CN109308093B - Fastening mechanism, transmission seat with fastening mechanism and electronic equipment - Google Patents

Abstract

A fastening mechanism, a transmission seat with the fastening mechanism and an electronic device with the fastening mechanism are provided, wherein the fastening mechanism comprises a rotating fastener, a guide frame and a translation frame. The rotating fastener can rotate around a pivot axis to a buckling state. The guide frame is provided with two outer side walls opposite to each other, the guide frame is convexly arranged on a bearing surface, the pivot axis of the rotary fastener is substantially parallel to the bearing surface, and the rotary fastener protrudes out of one of the outer side walls in the buckling state. The translation frame is provided with two inner side walls opposite to each other and two upper wall surfaces opposite to each other, and when the translation frame is butted with the bearing surface, the two outer side walls are positioned between the two inner side walls. The fastening mechanism, the transmission seat with the fastening mechanism and the electronic equipment have the advantages of quickly assembling a two-in-one computer, strengthening the connection between the tablet computer and the transmission seat, being not easy to remove the assembling relation due to impact or vibration and the like.

Description

Fastening mechanism, transmission seat with fastening mechanism and electronic equipment

[ technical field ] A method for producing a semiconductor device

The present invention relates to a fastening mechanism, a transmission base with the fastening mechanism, and an electronic device, and more particularly, to a fastening mechanism with a rotary fastener, and a transmission base with the fastening mechanism and an electronic device.

[ background of the invention ]

With the progress of technology, notebook computers are thinner, thinner and more compact, and tablet computers have higher and higher performance, which have a major breakthrough but have disadvantages and disadvantages. For example, a tablet pc has the advantage of high portability, but it lacks a built-in keyboard, which results in a low operation efficiency.

Therefore, in recent years, a detachable two-in-one notebook computer has been introduced by the industry as an innovative model of notebook computers. The screen part and the keyboard part are made detachable, so that the screen part can be used as a common panel when combined together, and the detachable two-in-one computer is a future market trend due to the advantages of high portability and high operation efficiency. In order to meet the usage of the computer, it is thought that how to quickly assemble and disassemble the two-in-one computer and ensure and strengthen the connection relationship between the two-in-one computer is a link that is very important for the practitioners in the art.

[ summary of the invention ]

Accordingly, the present invention provides a fastening mechanism, and a transmission base and an electronic device having the fastening mechanism, which can achieve the effect of quickly assembling a screen and a keyboard and simultaneously strengthening the connection relationship between the screen and the keyboard.

The invention discloses a fastening mechanism, which comprises a rotating fastener, a guide frame and a translation frame. The rotating fastener can rotate around a pivot axis to a buckling state. The guide frame is provided with two outer side walls opposite to each other, the guide frame is convexly arranged on a bearing surface, the pivot axis of the rotary fastener is substantially parallel to the bearing surface, and the rotary fastener protrudes out of one of the outer side walls in the buckling state. The translation frame is provided with two inner side walls opposite to each other and two upper wall surfaces opposite to each other, when the translation frame is butted on the bearing surface, the two outer side walls are positioned between the two inner side walls, and the rotation fastener can rotate to stop one of the upper wall surfaces in the buckling state.

According to a transmission base disclosed by the present invention, the transmission base is suitable for being butted with a first electronic device, a butting side of the first electronic device is butted with the transmission base along a bearing direction by at least one translation frame, and the transmission base comprises a base body, at least one rotation fastener and at least one guide frame. The seat body is provided with a containing groove for containing the butt joint side edge. At least one rotating fastener can rotate around a pivot axis to a buckling state. The at least one guide frame is provided with two opposite outer side walls and is convexly arranged on a bearing surface at the bottom of the accommodating groove, wherein the pivot axis of the at least one rotating fastener is substantially parallel to the bearing surface. The at least one translation frame is provided with two inner side walls opposite to each other and two upper wall surfaces adjacent to the two inner side walls respectively, when the translation frame is abutted to the bearing surface, the two outer side walls are located between the two inner side walls and can be used for stopping one of the upper wall surfaces when the rotary fastener rotates to the buckling state.

