CN212862824U - Graphene copper foil diaphragm vibration discharging mechanism - Google Patents

Abstract

The utility model belongs to the technical field of discharging device, concretely relates to graphene copper foil diaphragm vibration discharging mechanism, the supporting component includes the bottom plate, bottom plate upper surface both sides are fixedly connected with backup pad respectively, be provided with the vibration frame between two the backup pad, be fixedly connected with first guide arm respectively on the both sides wall of vibration frame, two first guide arm runs through two the backup pad respectively, vibration frame lateral wall with fixedly connected with first elastic component between the backup pad lateral wall, first elastic component cover is established on the first guide arm, vibration box upper surface both sides are provided with the second guide arm that link up the vibration box respectively, on the second guide arm and be located the vibration box upper surface with the vibration frame between the top surface overlap and be equipped with the second elastic component; the utility model discloses whole vibration is effectual, can realize the quick ejection of compact of graphite alkene copper foil diaphragm, and this discharge mechanism simple structure is fit for promoting.

Description

Graphene copper foil diaphragm vibration discharging mechanism

Technical Field

The utility model belongs to the technical field of discharging device, concretely relates to graphite alkene copper foil diaphragm vibrates discharge mechanism.

Background

In recent years, with the gradual popularization and upgrading acceleration of electronic products and the increasing growth of high-integration and high-performance electronic equipment, the volume size of a working assembly is smaller, the working speed and efficiency are higher, and the heat productivity is larger. At present, the known metal heat conduction and dissipation assembly is limited by the material and the heat conduction and dissipation limit thereof, and an advanced heat conduction and dissipation process and a heat conduction and dissipation material with excellent performance are required to effectively take away heat so as to ensure the effective work of electronic products. The graphite heat conduction and dissipation material has the advantages of low density, high heat conduction and dissipation coefficient and low thermal resistance, and the graphene copper foil membrane becomes a preferred material for solving the heat conduction and dissipation technology of modern electronic products.

However, the vibration effect of the vibration discharging mechanism of the existing graphene copper foil diaphragm is poor, so that the discharging result is not ideal.

SUMMERY OF THE UTILITY MODEL

The utility model provides a graphite alkene copper foil diaphragm vibration discharge mechanism aims at solving among the above-mentioned background art current graphite alkene copper foil diaphragm's vibration discharge mechanism's vibration effect not good, leads to the unsatisfactory problem of ejection of compact result.

In order to achieve the above object, the utility model provides a following technical scheme: a vibrating discharging mechanism for a graphene copper foil diaphragm comprises a supporting assembly, a vibrating assembly and a discharging disc, wherein the supporting assembly comprises a bottom plate, and supporting plates are fixedly connected to two sides of the upper surface of the bottom plate respectively;

the vibration component comprises a vibration frame, a vibration frame is arranged between two support plates, the vibration frame is of a hollow structure, the top of the vibration frame is provided with an opening, two first guide rods are fixedly connected to two side walls of the vibration frame respectively and penetrate through the two support plates respectively, a first elastic part is fixedly connected between the side wall of the vibration frame and the side wall of the support plate, the first elastic part is sleeved on the first guide rods, a vibration box is arranged in the hollow vibration frame, two sides of the upper surface of the vibration box are respectively provided with a second guide rod penetrating through the vibration box, one end of the second guide rod is fixedly connected with the inner top surface of the vibration frame, the other end of the second guide rod is fixedly connected with the inner bottom surface of the vibration frame, and a second elastic part is sleeved on the second guide rod and positioned between the upper surface of the vibration box and the inner top surface of the vibration frame, on the second guide arm and be located vibration box lower surface with also the cover is equipped with the second elastic component between the bottom in the vibration frame, the equal fixedly connected with pivot of intermediate position department before the vibration box and on the rear surface, fixedly connected with runner on the surface of pivot, be provided with on the runner and drive the runner carries out circumference pivoted drive arrangement, surface fixed connection has the play charging tray on the vibration box.

Preferably, the driving device comprises a rotating motor and a belt, the upper surface of the base plate is provided with two rotating motors which are respectively arranged on two sides of the supporting plate, the output end of the rotating motor is connected with the rotating wheel through the belt in a transmission manner, and the rotating motors are electrically connected with an external power supply.

