CN111648678A

CN111648678A - Locking and pop-up mechanism suitable for sharing mobile power supply with different thicknesses

Info

Publication number: CN111648678A
Application number: CN202010433525.XA
Authority: CN
Inventors: 钟发平; 张伟扬
Original assignee: Yiyang Corun Battery Co ltd
Current assignee: Yiyang Corun Battery Co ltd
Priority date: 2020-05-21
Filing date: 2020-05-21
Publication date: 2020-09-11
Anticipated expiration: 2040-05-21
Also published as: CN111648678B

Abstract

The invention provides a locking and ejecting mechanism suitable for sharing a mobile power supply with different thicknesses, wherein two locking arms are respectively arranged in two fixed supporting frames of a mobile power supply bin in a mode that locking blocks are opposite, a gap of horizontal parts of the locking blocks penetrates through a locking block through hole of the mobile power supply bin, an electromagnet is arranged in an electromagnet support, a cam in a trapezoidal structure is arranged at the top of a shaft of the electromagnet, the cam is arranged between the two locking arms, top parts of two sides of the cam are respectively contacted with a roller at the outer end of the horizontal part of the corresponding locking arm, a glass bead spring is sleeved at the bottom of the mobile power supply bin in a penetrating way that through holes are arranged on screw columns of the mobile power supply bin in a one-to-one correspondence mode, bosses are nested in boss through holes of the mobile power supply bin in a one-to-one correspondence mode, and convex ribs. The portable power supply is simple in structure, convenient to take out and load, suitable for portable power supplies with different thicknesses and good in universality.

Description

Locking and pop-up mechanism suitable for sharing mobile power supply with different thicknesses

Technical Field

The invention relates to a locking and ejecting mechanism suitable for sharing a mobile power supply with different thicknesses.

Background

Along with the popularization of smart phones, tablet computers and related mobile electronic products, mobile equipment develops rapidly, functions of the mobile equipment are diversified more and more, the demand for electric quantity of the mobile equipment is increased increasingly while the functions are diversified, the battery endurance of the mobile equipment cannot be improved greatly all the time, and the power failure of the mobile equipment becomes a trouble of many people in a critical time. In order to solve the problem of insufficient electric quantity, the mobile power supply is widely applied to mobile phones, tablet computers and related electronic products, but sometimes the mobile power supply or the portable mobile power supply is forgotten to be taken, and in order to meet the requirements of customers, a shared mobile power supply appears, and only the customers pay for renting. However, the portable power source may be dropped and damaged due to the fact that the portable power source is not installed when the portable power source is used by multiple persons, and a higher requirement is made on the convenience of taking out the portable power source. At present, products on the market generally only use a locking and ejecting mechanism for a mobile power supply with the same thickness, and the universality is poor.

Disclosure of Invention

The invention aims to provide a locking and ejecting mechanism which is simple in structure, convenient for taking out and putting in a mobile power supply and good in universality and is suitable for sharing the mobile power supply with different thicknesses.

The invention is realized by the following scheme:

