 is provided with a pin shaft part 611 (see fig. 5) which is abutted against the pushing part 632, so that the downward swinging of the first key 63 can drive the second locking part 61 to be far away from the first cavity 11 (see fig. 4); the first insertion portion 111 is provided protruding on the bottom wall of the first cavity 11 (see fig. 4); the third slot 414 is disposed on the riding surface 41b of the flap assembly 41 and is for the first insertion portion 111 to be inserted (see fig. 4).

In order to enable the other end of the supporting member 42 to be stably inserted into the first cavity 11 when the dual-purpose carrying mechanism is in the riding state, as shown in fig. 13, the supporting member 42 has a first surface 42a hidden in the second cavity 411 and a second surface 42b always exposed on the flap assembly 41, the first slot 421 is disposed on the first surface 42a, and the first inserting portion 111 can be inserted into the first slot 421; the second surface 42b of the supporting member 42 is provided with a fourth insertion groove 422 into which the second locking member 61 is inserted, and the fourth insertion groove 422 is provided near the other end portion of the supporting member 42.

In order to enable the connecting frame 3 to drive the dual-purpose bearing mechanism to axially move upwards along a preset track, a rib groove inserting and matching guide structure is arranged between the connecting frame 3 and the handle assembly 2 and comprises a convex rib 32 and a guide groove 22, the convex rib 32 is arranged on the inner side wall of the connecting frame 3 (see fig. 10), and the guide groove 22 is arranged on the outer peripheral wall of the handle assembly 2 (see fig. 9-10 and 15).

In order to facilitate the positioning of the position where the flap assembly 41 is suspended above the first cavity 11, a stop structure for limiting the axial upward movement of the connecting frame 3 is further disposed between the connecting frame 3 and the handle assembly 2, as shown in fig. 12, the stop structure includes a stop protrusion 33 and a stop groove 23 for inserting the stop protrusion 33, the stop protrusion 33 is disposed on the connecting frame 3, and the stop groove 23 is disposed on the peripheral wall of the handle assembly 2 and has a downward opening.

As shown in fig. 15, the third locking structure includes a second insertion portion 521 and a positioning hole 21 for inserting the second insertion portion 521, the second insertion portion 521 is disposed at the front end of the threaded sleeve 52 and slidably inserted in the front surface of the connecting frame 3, and the positioning hole 21 penetrates through the peripheral wall of the handle assembly 2.

As shown in fig. 8 and 15, the fourth locking structure includes a third locking member 71, a locking hole 31, a third elastic member 72, a second button 73, and a fourth elastic member 74. Wherein, the third locking piece 71 is slidably arranged on the front surface of the flap assembly 41 back and forth (see fig. 8 and 15); the locking hole 31 penetrates the connecting frame 3 and allows the front end of the third locking piece 71 to be inserted (see fig. 8 and 15); the third elastic member 72 is a spring and causes the third locking member 71 to always have a tendency to move forward (see fig. 8 and 15); the second button 73 is slidably arranged in front and back of the lock hole 31 (see fig. 8 and 15); the fourth elastic element 74 is a spring, and makes the second button 73 always have a forward movement tendency and exposed on the front surface of the connecting frame 3 (see fig. 8 and 15). In a state that the pedal surface 41a of the flap assembly 41 faces upward, the third locking member 71 abuts against the connecting frame 3, in this embodiment, the connecting frame 3 includes a front shell 34 and a rear shell 35 connected to each other, and the third locking member 71 is inserted into the rear shell 35 and abuts against the front shell 34; and the third locking member 71 and the locking hole 31 are correspondingly disposed at two sides of the rotation axis of the flap assembly 41, when the flap assembly 41 is accommodated in the first cavity 11, the front end surface of the connecting frame 3 corresponding to the locking hole 31 abuts against the car body 1, so that the front end surface of the second key 73 exposed on the front surface of the connecting frame 3 abuts against the car body 1 (see fig. 8), when the flap assembly 41 is suspended above the first cavity 11, the front end surface of the connecting frame 3 corresponding to the locking hole 31 is separated from the car body 1, and the second key 73 is exposed to the outside for the user to press. In a state where the seating surface 41b of the flap assembly 41 is directed upward, the front end of the third locking piece 71 is inserted into the lock hole 31 (see fig. 15).