Preferably, the support plate is provided with a through hole corresponding to the first guide rod, the through hole is matched with the first guide rod, the first guide rod penetrates through the support plate through the through hole, and the first guide rod can slide in the through hole.

Preferably, one end of the first guide rod, which is far away from the first elastic part, is fixedly connected with a limiting block.

Preferably, guide holes corresponding to the second guide rods are respectively formed in two sides of the upper surface of the vibration box, the guide holes are matched with the second guide rods, the second guide rods penetrate through the vibration box through the guide holes, and the second guide rods can slide in the guide holes.

Preferably, the supporting component further comprises a connecting plate, the middle position of the upper surface of the vibration box is fixedly connected with the connecting plate, the top end of the connecting plate is fixedly connected with a discharge disc, and two sides of the upper surface of the discharge disc are respectively provided with a baffle for preventing the diaphragm from sliding down.

Compared with the prior art, the beneficial effects of the utility model are that: the rotating motor rotates to drive the rotating wheel to rotate, so that the vibrating box can do linear motion on the second guide rod to compress the second elastic part under the limitation of the second guide rod, the resilience force generated after the second elastic part is compressed and restored enables the vibrating box to move in the opposite direction, the vibrating box can vibrate up and down, the rotating wheel also drives the vibrating box to move left and right, the vibrating box compresses the first elastic part in the left and right movement process, the resilience force generated after the first elastic part is restored enables the vibrating box to move in the opposite direction, the first guide rods on the two side walls of the vibrating box slide back and forth in the through hole, and finally the vibrating box can vibrate up and down, left and right, so that the graphene copper foil diaphragm on the discharging tray can be discharged finally, the discharging mechanism is good in overall vibration effect, can realize quick discharge of the graphene copper foil diaphragm, and is simple in structure, is suitable for popularization.

Drawings

Fig. 1 is a schematic front view of the present invention;

FIG. 2 is a top view of the vibrating box of the present invention;

fig. 3 is a top view of the support plate of the present invention;

FIG. 4 is a top view of the discharge tray of the present invention;

in the figure: the vibration device comprises a support assembly 1, a bottom plate 11, a support plate 12, a through hole 121, a connecting plate 13, a vibration assembly 2, a vibration frame 21, a first guide rod 22, a first limiting block 221, a first elastic part 23, a vibration box 24, a guide hole 241, a second guide rod 25, a second elastic part 26, a rotating shaft 27, a rotating wheel 28, a driving device 29, a rotating motor 291, a belt 292, a discharge disc 3, a baffle 31 and a copper foil diaphragm 4-graphene.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides a technical solution: a graphene copper foil diaphragm vibration discharging mechanism comprises a supporting component 1, a vibration component 2 and a discharging disc 3, wherein the supporting component 1 comprises a bottom plate 11, and supporting plates 12 are fixedly connected to two sides of the upper surface of the bottom plate 11 respectively;

the vibration component 2 comprises a vibration frame 21, a vibration frame 21 is arranged between two support plates 12, the vibration frame 21 is of a hollow structure, the top of the vibration frame 21 is provided with an opening, two side walls of the vibration frame 21 are respectively and fixedly connected with first guide rods 22, the two first guide rods 22 respectively penetrate through the two support plates 12, a first elastic part 23 is fixedly connected between the side wall of the vibration frame 21 and the side wall of the support plate 12, the first elastic part 23 is sleeved on the first guide rods 22, a vibration box 24 is arranged in the hollow part of the vibration frame 21, two sides of the upper surface of the vibration box 24 are respectively provided with second guide rods 25 penetrating through the vibration box 24, one end of each second guide rod 25 is fixedly connected with the inner top surface of the vibration frame 21, the other end of each second guide rod 25 is fixedly connected with the inner bottom surface of the vibration frame 21, a second elastic part 26 is sleeved on each second guide rod 25 and positioned between the upper surface of the vibration box 24 and the inner top surface of the vibration frame 21, the middle positions of the front surface and the rear surface of the vibration box 24 are fixedly connected with a rotating shaft 27, the outer surface of the rotating shaft 27 is fixedly connected with a rotating wheel 28, a driving device 29 capable of driving the rotating wheel 28 to rotate circumferentially is arranged on the rotating wheel 28, and the upper surface of the vibration box 24 is fixedly connected with a discharging disc 3.