a locking and ejecting mechanism suitable for sharing a mobile power supply with different thicknesses comprises a mobile power supply bin, two locking arms, an electromagnet and two pressing plates, wherein a plurality of through holes are formed in the pressing plates, two symmetrical bosses are arranged on the inward surfaces of the pressing plates, a plurality of convex ribs are arranged on the top surfaces of the bosses, and elastic sheets are arranged on the convex ribs; the left side and the right side of the mobile power supply bin are respectively provided with a fixed support frame near the bottom, the lower end part of the fixed support frame exceeds the bottom of the mobile power supply bin, the left side and the right side of the mobile power supply bin are respectively provided with a locking block perforation at the position above the fixed support frame, the front side and the rear side of the mobile power supply bin are respectively provided with two boss perforations which are bilaterally symmetrical and a plurality of screw columns, and the whole fixed support frame is of a through groove structure; the locking arm is integrally L-shaped, the outer end of the horizontal part of the locking arm is provided with a roller, the upper end of the vertical part of the locking arm is provided with a transverse T-shaped locking block, and the locking block has certain flexibility and elasticity; two locking arms are respectively installed in two fixed support frames of a mobile power supply bin in a mode that locking blocks are opposite, a gap of the horizontal part of each locking block penetrates through a locking block hole of the mobile power supply bin and is arranged in the mobile power supply bin, the lower end part of the vertical part of each locking arm is exposed out of the fixed support frame, the locking blocks are arranged in the mobile power supply bin, the locking blocks are partially clamped in clamping grooves on the corresponding side of the mobile power supply to realize locking of the mobile power supply, the locking arms can transversely move in the fixed support frames, electromagnets are installed in electromagnet supports and can move in the electromagnet supports along the direction parallel to the axes of the electromagnets, cams in a trapezoidal structure are installed at the tops of the axes of the electromagnets, the cams are arranged between the two locking arms, the top end parts of the two sides of the cams are respectively contacted with rollers at the outer ends of the horizontal parts of the corresponding locking arms, a glass bead spring is, the glass bead spring is located above the cam, when the mobile power supply is arranged in the mobile power supply bin, the glass bead spring is in a compressed state, the two pressing plates are respectively arranged on the front side and the rear side of the mobile power supply bin in a mode that the through holes are sleeved on the screw posts of the mobile power supply bin in a one-to-one correspondence mode, the bosses are nested in the boss through holes of the mobile power supply bin in a one-to-one correspondence mode, and the convex ribs are partially arranged in the mobile power supply bin. Softness and the elasticity of locking piece can design as required to thereby portable power source can be extruded and buckle at the in-process locking piece of packing into and make portable power source extrusion locking arm lateral shifting outwards, and the locking piece rebounds easily under the elastic force and clamps in the draw-in groove of portable power source corresponding side can. In actual manufacturing, the locking arm needs to move transversely in the fixed support frame, and the implementation mode can be designed according to needs, for example, a guide rail can be arranged on the inner side wall of the fixed support frame, and the locking arm can be arranged on the guide rail in a straddling manner; or two sides of the bottom of the lower end of the fixed support frame are provided with locking arm mounting clamping grooves, and the locking arms are clamped in the locking arm mounting clamping grooves. The number of the fixing pins can be designed according to needs, and the arrangement mode of the plurality of fixing pins can be adjusted and designed according to needs. The number of the through holes of the pressing plate is the same as that of the screw posts corresponding to the mobile power supply bin, and the number and the arrangement positions of the through holes and the screw posts can be adjusted and designed as required so as to meet the requirement that the pressing plate and the mobile power supply bin are installed together. The quantity of the convex rib of the pressing plate boss can be adjusted and designed as required, and the convex rib plays a role in compressing the mobile power supply.

Furthermore, the locking and ejecting mechanism suitable for sharing the mobile power supply with different thicknesses further comprises a pressing plate ejecting auxiliary component, the whole pressing plate ejecting auxiliary component is of a U-shaped structure, and tops of two sides of the pressing plate ejecting auxiliary component are of wedge-shaped structures rising inwards; the clamp plate is provided with inside cavity and bottom and clamp plate bottom parallel and level and opening, top closure and for the bulge of the inclined plane structure that rises inwards on the one side outwards, the clamp plate is flicked the auxiliary component and is installed in the top of cam and the supporting laminating in the both sides upper end of clamp plate flicking auxiliary component and install in the bulge of corresponding clamp plate, and the glass pearl spring is located the clamp plate flicking auxiliary component bottom top. In actual manufacturing, in order to reduce the weight of the pressing plate springing auxiliary component, the inward surface of the pressing plate springing auxiliary component is set to be a hollow structure, and a plurality of lightening holes can be formed in two sides of the pressing plate springing auxiliary component.

Furthermore, at least one fixed pin mounting through hole is formed in the bottom of the lower end groove of the fixed support frame, at least one fixed pin is vertically arranged at the lower end of the vertical part of the locking arm, and the at least one fixed pin of the locking arm is arranged in the fixed pin mounting through hole of the fixed support frame in a one-to-one corresponding clearance mode and is partially exposed.

Furthermore, a first reset spring is installed on the exposed part of the fixed pin, the first reset spring is limited by the end part of the fixed pin and the fixed support frame, and the first reset spring is in a semi-compression state.

Further, a second reset spring is sleeved on a screw post of the mobile power supply bin, and a gasket is installed on the outer end face of the screw post. The gasket can limit the second reset spring and the pressure plate to prevent

Furthermore, both sides of the lower end of the fixed support frame are respectively provided with a protective baffle extending back to the opening direction of the fixed support frame.

Furthermore, the rear side or the front side and the rear side of the mobile power supply cabin are provided with fixed clamping seats. The mobile power supply bin can be conveniently fixed by the arrangement of the fixed clamping seat.

The locking and popping mechanism suitable for the shared mobile power supplies with different thicknesses is simple in structure, convenient to use, safe, reliable, low in error rate, suitable for the shared mobile power supplies with different thicknesses, and good in universality, and the mobile power supplies can be conveniently taken out and put in.