According to an embodiment of the present invention, an electronic apparatus includes a transmission base, a first electronic device and a second electronic device. The first electronic device is provided with a butt joint side edge and at least one translation frame, the at least one translation frame is positioned on the butt joint side edge, and the first electronic device can be electrically butted with the transmission seat along a bearing direction. The transmission seat is disposed on the second electronic device, wherein the transmission seat includes a seat body, at least one rotating fastener, and at least one guiding frame. The seat body is provided with a containing groove for containing the butt joint side edge. At least one rotating fastener can rotate around a pivot axis to a buckling state. The at least one guide frame is provided with two opposite outer side walls and is convexly arranged on a bearing surface at the bottom of the accommodating groove, wherein the pivot axis of the at least one rotating fastener is substantially parallel to the bearing surface. The at least one translation frame is provided with two inner side walls opposite to each other and two upper wall surfaces adjacent to the two inner side walls respectively, when the translation frame is abutted to the bearing surface, the two outer side walls are located between the two inner side walls and can be used for stopping one of the upper wall surfaces when the rotation fastener rotates to the buckling state.

In the fastening mechanism disclosed in the present invention, and the transmission base and the electronic apparatus having the fastening mechanism, since the rotating fastener is rotatably disposed with the pivot axis substantially parallel to the carrying surface of the transmission base, the user only needs to butt the first electronic device (part of the screen) against the transmission base along the carrying direction substantially perpendicular to the carrying surface to complete the assembly, and the translation frame can push against and slide over the rotating fastener to complete the fastening operation. That is, the assembly of the locking mechanism of the present invention is intuitive and convenient, which is helpful for users to quickly assemble the first electronic device (screen part) on the second electronic device (keyboard part).

Moreover, when the rotating fastener rotates to the fastening state, the rotating fastener can be stopped on the upper wall surface of the translation frame, so that the translation frame can be limited by the rotating fastener and maintained on the bearing surface, namely the first electronic device is maintained on the bearing surface, and the connection relationship between the first electronic device and the second electronic device is enhanced.

The above description of the present disclosure and the following description of the embodiments are provided to illustrate and explain the spirit and principles of the present disclosure and to provide further explanation of the scope of the present disclosure.

[ description of the drawings ]

Fig. 1 is a partially exploded perspective view of an electronic device according to an embodiment of the invention.

Fig. 2 is a partially exploded perspective view of the electronic device of fig. 1.

Fig. 3 is a partially enlarged exploded view of the rotating fastener and the transmission base of fig. 1.

Fig. 4 is a partially enlarged, side-cut-away view of the electronic device of fig. 1.

Fig. 5 is a partially enlarged view of fig. 4.

FIGS. 6-7 are schematic views illustrating operations of the electronic device shown in FIG. 1.

Fig. 8 is a partially enlarged view of fig. 7.

Fig. 9 is a partially enlarged view of the release button and the safety button of fig. 7.

Fig. 10 is a schematic view of the safety button of fig. 7 switched to a protruded position.

Fig. 11 is a schematic view of the release member of fig. 7 switched to a release position.

Fig. 12 is a schematic view of the release member of fig. 7 switched to a release position.

[ detailed description ] embodiments

The detailed features and advantages of the present invention are described in detail in the following embodiments, which are sufficient for anyone skilled in the art to understand the technical content of the present invention and to implement the present invention, and the objectives and advantages related to the present invention can be easily understood by anyone skilled in the art according to the disclosure, claims and drawings of the present specification. The following examples are intended to illustrate the invention in further detail, but are not intended to limit the scope of the invention in any way.

In addition, the embodiments of the present invention will be disclosed in the drawings and, for the purpose of clarity, numerous implementation details will be set forth in the description below. It should be understood, however, that these implementation details are not intended to limit the invention. In addition, for the sake of simplicity, some conventional structures and elements will be shown in the drawings in a simple schematic manner, and even some of the drawings omit the structures such as traces (cables, or cables) to keep the drawings clean, which is stated first.

Moreover, unless otherwise defined, all words, including technical and scientific terms, used herein have their ordinary meaning as is understood by those skilled in the art. Furthermore, the definitions of the above-mentioned words should be construed in this specification as consistent with the technical fields related to the invention. Unless specifically defined otherwise, these terms are not to be interpreted in an idealized or formal sense.