In this embodiment, two supporting plates 12 fixed on two sides of the bottom plate 11 are used for supporting, when the driving device 29 is operated, the driving wheel 28 is driven to rotate, the rotating wheel 28 rotates to drive the rotating shaft 27 to rotate, so that the vibration box 24 is limited by the second guide rods 25 on two sides, the vibration box 24 can move along the second guide rods 25, the vibration box 24 compresses the second elastic member 26 when moving downwards, the vibration box 24 further moves upwards under the action of the resilience force of the second elastic member 26 when moving upwards, so that the vibration box 24 and the vibration frame 21 vibrate up and down, the rotating wheel 28 rotates to drive the rotating shaft 27 to rotate, and simultaneously can drive the vibration box 24 to move left and right, so that the vibration frame 21 also moves left and right, the vibration frame 21 compresses the first elastic member 23 during moving left and right, and the first guide rods 22 also make reciprocating movement in the supporting plates 12, thereby realizing the left and right vibration of the vibration frame 21, finally, the vibrating box 24 drives the discharging tray 3 to vibrate, so that the material is discharged.

Further, the driving device 29 includes a rotating motor 291 and a belt 292, the rotating motor 291 is disposed on the upper surface of the bottom plate 11 and located on two sides of the two support plates 12, the output end of the rotating motor 291 is in transmission connection with the rotating wheel 28 through the belt 292, and the rotating motor 291 is electrically connected with an external power source.

In the embodiment, the output end of the rotating motor 291 starts to rotate, the belt 292 transmits transmission to the rotating wheel 28, and the rotating wheel 28 further rotates to drive the vibration box 24 to vibrate for discharging, wherein the model of the rotating motor 291 is GB/T4831-.

Furthermore, the supporting plate 12 is provided with a through hole 121 corresponding to the first guide rod 22, the through hole 121 is matched with the first guide rod 22, the first guide rod 22 penetrates through the supporting plate 12 through the through hole 121, and the first guide rod 22 can slide in the through hole 121.

In the present embodiment, the first guide rod 22 can slide in the through hole 121 through the through hole 121 adapted to the first guide rod 22, so that the vibration frame 21 moves back and forth left and right and compresses the first elastic member 23, thereby vibrating the vibration frame 21 left and right.

Furthermore, a limit block 221 is fixedly connected to one end of the first guide rod 22 away from the first elastic member 23.

In this embodiment, the limiting block 221 at one end of the first guide rod 22 is used for limiting the first guide rod 22 in the left-right reciprocating motion, so as to prevent the first guide rod 22 from sliding out of the through hole 121.

Furthermore, guide holes 241 corresponding to the second guide rods 25 are respectively formed in two sides of the upper surface of the vibration box 24, the guide holes 241 are matched with the second guide rods 25, the second guide rods 25 penetrate through the vibration box 24 through the guide holes 241, and the second guide rods 25 can slide in the guide holes 241.

In the present embodiment, the second guide rod 25 is easily inserted through the vibration box 24 through the guide hole 241 adapted to the second guide rod 25, so that the vibration box 24 can move up and down along the second guide rod 25.

Further, the supporting component 1 further comprises a connecting plate 13, the middle position of the upper surface of the vibration box 24 is fixedly connected with the connecting plate 13, the top end of the connecting plate 13 is fixedly connected with a discharge disc 3, and two sides of the upper surface of the discharge disc 3 are respectively provided with a baffle 31 for preventing the graphene copper foil membrane 4 from sliding off.

In this embodiment, install fixed ejection of compact dish 3 through connecting plate 13 to when vibration box 24 vibrates about last, drive ejection of compact dish 3 and vibrate the ejection of compact, the baffle 31 of ejection of compact dish 3 upper surface both sides for prevent the landing of graphite alkene copper foil diaphragm 4 in the vibration ejection of compact in-process.

The utility model discloses a theory of operation and use flow: after the utility model is installed, when the driving device 29 works, the driving wheel 28 is driven to rotate, the rotating wheel 28 rotates to drive the rotating shaft 27 to rotate, so that the vibration box 24 is limited by the second guide rods 25 at both sides, the vibration box 24 can move along the second guide rods 25, the vibration box 24 compresses the second elastic part 26 when moving downwards, the vibration box 24 further moves upwards under the resilience force of the second elastic part 26 when moving upwards, so that the vibration box 24 and the vibration frame 21 vibrate up and down, the rotating wheel 28 rotates to drive the rotating shaft 27 to rotate, and simultaneously can drive the vibration box 24 to move left and right, and also drive the vibration frame 21 to move left and right, the vibration frame 21 compresses the first elastic part 23 during moving left and right, and also make the first guide rod 22 do reciprocating back and forth movement in the supporting plate 12, thereby realizing the left and right vibration of the vibration frame 21, and finally making the vibration box 24 drive the discharging tray 3 to vibrate, thereby carrying out the discharging of the materials.