Drawings

Fig. 1(a) is a schematic overall structure diagram (a) of a locking and ejecting mechanism of a shared mobile power supply applicable to different thicknesses in embodiment 1;

fig. 1(b) is a schematic view (two) of the overall structure of the locking and ejecting mechanism of the sharing mobile power supply with different thicknesses in embodiment 1;

fig. 2 is an exploded view of a locking and ejecting mechanism of a shared mobile power supply with different thicknesses in embodiment 1;

fig. 3(a) is a side sectional view of a locking and ejecting mechanism of a shared mobile power supply applicable to different thicknesses in embodiment 1;

fig. 3(b) is a front sectional view of the locking and ejecting mechanism of the shared mobile power supply applicable to different thicknesses in embodiment 1;

FIG. 4 is a schematic view showing the structure of a platen in example 1;

fig. 5(a) is a schematic structural diagram (one) of the mobile power supply bin in embodiment 1;

fig. 5(b) is a schematic structural diagram of the mobile power supply cabin in embodiment 1 (ii);

FIG. 6 is a schematic view showing the installation of the pressing plate ejection assisting member and the cam in embodiment 1;

fig. 7 is a schematic structural view of a lock arm in embodiment 1.

Detailed Description

The invention is further illustrated by the following figures and examples, but the invention is not limited to the examples.

Example 1

A locking and ejecting mechanism suitable for sharing a mobile power supply with different thicknesses is shown in figures 1(a), 1(b), 2, 3(a) and 3(b), and comprises a mobile power supply bin 1, two locking arms 2, an electromagnet 3, two pressing plates 4 and a pressing plate ejecting auxiliary component 5; as shown in fig. 4, four through holes 41 are formed on the pressing plate 4, two symmetrical bosses 42 are arranged on the inward surface of the pressing plate 4, two convex ribs 43 are arranged on the top surfaces of the bosses 42, elastic pieces 45 are arranged on the convex ribs 43, and a convex part 44 which is hollow and has a bottom which is flush with the bottom of the pressing plate 4, an opening and a closed top and is in an inward ascending slope structure is arranged on the outward surface of the pressing plate 4;

as shown in figure 5(a), as shown in fig. 5(b), the left and right sides of the mobile power supply bin 1 near the bottom are respectively provided with a fixed support frame 11, the lower end part of the fixed support frame 11 exceeds the bottom of the mobile power supply bin 1, the left and right sides of the mobile power supply bin 1 above the fixed support frame 11 are respectively provided with a locking block through hole 12, the front and back sides of the mobile power supply bin 1 are respectively provided with two boss through holes 13 and four screw posts 14 which are bilaterally symmetrical, the fixed support frame 11 is integrally in a through groove structure, the bottom of the fixed support frame 11 is provided with two fixed pin mounting through holes 111 which are longitudinally arranged up and down, the two sides of the bottom of the fixed support frame 11 are provided with locking arm mounting slots 112, the two sides of the lower end of the fixed support frame 11 are respectively provided with a protective baffle 113 extending in a direction away from;

as shown in fig. 6, the pressing plate flicking auxiliary component 5 is integrally of a U-shaped structure, tops of two sides of the pressing plate flicking auxiliary component 5 are of wedge-shaped structures rising inwards, an inwards surface of the pressing plate flicking auxiliary component 5 is of a hollow structure, and two weight-reducing holes 51 are respectively formed in two sides of the pressing plate flicking auxiliary component 5;

as shown in fig. 7, the locking arm 2 is L-shaped as a whole, the outer end of the horizontal portion of the locking arm 2 is provided with a roller 21, the upper end of the vertical portion of the locking arm 2 is provided with a locking block 22 in a transverse T shape, the locking block 22 has certain flexibility and elasticity, and the lower end of the vertical portion of the locking arm 2 is vertically provided with two vertically arranged fixing pins 23;