As shown in fig. 6 and 17, the opening/closing switching lock structure is provided between the joint portion 24 and the vehicle body 1, and is used to switch the deployed state and the folded state of the handle assembly 2. As shown in fig. 6 and 17, the opening/closing switching locking structure includes a fourth locking member 81, a fifth slot 241, a sixth slot 242, and a fifth elastic member 82. As shown in fig. 6 and 17, the fifth slot 241 and the sixth slot 242 are spaced in the circumferential direction of the joint portion 24; the fourth locking piece 81 can be slidably arranged in the vehicle body 1 in a reciprocating manner, an operating part 811 and a third inserting part 812 are arranged on the fourth locking piece 81, the operating part 811 is exposed at the lower side of the front part of the vehicle body 1, and the third inserting part 812 can be respectively inserted into the fifth slot 241 and the sixth slot 242; the fifth elastic member 82 is a spring, and makes the third insertion portion 812 always have a movement tendency to be inserted into the fifth insertion groove 241.

The theory of operation of two unification children's scooter in this embodiment does:

in use, the handle assembly 2 is substantially perpendicular to the vehicle body 1, and the third insertion portion 812 of the fourth locking member 81 is inserted into the fifth insertion groove 241 to place the handle assembly 2 in the unfolded state (see fig. 6).

When the two-in-one children scooter is used as a scooter, the flap assembly 41 is accommodated in the first cavity 11 with the pedal face 41a facing upwards (see fig. 2), the second locking piece 61 is inserted into the second slot 413, and the first insertion portion 111 is inserted into the third slot 414 (see fig. 4); the supporting member 42 is accommodated in the second cavity 411 (see fig. 2), the first locking member 51 is inserted into the first slot 421, and the front end surface of the threaded sleeve 52 abuts against the peripheral wall of the handle assembly 2 (see fig. 3); the third locking member 71 abuts against the connecting frame 3, the front end surface of the second button 73 abuts against the vehicle body 1, and the third locking member 71 and the lock hole 31 are correspondingly arranged on two sides of the rotation axis of the flap assembly 41 (see fig. 8).

When the two-in-one child scooter is required to be used as a scooter, the functions are switched according to the following operation steps: pressing the first key 63 downwards to make the first key 63 drive the second locking member 61 to be separated from the second slot 413; moving the connecting frame 3 upward axially until the stop convex part 33 on the connecting frame 3 is inserted into the stop concave groove 23 on the handle assembly 2 (see fig. 12), so that the dual-purpose bearing mechanism is suspended above the first cavity 11 and the first insertion part 111 is separated from the third slot 414; turning over the dual-purpose bearing mechanism until the riding surface 41b of the flap assembly 41 faces upwards (see fig. 9), driving the threaded sleeve 52 to move forwards by the threaded portion 412 of the flap assembly 41 to the second insertion portion 521 to be inserted into the positioning hole 21, and driving the first locking member 51 to move forwards to be separated from the first slot 421 (see fig. 15), at this time, the front end of the third locking member 71 is inserted into the locking hole 31, and the second key 73 is exposed to the outside (see fig. 15); the support member 42 is swung downward such that the other end of the support member 42 is inserted into the first cavity 11, the first insertion portion 111 is inserted into the first insertion groove 421, and the second locking member 61 is inserted into the fourth insertion groove 422 due to the second elastic member 62 (see fig. 13).

When the two-in-one child scooter is required to be used as a scooter, the functions are switched according to the following operation steps: firstly, pressing the first key 63 downwards to make the first key 63 drive the second locking piece 61 to be separated from the fourth slot 422; swing up the other end of the supporting member 42 to allow the supporting member 42 to be received in the second cavity 411; thirdly, the second key 73 is pressed backwards, so that the third locking piece 71 moves backwards to be separated from the lock hole 31; the dual-purpose bearing mechanism is reversely turned until the pedal surface 41a of the flap assembly 41 faces upwards, the thread part 412 of the flap assembly 41 drives the thread sleeve 52 to move backwards to the second insertion part 521 to be separated from the positioning hole 21, and drives the first locking part 51 to move backwards and to be inserted into the first slot 421 again, at this time, the third locking part 71 abuts against the connecting frame 3, the front end surface of the second key 73 is still exposed to the outside, and the third locking part 71 and the lock hole 31 are correspondingly arranged on two sides of the rotation axis of the flap assembly 41; the connecting frame 3 is axially moved downwards until the flap assembly 41 is accommodated in the first cavity 11, the first insertion portion 111 is inserted into the third slot 414, and the second locking member 61 is inserted into the second slot 413 under the action of the second elastic member 62 (see fig. 4), at this time, the front end surface of the second key 73 abuts against the vehicle body 1 (see fig. 8).