First, referring to fig. 1, a partial exploded perspective view of an electronic device according to an embodiment of the invention is shown. The embodiment provides an electronic apparatus 1000, which includes a transmission base 100, a first electronic device 200 and a second electronic device 300. It should be noted that the present invention focuses on the connection and assembly relationship between the first electronic device 200 and the transmission seat 100, and therefore fig. 1 only shows a portion of the first electronic device 200 and a portion of the second electronic device 300.

The first electronic device 200 is a tablet computer and has a display portion (not shown). The display portion is, for example, a liquid crystal display panel, and can be used for displaying a picture and executing various touch operations. In addition, the first electronic device 200 can be used as a tablet computer alone, and has a Central Processing Unit (CPU), a Hard Disk Drive (HDD), a Random Access Memory (RAM), a battery, and other electronic components, which are configured with each other to implement various functions.

The second electronic device 300 has an input portion for a user to perform input processing, such as a keyboard, a touch pad, and a plurality of operation keys (all not shown). In addition, the first electronic device 20 and the second electronic device 300 may be optionally provided with additional connection ports such as an earphone hole, a USB hole, and the like to meet various basic requirements, which is not limited in the present invention.

In the embodiment, the second electronic device 300 is pivotally connected to one side of the transmission base 100, and the docking side 201 of the first electronic device 200 is adapted to be accommodated in an accommodating groove 110S of the transmission base 100 along a carrying direction D1 to dock with a carrying surface S1 of the transmission base 100; the carrying direction D1 is substantially perpendicular to the carrying surface S1, and the carrying surface S1 of the transport stage 100 refers to an upper surface of the transport stage 100 for receiving the first electronic device 200. When the docking side 201 of the first electronic device 200 docks the carrying surface S1 of the transmission socket 100, a connector (not numbered) is disposed on the docking side 201 of the first electronic device 200 and can electrically dock with a connector (not numbered) on the carrying surface S1 of the transmission socket 100, so that the first electronic device 200 and the second electronic device 300 can exchange signals and power. For example, a signal via a keyboard, a touch pad, or an operation key on the second electronic device 300 can be transmitted to the first electronic device 200, and the first electronic device 200 can receive and react according to the signal. Thus, the first electronic device 200 and the second electronic device 300 can be assembled and disassembled, so that the electronic apparatus 1000 constitutes a so-called detachable two-in-one computer.

Next, referring to fig. 2 to 5, fig. 2 is a partial exploded perspective view of the electronic device of fig. 1, fig. 3 is a partial exploded enlarged view of the rotation fastener and the transmission seat of fig. 1, fig. 4 is a partial enlarged sectional side view of the electronic device of fig. 1, and fig. 5 is a partial enlarged view of the electronic device of fig. 4. In order to keep the components at a proper size, fig. 2 only shows a portion of the first electronic device 200 and omits the second electronic device 300, and fig. 4 omits the second electronic device 300.

In the present embodiment, the transmission base 100 includes a base body 110, two rotating fasteners 10 and two guiding frames 30. The base 110 has the carrying surface S1 for docking the first electronic device 200 and the receiving groove 110S for receiving the docking side 201 of the first electronic device 200.

In the present embodiment, the guiding frame 30 and a portion of the supporting surface S1 are formed simultaneously by using an al-mg alloy casting, and a pivot base 101 is located at the opposite side of the guiding frame 30. In other words, the guiding frame 30, a portion of the bearing surface S1, and the pivot base 101 can be integrally formed in a single alloy casting. However, in other embodiments, the pivot base 101 may be integrally formed on the base 110. The guiding frame 30 is protruded on the carrying surface S1, and the guiding frame 30 is a hollow structure with a slightly inverted U-shape. Each guide frame 30 has two opposite outer sidewalls 310 and 320; the outer sidewall 320 of each guide frame 30 has an opening 321.