The above description is only exemplary of the present invention and should not be construed as limiting the present invention, and any modifications, equivalents and improvements made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims (6)

1. The utility model provides a graphite alkene copper foil diaphragm vibration discharge mechanism, includes supporting component (1), vibration subassembly (2) and goes out workbin (3), its characterized in that: the supporting component (1) comprises a bottom plate (11), and supporting plates (12) are fixedly connected to two sides of the upper surface of the bottom plate (11) respectively;

the vibration component (2) comprises a vibration frame (21), the vibration frame (21) is arranged between two support plates (12), the vibration frame (21) is of a hollow structure, an opening is formed in the top of the vibration frame (21), first guide rods (22) are fixedly connected to two side walls of the vibration frame (21) respectively, the two first guide rods (22) penetrate through the two support plates (12) respectively, first elastic pieces (23) are fixedly connected between side walls of the vibration frame (21) and side walls of the support plates (12), the first elastic pieces (23) are sleeved on the first guide rods (22), a vibration box (24) is arranged in the hollow portion of the vibration frame (21), second guide rods (25) penetrating through the vibration box (24) are arranged on two sides of the upper surface of the vibration box (24) respectively, one end of each second guide rod (25) is fixedly connected with the inner top surface of the vibration frame (21), second guide arm (25) the other end with bottom fixed connection in vibration frame (21), just be located on second guide arm (25) vibration box (24) upper surface with the cover is equipped with second elastic component (26) between vibration frame (21) the interior top surface, just be located on second guide arm (25) vibration box (24) lower surface with also the cover is equipped with second elastic component (26) between the bottom in vibration frame (21), vibration box (24) preceding and the rear surface on the equal fixedly connected with pivot (27) of intermediate position department, fixedly connected with runner (28) on pivot (27) surface, be provided with on runner (28) and drive runner (28) carry out circumference pivoted drive arrangement (29), vibration box (24) upper surface fixed connection has ejection of compact dish (3).

2. The vibrating and discharging mechanism for the graphene copper foil membrane as claimed in claim 1, wherein: the driving device (29) comprises a rotating motor (291) and a belt (292), the rotating motor (291) is arranged on the upper surface of the bottom plate (11) and positioned on two sides of the supporting plate (12), the output end of the rotating motor (291) is in transmission connection with the rotating wheel (28) through the belt (292), and the rotating motor (291) is electrically connected with an external power supply.

3. The vibrating and discharging mechanism for the graphene copper foil membrane as claimed in claim 1, wherein: the supporting plate (12) is provided with a through hole (121) corresponding to the first guide rod (22), the through hole (121) is matched with the first guide rod (22), the first guide rod (22) penetrates through the supporting plate (12) through the through hole (121), and the first guide rod (22) can slide in the through hole (121).

4. The vibrating and discharging mechanism for the graphene copper foil membrane as claimed in claim 3, wherein: one end of the first guide rod (22) far away from the first elastic part (23) is fixedly connected with a limiting block (221).

5. The vibrating and discharging mechanism for the graphene copper foil membrane as claimed in claim 1, wherein: guide holes (241) corresponding to the second guide rods (25) are respectively formed in two sides of the upper surface of the vibration box (24), the guide holes (241) are matched with the second guide rods (25), the second guide rods (25) penetrate through the vibration box (24) through the guide holes (241), and the second guide rods (25) can slide in the guide holes (241).

6. The vibrating and discharging mechanism for the graphene copper foil membrane as claimed in claim 1, wherein: the supporting component (1) further comprises a connecting plate (13), the middle position of the upper surface of the vibration box (24) is fixedly connected with the connecting plate (13), the top end of the connecting plate (13) is fixedly connected with a discharge disc (3), and two sides of the upper surface of the discharge disc (3) are respectively provided with a baffle (31) for preventing the graphene copper foil diaphragm (4) from sliding down.

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