TELESCOPIC FRAME STRUCTURE OF SCOOTER

Abstract

The telescopic frame structure of a scooter includes: rear and front frame bodies; a telescopic connection frame; a limiting member having front and rear plate bodies disposed above the telescopic connection frame, the front plate body is pivoted to the front frame body through the first pivoting shaft member, the rear plate body is pivoted to the rear frame body through the second pivoting shaft member, and the front plate body is pivoted to the rear plate body through the second pivoting shaft member. The axle center definition of the first, second and third pivoting shaft member respectively forms the first, second and third pivoting axis. The connecting definition between the first and second pivoting axes forms a virtual connecting axis corresponding to the third pivoting shaft member defines an intermediate line section. The height of the third pivot axis is lower than the intermediate line section.

Claims

1. A telescopic frame structure of the scooter includes: a rear frame body; a front frame body, disposed at the front end interval of the rear frame body, a telescopic connection frame is disposed between the front frame body and the rear frame body to be retractable and adjustable under force, so that the front frame body and the rear frame body are selectively reciprocally movable to change the total length of the telescopic frame structure of the scooter; and a limiting member comprises a front plate body and a rear plate body disposed above the telescopic connection frame, the front plate body and the rear plate body respectively have a front side and a rear side, wherein the front side of the plate body is pivoted to the rear edge of the front frame body through a first pivoting shaft member; the rear side of the rear plate body is pivoted to the front edge of the rear frame body through a second pivoting shaft member; the rear side of the front plate body is pivoted to the front side of the rear plate body through a third pivoting shaft member; when the telescopic connection frame is in an elongated state, the front plate body and the rear plate body are relatively interlocked by the third pivoting shaft member in flat rotary fulcrum state; wherein the axle center definition of the first pivoting shaft member forms a first pivoting axis, the axle center definition of the second pivoting shaft member forms a second pivoting axis, and the axle center definition of the third pivoting shaft member forms a third pivoting axis; and the connecting definition between the first pivoting axis and the second pivoting axis forms a virtual connecting axis, the virtual connecting axis is in an any state of horizontal line or approaching the horizontal line, and the virtual connecting axis corresponding to the third pivoting shaft member defines an intermediate line section and the height of the third pivot axis is lower than the height of the intermediate line section.

2. The telescopic frame structure of the scooter defined in claim 1, wherein the telescopic connection frame includes two rod bodies at left and right interval configuration; the front plate body and the bottom of the rear plate body are provided with two abutting parts at left and right interval configuration, so that the two abutting parts are correspondingly abutted downward against the two rod bodies.

3. The telescopic frame structure of the scooter defined in claim 1, wherein the front plate body and the rear plate body are in a plate shape of a default thickness or in a bending composition type of metal sheet; the upper edge of the rear side of the front plate body and the upper edge of the front side of the rear plate body are respectively provided with a first abutting part and a second abutting part; when the front frame body relative to the rear frame body is extended towards in riding state, the first abutting part and the second abutting part are abutted against each other.

4. The telescopic frame structure of the scooter defined in claim 1, wherein one selected from the front plate body and the rear plate body is provided with an operation part, and the operation part is either in a bump type or in an open-hole type.

5. The telescopic frame structure of the scooter defined in claim 2, wherein one selected from the front plate body and the rear plate body is provided with an operation part, and the operation part is either in a bump type or in an open-hole type.

6. The telescopic frame structure of the scooter defined in claim 3, wherein one selected from the front plate body and the rear plate body is provided with an operation part, and the operation part is either in a bump type or in an open-hole type.

7. The telescopic frame structure of the scooter defined in claim 1, wherein one selected from the front plate body and the rear plate body is provided with at least one snap member, and the snap member is selectively snapped onto the telescopic connection frame structure.

8. The telescopic frame structure of the scooter defined in claim 2, wherein one selected from the front plate body and the rear plate body is provided with at least one snap member, and the snap member is selectively snapped onto the telescopic connection frame structure.

9. The telescopic frame structure of the scooter defined in claim 3, wherein one selected from the front plate body and the rear plate body is provided with at least one snap member, and the snap member is selectively snapped onto the telescopic connection frame structure.

10. The telescopic frame structure of the scooter defined in claim 4, wherein one selected from the front plate body and the rear plate body is provided with at least one snap member, and the snap member is selectively snapped onto the telescopic connection frame structure.

11. The telescopic frame structure of the scooter defined in claim 1, wherein the top surface of the front plate body and the rear plate body forms a stepping surface for the user to step on by the foot, so as to further enhance the effect of preventing the front plate body and the rear plate body from jumping upward.