Each rotating fastener 10 includes a pivot portion 11, an arm 12, a hook portion 13 and a rod 14. The pivoting portion 11 is pivotally connected to the base 110 of the transmission base 100 by a pivot axis a1 and is disposed adjacent to the outer sidewall 320 of the guiding frame 30, specifically, as shown in fig. 3, the pivoting portion 11 is placed in the pivoting base 101 below the alloy casting forming the guiding frame 30, and a pivot 9 passes through the pivoting base 101 and the pivoting portion 11, so that the rotating fastener 10 is pivotally connected to the alloy casting forming the guiding frame 30; the pivot axis a1 (i.e. the extending direction of the pivot 9) is substantially parallel to the bearing surface S1 of the transmission seat 100 (for example, from the perspective of fig. 4). The arm 12 and the hook 13 extend in sequence from the pivot 11, and the rod 14 extends from the pivot 11 in a direction opposite to the arm 12. Further, the rotating fastener 10 further includes a protrusion 15 formed at the end of the hook 13. In addition, the hook 13 has a pushed surface 131. The rotating fastener 10 can rotate about the pivot axis a1 to a locked state (i.e. the rotating fastener 10 shown in fig. 5), and when the rotating fastener 10 is in the locked state, the hook 13 of the rotating fastener 10 protrudes outward from the opening 321 of the outer sidewall 320 of the guide frame 30, so that the pushed surface 131 is exposed outside the guide frame 30.

The first electronic device 200 has two translational frames 40 located at the docking side 201 of the first electronic device 200. The translational frames 40 are two inward recessed structures at the abutting side 201 of the first electronic device 200, and the positions thereof respectively correspond to the guiding frames 30, and each translational frame 40 has two inner side walls 410 and 420 opposite to each other and two upper wall surfaces 430 and 440 respectively adjacent to the two inner side walls 410 and 420.

It is noted that the electronic apparatus 1000 of the present embodiment includes a locking mechanism 1, and when the docking side 201 of the first electronic device 200 docks the carrying surface S1 of the transmission seat 100, the locking mechanism 1 can prevent the first electronic device 200 from being detached from the transmission seat 100 and being disconnected from the second electronic device 300.

The fastening mechanism 1 is, for example, a mechanism composed of the two rotating fasteners 10, the two guiding frames 30, the two translating frames 40, a linking member 50, an elastic member 60, a releasing member 70 and a safety button 80.

The linking element 50 is slidably disposed on the base 110 of the transmission base 100, and the two rods 14 of the rotating fastener 10 simultaneously pass through the linking element 50, so that the linking element 50 is adapted to simultaneously drive the two rods 14. The elastic element 60 is an extension spring, one end of which is fixed to the seat body 110 of the transmission seat 100, and the opposite end of which is fixed to the linkage element 50, and the elastic element 60 can normally apply a pulling force in the direction of the arrow a to the linkage element 50, so that the elastic element 60 can drive the two rotary fasteners 10 to deflect to the buckling state through the linkage element 50, that is, the pushed surface 131 is exposed outside the guide frame 30. The release member 70 is fixed on one side of the linking member 50, and is used as a component for the user to operate to drive the linking member 50 to slide relative to the transmission base 100. In the present embodiment, the releasing element 70 is configured to slide between a releasing position and a locking position, and it can be understood that the elastic element 60 can normally pull the releasing element 70 to the locking position through the linking element 50 when the user does not operate the releasing element 70. The safety button 80 may be disposed inside the release member 70 in a manner orthogonal to the sliding direction of the release member 70, and the safety button 80 protrudes outward from a sliding hole 71 of the release member 70, so that a user can move the safety button 80 with a finger to switch the safety button to a protruding position or a sinking position.

Referring to fig. 6 to 8, fig. 6 to 7 are operation schematic diagrams of the electronic device of fig. 1, and fig. 8 is a partial enlarged view of fig. 7. The relative positions and the actuation relationship of the components in the latch mechanism 1 will be more clearly described through the description of assembling the first electronic device 200 and the second electronic device 300.

First, as shown in fig. 6, when a user wants to assemble the first electronic device 200 to the second electronic device 300, the first electronic device 200 may be first placed in the receiving cavity 110S of the transmission base 100 along the carrying direction D1 to be abutted to the carrying surface S1 of the transmission base 100.

In the process, the translation frame 40 is correspondingly sleeved on the guide frame 30 on the supporting surface S1 along the supporting direction D1 with the first electronic device 200. The matching of the guiding frame 30 and the translating frame 40 helps the user to assemble the first electronic device 200 in the correct direction. In addition, since the hook 13 protruding outward from the outer sidewall 320 of the guide frame 30 is located on the moving path of the inner sidewall 420 of the translation frame 40, the translation frame 40 pushes the pushed surface 131 on the hook 13 by the inner sidewall 420.