as shown in fig. 1(a), fig. 1(b) and fig. 3, two locking arms 2 are respectively installed in two fixed support frames 11 of a mobile power supply bin 1 in a manner that locking blocks 22 are opposite, a horizontal part of each locking block 22 penetrates through a locking block through hole 12 of the mobile power supply bin 1 and is placed in the mobile power supply bin 1, two fixed pins 23 of each locking arm 2 are installed in fixed pin installation through holes 111 of the fixed support frames 11 in a one-to-one correspondence clearance manner and are partially exposed, a first return spring 24 is installed on an exposed part of each fixed pin 23, the first return spring 24 is limited by the end part of each fixed pin 23 and the fixed support frame 11, the first return spring 24 is in a semi-compression state, the lower end part of the vertical part of each locking arm 2 is exposed out of the fixed support frame 11, the locking block 22 is placed in the mobile power supply bin 1 and is partially clamped in a, the locking arms 2 can transversely move in the fixed support frame 11, the electromagnet 3 is arranged in the electromagnet support frame 6, the electromagnet 3 can move in the electromagnet support frame 6 along the direction parallel to the axis of the electromagnet 3, the top of the axis of the electromagnet 3 is provided with a cam 7 in a trapezoidal structure, the cam 7 is arranged between the two locking arms 2, the top end parts of the two sides of the cam 7 are respectively contacted with the rollers 21 at the outer ends of the horizontal parts of the corresponding locking arms 2, the pressing plate flicking auxiliary component 5 is arranged at the top of the cam 7, the upper ends of the two sides of the pressing plate flicking auxiliary component 5 are matched and attached in the convex part 44 of the corresponding pressing plate 4, the bottom of the mobile power supply bin 1 is sleeved with a glass bead spring 8, the upper end part of the glass bead spring 8 is arranged in the mobile power supply bin 1, the glass bead spring 8 is positioned above the cam 7, and the glass, when a mobile power supply is loaded into the mobile power supply cabin 1, the glass bead springs 8 are in a compressed state, the two pressing plates 4 are respectively installed on the front side and the rear side of the mobile power supply cabin 1 in a mode that the through holes 41 are sleeved on the screw posts 14 of the mobile power supply cabin 1 in a one-to-one corresponding mode, the bosses 42 are nested in the boss through holes 13 of the mobile power supply cabin 1 in a one-to-one corresponding mode, and the convex ribs 43 are partially arranged in the mobile power supply cabin 1, the screw posts 14 are sleeved with the second reset springs 15, the gaskets 16 are installed on the outer end faces of the screw posts 14, and.

When needs installation locking portable power source (the treasured that charges promptly), pack into portable power source to the portable power source storehouse inwards gradually, because the locking piece has certain compliance and elasticity, thereby portable power source can be buckled by the extrusion at the in-process locking piece of packing into and makes portable power source extrusion locking arm lateral shifting outwards, and the locking piece rebounds easily under the elastic action and clamps in the draw-in groove of the corresponding side of portable power source, the protruding muscle of clamp plate boss compresses tightly portable power source simultaneously, thereby accomplish the portable power source locking in the portable power source storehouse, the glass pearl spring is in compression state this moment. When the mobile power supply needs to be taken out, the control unit controls the electromagnet to be powered on, the shaft of the electromagnet moves upwards, the shaft drives the cam to move upwards, the cam pushes and pushes the two locking arms to move outwards and transversely in the upward moving process, so that the locking block is separated from the clamping groove of the mobile power supply, meanwhile, the cam drives the pressing plate flicking auxiliary component to move upwards in the upward moving process, the pressing plate flicking auxiliary component pushes and pushes the pressing plate to move outwards under the extrusion acting force, so that the convex rib of the pressing plate boss does not press the mobile power supply any more, after the locking block is completely separated and the convex rib of the pressing plate boss is separated from the mobile power supply, the spring force of the glass bead spring pushes the mobile power supply to move upwards, at the moment, the mobile power supply is taken out, after the mobile power supply is taken out, the electromagnet is powered off, the shaft of the electromagnet drives the cam, the locking arm is reset under the spring force of the first return spring, and the pressing plate is reset under the spring force of the second return spring.

Considering that the shared mobile power supply needs to be charged, the mobile power supply bin can be installed on the shared charging cabinet through the fixed clamping seat, the electromagnet support is installed on the shared charging cabinet, the charging unit of the shared charging cabinet is inserted into the corresponding position of the bottom of the mobile power supply bin, and after the mobile power supply is installed in the mobile power supply bin, the mobile power supply can be controlled to start charging through the control unit.

Example 2

The utility model provides a be suitable for different thickness sharing portable power source locking and pop-up mechanism which the structure is similar with the structure that is suitable for different thickness sharing portable power source locking and pop-up mechanism in embodiment 1, its difference lies in: the number of the fixed pins is one, and the rear side of the mobile power supply bin is provided with a fixed clamping seat.

Example 3

The utility model provides a be suitable for different thickness sharing portable power source locking and pop-up mechanism which the structure is similar with the structure that is suitable for different thickness sharing portable power source locking and pop-up mechanism in embodiment 1, its difference lies in: the two fixing pins are horizontally arranged side by side.