12. The telescopic frame structure of the scooter defined in claim 2, wherein the top surface of the front plate body and the rear plate body forms a stepping surface for the user to step on by the foot, so as to further enhance the effect of preventing the front plate body and the rear plate body from jumping upward.

13. The telescopic frame structure of the scooter defined in claim 3, wherein the top surface of the front plate body and the rear plate body forms a stepping surface for the user to step on by the foot, so as to further enhance the effect of preventing the front plate body and the rear plate body from jumping upward.

Description

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

[0015] FIG. 1 is a side view of the scooter of the present invention.

[0016] FIG. 2 is a side view of the folded seat of the scooter in FIG. 1.

[0017] FIG. 3 is a top view of the telescopic connection frame of the present invention in unfolding state.

[0018] FIG. 4 is a three-dimensional diagram of the partial component decomposition of the present invention.

[0019] FIG. 5 is a three-dimensional diagram of the front plate body and rear plate body of the present invention in folded state.

[0020] FIG. 6 is a side view of the scooter exposed corresponding to FIG. 5.

[0021] FIG. 7 is a three-dimensional outside view of the scooter of the present invention after folding.

[0022] FIG. 8 is a side view of the unfolded limiting member of the present invention.

[0023] FIG. 8A is a partial enlargement diagram of FIG. 8.

[0024] FIG. 8B is an embodiment diagram of the top surface of a front plate body and a rear plate body of the present invention in an angular state of less than 180 included angle.

[0025] FIG. 9 is a three-dimensional upward view of the folded limiting member of the present invention.

[0026] FIG. 10 is a three-dimensional upward view of the folded limiting member of the present invention.

[0027] FIG. 11 is a vertical sectional view of the rear plate body provided with snap member snapped in the telescopic connection frame.

[0028] FIG. 12 is an embodiment diagram of the operation part of the present invention in the open-hole type.

[0029] FIG. 13 is a side view of the second preferred embodiment of the folded limiting member of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

[0030] Referring to FIG. 1 to FIG. 11 for the preferred embodiments of the telescopic frame structure of the scooter of the present invention. However, these embodiments are for illustrative purposes only and are not limited by the structure in the patent application.

[0031] The telescopic frame structure of the scooter includes a rear frame body 10 and a set of front frame bodies 20 disposed at a front end of the rear frame body 10; a forced-telescopic and adjustable telescopic connection frame 30 is disposed between the front frame body 20 and the rear frame body 10, so that the front frame body 20 and the rear frame body 10 are selectively reciprocally movable to change the total length of the telescopic frame structure of the scooter; a limiting member 40 comprises a front plate body 41 and a rear plate body 42 disposed above the telescopic connection frame 30, the front plate body 41 and the rear plate body 42 respectively have a front side and a rear side, wherein the front side of the plate body 41 is pivoted to the rear edge of the front frame body 20 through a first pivoting shaft member 81. The rear side of the rear plate body 42 is pivoted to the front edge of the rear frame body 10 through a second pivoting shaft member 82. The rear side of the front plate body 41 is pivoted to the front side of the rear plate body 42 through a third pivoting shaft member 83. When the telescopic connection frame 30 is in an unfolded state, the front plate body 41 and the rear plate body 42 are relatively interlocked by the third pivoting shaft member 83 in flat rotary fulcrum state (as shown in FIGS. 2 and 8); wherein the axle center definition of the first pivoting shaft member 81 forms a first pivoting axis L1, the axle center definition of the second pivoting shaft member 82 forms a second pivoting axis L2, and the axle center definition of the third pivoting shaft member 83 forms a third pivoting axis L3; and the connecting definition between the first pivoting axis L1 and the second pivoting axis L2 forms a virtual connecting axis L4, the virtual connecting axis L4 is in an any state of horizontal line or approaching the horizontal line, and the virtual connecting axis L4 corresponding to the third pivoting shaft member 83 defines an intermediate line section W and the height of the third pivot axis L3 is lower than the height of the intermediate line section W(as shown in FIGS. 8 and 8A).

[0032] As shown in FIG. 11, wherein the telescopic connection frame 30 includes two rod bodies 31 and 32 at left and right interval configuration; the front plate body 41 and the bottom of the rear plate body 42 are provided with two abutting parts 45 and 46 at left and right interval configuration, so that the two abutting parts 45 and 46 are correspondingly abutted downward against the two rod bodies 31 and 32.