It can be understood that, in the process from fig. 6 to fig. 7, the translation frame 40 continues to move along the carrying direction D1, which forces the hook 13 to move toward the inside of the guiding frame 30 to deflect the rotating fastener 10 in the counterclockwise direction (as viewed in fig. 6), so that the inner sidewall 420 slides over the hook 13. When the abutting side 201 abuts against the bearing surface S1, the hook 13 of the rotating fastener 10 is no longer pressed by the translation frame 40, and thus the elastic element 60 can pull the rod 14 of the rotating fastener 10 in the direction of the arrow a via the linking element 50 to rotate the rotating fastener 10 clockwise (as viewed in fig. 7) to the fastened state.

As shown in fig. 8, one of the rotating fasteners 10 of fig. 7 can be clearly seen in a snap-fit condition. The hook 13 of the rotating fastener 10 is fastened to the translating frame 40 and stopped above the upper wall 440 of the translating frame 40. Further, when the rotating fastener 10 is in the fastened state, a reference line R1 parallel to the bearing direction D1 passes through the hook 13, the upper wall 440 and the pivot 9 of the pivot 11 at the same time, so that if the translational frame 40 intends to move upward (opposite to the bearing direction D1), the extension line of the force of the upper wall 440 on the hook 13 of the rotating fastener 10 will not generate a torque on the rotating fastener 10 due to passing through the pivot 9 of the pivot 11, and therefore when the first electronic device 200 intends to move away from the transmission seat 100 due to vibration or impact, the rotating fastener 10 will not rotate and the first electronic device 200 can be maintained at the position of abutting against the bearing surface S1. In other words, the probability that the rotating fastener 10 deviates from the fastening state due to the vibration or impact of the first electronic device 200 can be reduced, and the first electronic device 200 can be prevented from moving away from the transmission base 100 and separating from the transmission base 100; furthermore, the protruding point 15 of the rotating fastener 10 is engaged with the outer side of the translating frame 40, which not only can change the direction of the force applied by the translating frame 40 to the hook 13, but also can generate a torque to rotate the rotating fastener 10 toward the engaged state, and can also increase the friction between the hook 13 and the translating frame 40, which helps to reduce the probability that the rotating fastener 10 is inadvertently disengaged from the engaged state.

Next, referring to fig. 9 to 10, fig. 9 is a partially enlarged view of the release button and the safety button of fig. 7, and fig. 10 is a schematic view of switching the safety button of fig. 7 to a protruding position. In the process that the elastic member 60 pulls the rotating fastener 10 back to the locked state via the linking member 50, the releasing member 70 slides along with the linking member 50 to return to the locked position (see fig. 9). At this time, if the release button 70 is to be maintained at the engagement position, the safety button 80 may be slid upward to be switched to the protruding position. At this time, as shown in fig. 10, the safety button 80 protrudes from the upper edge of the release member 70 and enters a limiting groove (111) of the transmission seat 100, so that the safety button 80 cannot slide along with the release member 70 due to the limitation of the limiting groove 111, and further the release member 70 is limited to the fastening position and cannot be pushed by a user, thereby preventing the release member 70 from being accidentally touched to cause the rotary fastener 10 to deviate from the fastening state.

On the contrary, if the user wants to detach the first electronic device 200 from the transmission base 100, please refer to fig. 11 to 12, fig. 11 is a schematic diagram illustrating the release button of fig. 7 being switched to the release position, and fig. 12 is a schematic diagram illustrating the release button of fig. 7 being switched to the release position. The user can follow the aforementioned reverse sequence, and first slide the safety button 80 downward to the retracted position (as shown in fig. 9), and then push the release member 70 to the release position (as shown in the direction of arrow B), so as to drive the rotating fastener 10 to rotate counterclockwise (as viewed from the perspective of fig. 12) through the linking member 50, so that the rotating fastener 10 deviates from the snap-fit state to release the snap-fit relationship between the hook 13 and the translation frame 40. At this point, the first electronic device 200 can be detached from the cradle 100.

The above is a description of the structure of the electronic device 1000 and the assembling and disassembling operations by the locking mechanism 1, but the invention is not limited thereto. For example, although the sliding frame 40 of the fastening mechanism 1 includes two inner sidewalls (410 and 420) and two upper walls (430 and 440), the number of the components is not limited by the invention. For example, in other embodiments, each translational frame 40 may include only one inner sidewall and only one adjacent upper sidewall.