When the two-in-one scooter needs to be folded, the operating part 811 is pulled forward to make the third insertion part 812 be separated from the fifth slot 241, the handle assembly 2 is rotated until the handle assembly 2 is substantially parallel to the scooter body 1 to make the handle assembly be in the folded state, and the operating part 811 is released to make the third insertion part 812 be inserted into the sixth slot 242 (see fig. 17).

It should be noted that in the description of the present embodiment, the terms "front, back", "left, right", "up, down", etc. indicate the orientation or positional relationship based on the orientation or positional relationship shown in the drawings, which is only for convenience of description of the present invention and simplification of description, but does not indicate or imply that the device or element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. The terms "mounted," "connected," and "coupled" are to be construed broadly and may, for example, be fixedly coupled, detachably coupled, or integrally coupled; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Claims (10)

1. A two-in-one children scooter comprises:

a vehicle body (1);

a handle assembly (2) connected to the vehicle body (1);

it is characterized by also comprising a step of,

the connecting frame (3) is arranged on the handle assembly (2) in an axially reciprocating sliding manner;

the dual-purpose bearing mechanism comprises a turning plate assembly (41) arranged transversely and a support member (42) with one end hinged with the turning plate assembly (41), the front end of the turning plate assembly (41) is rotatably arranged on the connecting frame (3) and can be turned over for 180 degrees up and down, the turning plate assembly (41) is provided with a pedal surface (41a) provided with a second cavity (411) and a riding surface (41b) opposite to the pedal surface (41a), the upper surface of the vehicle body (1) is provided with a first cavity (11), and the support member (42) can swing up and down to be accommodated in the second cavity (411) or the other end of the support member is inserted into the first cavity (11);

the dual-purpose bearing mechanism comprises a dual-purpose bearing mechanism body, a support piece (42), a turning plate assembly (41), a plate turning assembly and a support piece (42), wherein the dual-purpose bearing mechanism body is used for switching a sliding plate state and a riding state of the dual-purpose bearing mechanism body, the plate turning assembly (41) locks the dual-purpose bearing mechanism body in the sliding plate state, the pedal faces (41a) face upwards, the support piece (42) is arranged in the transverse direction, the support piece (42) is arranged in the longitudinal direction, the other end of the support piece (42) is inserted into the first cavity (11), the support piece (42) is arranged in the riding state, and the support piece (42) is arranged above the first cavity (411) in the transverse direction.

2. The two-in-one children's scooter according to claim 1, wherein the function switching locking structure comprises a first locking structure for locking or unlocking a state where the support member (42) is received in the second cavity (411), a second locking structure for allowing the flap assembly (41) to escape from the first cavity (11) in a skateboard state of the dual purpose carrying mechanism, a third locking structure for allowing the link frame (3) to axially slide along the handle assembly (2) in a riding state of the dual purpose carrying mechanism, and a fourth locking structure for allowing the flap assembly (41) to turn over in a riding state of the dual purpose carrying mechanism.

3. The two-in-one child scooter according to claim 2, wherein the first locking structure comprises

A first slot (421) arranged at the other end of the supporting piece (42);

the threaded part (412) is arranged at the front end of the flap component (41);

a threaded sleeve (52) which is connected with the threaded part (412) in a threaded manner and is arranged in the connecting frame (3) in a sliding manner;

the first locking piece (51) is constrained on the threaded sleeve (52) and can be arranged on the side wall of the second cavity (411) in a penetrating manner in a forward and backward sliding manner, and the first locking piece (51) can be inserted into the first insertion groove (421);

a first elastic member (53) for always having the first locking member (51) have a tendency to be inserted into the first insertion groove (421).

4. The two-in-one child scooter according to claim 3, wherein the second locking structure comprises

The second locking piece (61) can be arranged on the side wall of the first cavity (11) in a penetrating way in a reciprocating way;

the second slot (413) is arranged on the side wall of the turning plate component (41) and is used for the second locking piece (61) to insert;

a second elastic element (62) which makes the second locking element (61) always have a movement trend moving towards the first cavity (11);

the first key (63) is hinged to the vehicle body (1) and can swing up and down, and the downward swing of the first key (63) can drive the second locking piece (61) to be away from the first cavity (11);

the first inserting part (111) is convexly arranged on the bottom wall of the first concave cavity (11);

and a third slot (414) which is arranged on the riding surface (41b) of the flap assembly (41) and is used for the first insertion part (111) to insert.