[0033] As shown in FIGS. 8, 8A and 10, the upper edge of the rear side of the front plate body 41 and the upper edge of the front side of the rear plate body 42 are respectively provided with a first abutting part 411 and a second abutting part 421; when the front frame body 20 and the rear frame body 10 are in a flat state (as shown in FIGS. 2 and 8), the first abutting part 411 and the second abutting part 421 are abutted against each other, so that the top surface of the front plate body 41 and the top surface of the rear plate body 42 form an included angle of less than 180, and the front plate body 41 and the rear plate body 42 are in a dead point state, so the relative position between the front frame body 20 and the rear frame body 10 of the scooter will not be arbitrarily changed, thereby further improving the use stability and safety of the scooter.

[0034] As shown in FIG. 8FIG. 10, the front plate body 41 and the rear plate body 42 are in a plate shape of a default thickness; or as shown in FIG. 12, the front plate body 41A and the rear plate body 42A are in a bending composition type of metal sheet.

[0035] As shown in FIGS. 8, 8A, 8B, 9 and 10, one selected from the front plate body 41 and the rear plate body 42 is provided with an operation part 43A, and in the preferred embodiment, the operation part 43A is arranged above the rear plate body 42; before the limiting member 40 is engaged, and when the front frame body 20 and the rear frame body 10 are relatively retracted, it is convenient for the user to easily lift up the front plate body 41 and the rear plate body 42 from the operation part 43A. The specific embodiment type of the operation part 43A is as shown in FIG. 10, and it is in a bump type; also, the operation part 43B shown in FIG. 12 is in an open-hole type formed on the front plate body 41 (or the rear plate body 42), and it is also convenient to lift up the front plate body 41 and the rear plate body 42.

[0036] As shown in FIG. 9, one selected from the front plate body 41 and the rear plate body 42 is provided with at least one snap member 44, and the snap member 44 is selectively snapped onto the telescopic connection frame 30 structure (as shown in FIG. 11), this embodiment mainly aims that the snap member 44 snapped in the telescopic connection frame 30 structure can produce the appropriate assistance snapping and positioning effect for the flat state of the front plate body 41 and the rear plate body 42, so as to enhance the effect of preventing the front plate body 41 and the rear plate body 42 from jumping upward. Or, the top surface of the front plate body 41 and the rear plate body 42 forms a stepping surface for the user to step on by the foot, so as to further enhance the effect of preventing the front plate body 41 and the rear plate body 42 from jumping upward.

[0037] Based on the above structural composition types and technical features, the use of the preferred embodiment of the present invention is illustrated as follows: as shown in FIG. 1, the scooter is in a riding and driving state, at this time, the front frame body 20 is extended forward with respect to the rear frame body 10 by using the telescopic connection frame 30, when the front frame body 20 and the rear frame body 10 are close to each other by the force (such as the relative acting force of the components generated during driving), the first abutting part 411 and the second abutting part 421 will be abutted to each other, at this time with the different abutment set angle of the first abutting part 411 and the second abutting part 421, the top surface of the front plate body 41 and the rear plate body 42 may be in a state of 180 included angle (i.e., plane joint) (as shown in FIG. 8A); or, as shown in FIG. 8B, the top surface of the front plate body 41 and the rear plate body 42 in an included angle state of less than 180 (i.e., the zigzag surface is engaged), so that the front plate body 41 and the rear plate body 42 are in the dead point state, while the snap member 44 is snapped onto the telescopic connection frame 30 structure (see FIG. 11 for details). As shown in FIG. 2, when the scooter frame begins to fold, the seat 50 is firstly engaged towards the rear frame body 10 by the connecting rod structure 60, to lower its horizontal height. Next, referring to FIGS. 5 and 6, when the user wants to further fold the scooter frame, first uses the operation part 43A to lift up the front plate body 41 and the rear plate body 42, so that the front plate body 41 and the rear plate body 42 are out of the dead point state, at the same time, the snap member 44 is also synchronously disengaged from the telescopic connection frame 30. When the user makes that the front plate body 41 and the rear plate body 42 are in a folded state with the third pivoting shaft member 83 as a pivot point (as shown in FIG. 5), the front frame body 20 is retracted relative to the rear frame body 10 by using the telescopic connection frame 30, so as to achieve the purpose of reducing the total length of the scooter frame. Referring to FIG. 7 for details, finally, the user uses the pivoting structure 71 of the scooter handlebar structure 70 to close and fix the folded seat 50, that is, the entire folding process of the scooter is completed.