In addition, although the number of the rotating fasteners 10, the guiding frame 30 and the translating frame 40 in the fastening mechanism 1 is two, the number is not limited in the present invention. For example, in other embodiments, the fastening mechanism may only include a rotating fastener 10, a guiding frame 30 and a translating frame 40, and the first electronic device 200 is prevented from moving away from the cradle 100 and separating from the cradle 100.

In addition, although the locking mechanism 1 includes the linking element 50 and the elastic element 60, the linking element 50 and the elastic element 60 are optional. For example, in other embodiments, the elastic member 60 may be omitted, and the torsion springs are disposed on the two rotating fasteners 10, so as to normally bias the rotating fasteners 10 to the fastening state, and it is understood that in this embodiment, the linking member 50 may also be omitted because both rotating fasteners 10 are biased to the fastening state.

Furthermore, the release 70 and the safety button 80 are optional. For example, in other embodiments, the locking mechanism may omit both the release member 70 and the safety button 80, and the user may release the two rotating fasteners 10 from the locked state by manually moving them simultaneously.

With the above-mentioned fastening mechanism, the transmission base and the electronic device having the fastening mechanism, since the rotating fastener is rotatably disposed with the pivot axis substantially parallel to the carrying surface of the transmission base, the user only needs to butt the first electronic device (part of the screen) against the transmission base along the carrying direction substantially perpendicular to the carrying surface to complete the assembly, and the translation frame can push against and slide over the rotating fastener to complete the fastening operation. That is, the operation of the locking mechanism of the present invention is intuitive and convenient, which is helpful for users to quickly assemble the first electronic device (screen part) on the second electronic device (keyboard part).

And because the rotating fastener can be stopped on the upper wall surface of the translation frame when rotating to the buckling state, the translation frame can be limited by the rotating fastener and maintained on the bearing surface, namely the first electronic device is maintained on the bearing surface, which is beneficial to strengthening the connection relation between the first electronic device and the second electronic device, and the first electronic device is prevented from moving towards the direction far away from the transmission seat and separating from the transmission seat, thereby avoiding the first electronic device and the second electronic device from being disassembled due to impact or vibration.

In short, the fastening mechanism, the transmission seat with the fastening mechanism and the electronic device have the advantages of fast assembling a two-in-one computer, strengthening the connection between the tablet computer and the transmission seat and the like, are convenient for a user to use, and are not easy to remove the assembling relation due to impact or vibration.

Although the present invention has been described with reference to the above embodiments, it is not intended to limit the invention. All changes and modifications that come within the spirit and scope of the invention are desired to be protected. For the protection defined by the present invention, reference should be made to the appended claims.

Claims (13)

1. A latch mechanism, comprising:

at least one rotating fastener, which can rotate around a pivot axis to a fastening state;

at least one guide frame having two opposite outer sidewalls, the at least one guide frame being protruded on a bearing surface, wherein the pivot axis of the at least one rotary fastener is substantially parallel to the bearing surface, and the at least one rotary fastener protrudes out of one of the two outer sidewalls in the fastening state; and

the at least one translation frame is provided with two inner side walls opposite to each other and two upper wall surfaces adjacent to the two inner side walls respectively, when the at least one translation frame is abutted to the bearing surface, the two outer side walls are positioned between the two inner side walls, and the at least one rotation fastener can rotate to stop one of the two upper wall surfaces in the buckling state.

2. The buckle mechanism according to claim 1, wherein the at least one rotating buckle includes a pivot portion, an arm, and a hook portion, the pivot portion is disposed adjacent to one side of the at least one guiding frame along the pivot axis, and the arm and the hook portion extend from the pivot portion in sequence; when the at least one translation frame is in butt joint with the bearing surface and the at least one rotating fastener is in the buckling state, the hook part protrudes out of one of the two outer side walls and stops at one of the two upper wall surfaces.

3. The buckle mechanism according to claim 2, wherein during the process of the at least one translational frame abutting against the bearing surface along a bearing direction, one of the two inner side walls pushes against a pushed surface of the hook portion to rotate the at least one rotational buckle to deviate from the buckle state, wherein the bearing direction is substantially perpendicular to the bearing surface.

4. The buckle mechanism according to claim 2, wherein when the at least one translation frame is abutted to the bearing surface and the at least one rotation buckle is in the buckle state, a reference line parallel to the bearing direction passes through the hook portion, one of the two upper walls and the pivot portion at the same time.