5. The two-in-one children's scooter according to claim 4, wherein the supporting member (42) has a first surface (42a) hidden in the second cavity (411) and a second surface (42b) always exposed on the flap assembly (41), the first insertion slot (421) is provided on the first surface (42a), and the first insertion portion (111) is inserted into the first insertion slot (421); the second surface (42b) of the supporting member (42) is provided with a fourth slot (422) for the second locking member (61) to be inserted into, and the fourth slot (422) is disposed near the other end of the supporting member (42).

6. The two-in-one children scooter according to claim 3, wherein the third locking structure comprises a second insertion portion (521) and a positioning hole (21) for inserting the second insertion portion (521), the second insertion portion (521) is disposed at the front end of the threaded sleeve (52) and slidably inserted in the front surface of the connecting frame (3), and the positioning hole (21) penetrates through the peripheral wall of the handle assembly (2).

7. The two-in-one child scooter according to claim 2, wherein the fourth locking structure comprises

A third locking piece (71) which can be arranged on the front surface of the flap assembly (41) in a penetrating way in a sliding way;

a lock hole (31) which penetrates the connecting frame (3) and into which the front end of the third locking piece (71) is inserted;

a third elastic member (72) which enables the third locking member (71) to always have a forward movement trend;

the second key (73) can be arranged in front of and behind the lock hole (31) in a sliding mode;

a fourth elastic element (74) which enables the second key (73) to always have a forward movement trend and be exposed on the front surface of the connecting frame (3);

under the condition that the pedal face (41a) of the flap assembly (41) faces upwards, the third locking piece (71) is abutted to the connecting frame (3), the third locking piece (71) and the lock hole (31) are correspondingly arranged on two sides of the rotation axis of the flap assembly (41), the riding seat face of the flap assembly (41) faces upwards, and the front end of the third locking piece (71) is inserted into the lock hole (31).

8. The two-in-one children scooter according to any one of claims 1 to 7, wherein a rib and groove insertion guiding structure is disposed between the connecting frame (3) and the handle assembly (2), the rib and groove insertion guiding structure comprises a rib (32) and a guiding groove (22), the rib (32) is disposed on one of an inner side wall of the connecting frame (3) and an outer peripheral wall of the handle assembly (2), and the guiding groove (22) is disposed on the other of the inner side wall of the connecting frame (3) and the outer peripheral wall of the handle assembly (2).

9. The two-in-one children scooter according to any one of claims 1 to 7, wherein a stop structure for limiting the axial upward movement of the connecting frame (3) is further disposed between the connecting frame (3) and the handle assembly (2), the stop structure includes a stop protrusion (33) and a stop groove (23) for inserting the stop protrusion (33), the stop protrusion (33) is disposed on the connecting frame (3), and the stop groove (23) is disposed on the peripheral wall of the handle assembly (2) and has a downward opening.

10. The two-in-one children's scooter according to any one of claims 1 to 7, wherein the lower axial end of the handle assembly (2) is provided with a joint (24) hinged to the scooter body (1), an opening/closing switching locking structure for switching the unfolded state and the folded state of the handle assembly (2) is arranged between the joint (24) and the scooter body (1), and the opening/closing switching locking structure comprises

A fifth slot (241) and a sixth slot (242) which are arranged at intervals in the circumferential direction of the joint part (24);

a fourth locking piece (81) which is arranged in the vehicle body (1) in a reciprocating sliding way, an operation part (811) and a third insertion part (812) are arranged on the fourth locking piece, the operation part (811) is exposed at the front part of the vehicle body (1), and the third insertion part (812) can be respectively inserted into the fifth slot (241) and the sixth slot (242);

a fifth elastic member (82) that causes the third insertion portion (812) to always have a tendency to move toward the joint portion (24);

under handle subassembly (2) development condition, handle subassembly (2) with automobile body (1) is basically perpendicular, and the third portion of inserting (812) of fourth locking piece (81) inserts in fifth slot (241), under handle subassembly (2) folding condition, handle subassembly (2) with automobile body (1) is basically parallel, just the third portion of inserting (812) of fourth locking piece (81) inserts in sixth slot (242).

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