Claims

1. The utility model provides a be suitable for different thickness sharing portable power source's locking and pop-up mechanism which characterized in that: the portable power supply comprises a mobile power supply bin, two locking arms, an electromagnet and two pressing plates, wherein a plurality of through holes are formed in the pressing plates, two symmetrical bosses are arranged on the inward surfaces of the pressing plates, a plurality of convex ribs are arranged on the top surfaces of the bosses, and elastic pieces are arranged on the convex ribs; the left side and the right side of the mobile power supply bin are respectively provided with a fixed support frame near the bottom, the lower end part of the fixed support frame exceeds the bottom of the mobile power supply bin, the left side and the right side of the mobile power supply bin are respectively provided with a locking block perforation at the position above the fixed support frame, the front side and the rear side of the mobile power supply bin are respectively provided with two boss perforations which are bilaterally symmetrical and a plurality of screw columns, and the whole fixed support frame is of a through groove structure; the locking arm is integrally L-shaped, the outer end of the horizontal part of the locking arm is provided with a roller, the upper end of the vertical part of the locking arm is provided with a transverse T-shaped locking block, and the locking block has certain flexibility and elasticity; two locking arms are respectively installed in two fixed support frames of a mobile power supply bin in a mode that locking blocks are opposite, a gap of the horizontal part of each locking block penetrates through a locking block hole of the mobile power supply bin and is arranged in the mobile power supply bin, the lower end part of the vertical part of each locking arm is exposed out of the fixed support frame, the locking blocks are arranged in the mobile power supply bin, the locking blocks are partially clamped in clamping grooves on the corresponding side of the mobile power supply to realize locking of the mobile power supply, the locking arms can transversely move in the fixed support frames, electromagnets are installed in electromagnet supports and can move in the electromagnet supports along the direction parallel to the axes of the electromagnets, cams in a trapezoidal structure are installed at the tops of the axes of the electromagnets, the cams are arranged between the two locking arms, the top end parts of the two sides of the cams are respectively contacted with rollers at the outer ends of the horizontal parts of the corresponding locking arms, a glass bead spring is, the glass bead spring is located above the cam, when the mobile power supply is arranged in the mobile power supply bin, the glass bead spring is in a compressed state, the two pressing plates are respectively arranged on the front side and the rear side of the mobile power supply bin in a mode that the through holes are sleeved on the screw posts of the mobile power supply bin in a one-to-one correspondence mode, the bosses are nested in the boss through holes of the mobile power supply bin in a one-to-one correspondence mode, and the convex ribs are partially arranged in the mobile power supply bin.

2. The locking and ejecting mechanism for the shared mobile power supply with different thicknesses as claimed in claim 1, wherein: the pressing plate flicking auxiliary component is of a U-shaped structure as a whole, and the tops of two sides of the pressing plate flicking auxiliary component are of wedge-shaped structures rising inwards; the clamp plate is provided with inside cavity and bottom and clamp plate bottom parallel and level and opening, top closure and for the bulge of the inclined plane structure that rises inwards on the one side outwards, the clamp plate is flicked the auxiliary component and is installed in the top of cam and the supporting laminating in the both sides upper end of clamp plate flicking auxiliary component and install in the bulge of corresponding clamp plate, and the glass pearl spring is located the clamp plate flicking auxiliary component bottom top.

3. The locking and ejecting mechanism for the shared mobile power supply with different thicknesses as claimed in claim 2, wherein: at least one fixed pin mounting through hole is formed in the bottom of the lower end groove of the fixed support frame, at least one fixed pin is vertically arranged at the lower end of the vertical part of the locking arm, and the at least one fixed pin of the locking arm is mounted in the fixed pin mounting through hole of the fixed support frame in a one-to-one corresponding clearance mode and partially exposed.

4. The locking and ejecting mechanism for the shared mobile power supply with different thicknesses as claimed in claim 3, wherein: the fixing pin is characterized in that a first reset spring is mounted on the exposed part of the fixing pin, the first reset spring is limited by the end part of the fixing pin and the fixing support frame, and the first reset spring is in a semi-compression state.

5. The locking and ejecting mechanism for the shared mobile power supply with different thicknesses as claimed in claim 1, wherein: a second reset spring is sleeved on a screw post of the mobile power supply bin, and a gasket is installed on the outer end face of the screw post.

6. The locking and ejecting mechanism suitable for the shared mobile power supply with different thicknesses as claimed in any one of claims 1 to 5, wherein: and two sides of the lower end of the fixed support frame are respectively provided with a protective baffle extending back to the opening direction of the fixed support frame.

7. The locking and ejecting mechanism suitable for the shared mobile power supply with different thicknesses as claimed in any one of claims 1 to 5, wherein: and the rear side or the front side and the rear side of the mobile power supply bin are provided with fixed clamping seats.