5. The buckle mechanism as claimed in claim 1, further comprising a linking member and an elastic member, wherein the number of the at least one rotating fastener is two, the linking member is connected to the two rotating fasteners, and the elastic member is connected to the linking member to normally bias the two rotating fasteners to the buckle state.

6. A transmission seat adapted to be docked with a first electronic device, a docking side of the first electronic device being docked with the transmission seat along a carrying direction by at least one translation frame, the transmission seat comprising:

a seat body provided with a containing groove for containing the butt joint side edge;

at least one rotating fastener, which can rotate around a pivot axis to a fastening state; and

at least one guide frame, which has two opposite outer side walls and is convexly arranged on a bearing surface at the bottom of the accommodating groove, wherein the pivot axis of the at least one rotating fastener is substantially parallel to the bearing surface;

the at least one translation frame is provided with two inner side walls opposite to each other and two upper wall surfaces adjacent to the two inner side walls respectively, when the at least one translation frame is abutted to the bearing surface, the two outer side walls are positioned between the two inner side walls and can be used for stopping one of the two upper wall surfaces when the at least one rotation fastener rotates to the buckling state.

7. The transport base of claim 6, wherein the at least one rotation fastener includes a pivot portion, an arm and a hook portion, the pivot portion is disposed adjacent to one side of the at least one guiding frame along the pivot axis, and the arm and the hook portion extend from the pivot portion in sequence; when the at least one translation frame is abutted to the bearing surface and the at least one rotating fastener is in the buckling state, the hook part protrudes out of one of the two outer side walls and stops against one of the two upper wall surfaces, so that the first electronic device is fixed on the transmission seat.

8. The transport seat of claim 7, wherein during the process of the at least one translation frame abutting against the bearing surface along the bearing direction, one of the two inner sidewalls pushes against a pushed surface of the hook to rotate the at least one rotation fastener to deviate from the snap-fit state, wherein the bearing direction is substantially perpendicular to the bearing surface.

9. The transport pod of claim 7 wherein a reference line parallel to the load-bearing direction passes through the hook, one of the two top walls and the pivot when the translating frame is engaged with the load-bearing surface and the at least one rotating fastener is in the locked position.

10. An electronic device, comprising:

a transmission seat;

a first electronic device having a docking side and at least one translation frame, wherein the at least one translation frame is located on the docking side, and the first electronic device can be electrically docked to the transmission seat along a carrying direction;

a second electronic device, wherein the transmission seat is disposed on the second electronic device, wherein the transmission seat comprises:

a seat body provided with a containing groove for containing the butt joint side edge;

at least one rotating fastener, which can rotate around a pivot axis to a fastening state; and

at least one guide frame, which has two opposite outer side walls and is convexly arranged on a bearing surface at the bottom of the accommodating groove, wherein the pivot axis of the at least one rotating fastener is substantially parallel to the bearing surface;

the at least one translation frame is provided with two inner side walls opposite to each other and two upper wall surfaces adjacent to the two inner side walls respectively, when the at least one translation frame is abutted to the bearing surface, the two outer side walls are positioned between the two inner side walls and can be used for stopping one of the two upper wall surfaces when the at least one rotation fastener rotates to the buckling state.

11. The electronic device according to claim 10, wherein the at least one rotating fastener includes a pivot portion, an arm, and a hook portion, the pivot portion is disposed adjacent to one side of the at least one guiding frame with the pivot axis, and the arm and the hook portion extend from the pivot portion in sequence; when the at least one translation frame is in butt joint with the bearing surface and the at least one rotary fastener is in the buckling state, the hook part protrudes out of one of the two outer side walls and stops at one of the two upper wall surfaces.

12. The electronic device of claim 11, wherein one of the two inner sidewalls pushes against a pushed surface of the hook to rotate the at least one rotating fastener to deviate from the snap-fit state when the at least one translation frame is abutted to the carrying surface along the carrying direction, wherein the carrying direction is substantially perpendicular to the carrying surface.

13. The electronic device of claim 11, wherein when the translation frame is abutted to the carrying surface and the at least one rotating fastener is in the fastened state, a reference line parallel to the carrying direction passes through the hook, one of the two upper walls and the pivot.

Images