CN109685999B - Leasing equipment - Google Patents

Abstract

The present application relates to a rental apparatus that includes an access mechanism for storing rentable electronic devices. The access mechanism comprises a hollow shell, and an elastic energy storage part and a lock catch which are fixedly arranged on the shell. The inner cavity of the shell is used for storing the electronic device, the elastic energy storage part is connected with the pushing part in a sliding way, the speed reducing part is connected between the pushing part and the shell in a sliding way, and the pushing part at least partially stretches into the inner cavity and is elastically abutted to the electronic device, and the lock catch is used for locking the electronic device in the inner cavity. When the lock catch unlocks the electronic device, the elastic acting force of the elastic energy storage part drives the pushing part to push the electronic device out of the opening from the inner cavity, and the speed reducing part acts on the electronic device to control the moving speed of the electronic device relative to the inner cavity. According to the electronic device access mechanism, the elastic energy storage part can be arranged to ensure the pushing-out of the electronic device by larger elastic force through the speed control of the speed reduction part, and the electronic device is prevented from sliding off through the speed reduction part.

Description

Leasing equipment

Technical Field

The present application relates to the field of public apparatuses, and in particular, to a rental apparatus for storing electronic devices available for rental.

Background

The electronic device which is represented by the rentable mobile power supply and can be rented has higher practical value because of the convenience and availability. For example, when the user goes out and needs to charge electronic products such as a mobile terminal, the mobile terminal can be rented by the portable power source, and convenience is brought to the user. Existing rental equipment, typically portable power rental equipment, for storing electronic devices is typically provided with multiple access mechanisms for storing and locking the electronic devices. When the user rents the electronic device, the access mechanism unlocks the electronic device by the mobile phone code scanning, and the electronic device is taken out by manual operation or automatic carrying out of the access mechanism. When the user returns the electronic device, the electronic device is only required to be placed at the bin gate of the access mechanism, and the electronic device is manually pushed in or automatically sucked and locked by the access mechanism. When the electronic device is manually accessed, in order to avoid the electronic device being too tightly clamped with the access mechanism, the access mechanism needs to be provided with a spring at the bottom of the electronic device to eject the electronic device out of the bin opening, so that the electronic device is convenient for a user to take. However, when the spring force is too large, the electronic device is easy to be ejected integrally to cause falling, and when the spring force is too small, the electronic device can not be ejected or the ejection length is insufficient. The access mechanism for automatically sucking and carrying out the electronic device is relatively complex in structure, and usually needs to be driven by a motor, and is assisted by a position sensor to detect the position of the electronic device, so that the electronic device can be completely accommodated and locked.

On the other hand, electronic device rental equipment represented by a portable power source, a portable electronic terminal, and the like is generally provided with a charging function, and after the access mechanism sucks the electronic device, a charging pin at the bottom of the access mechanism contacts with a charging interface of the electronic device to realize charging. Because the travel of the electronic device relative to the access mechanism is larger, the accuracy of the electric suction device is difficult to control, and the phenomenon that the electronic device is in poor contact with the charging spring needle or the charging spring needle is excessively pressed and damaged is caused. After the electronic device is leased for a long time, the outer surface of the electronic device is easy to be deformed such as bulge or the like, or a user does not completely store a charging wire of the electronic device, so that a gap between the electronic device and an access mechanism is easily blocked, friction force is increased, and the electronic device is difficult to access.

Disclosure of Invention

The application aims to provide a leasing device comprising an access mechanism with a mechanical principle, which can help a user to conveniently access an electronic device stored on the leasing device. The method specifically comprises the following technical scheme:

The access mechanism comprises a hollow shell, an opening is formed in one side of the shell, the electronic device enters the shell from the opening and is contained in an inner cavity of the shell, an elastic energy storage part and a lock catch are further fixedly arranged on the shell, the elastic energy storage part is slidably connected with a pushing part, a speed reducing part is slidably connected between the pushing part and the shell, the pushing part at least partially stretches into the inner cavity and is propped against the electronic device under the elastic action of the elastic energy storage part, the sliding direction of the pushing part is parallel to the direction of the electronic device entering the inner cavity, the lock catch is used for locking the electronic device in the inner cavity, and when the lock catch unlocks the electronic device, the elastic acting force of the elastic energy storage part drives the pushing part to push the electronic device out of the opening from the inner cavity, and the speed reducing part acts on the electronic device to control the moving speed of the electronic device relative to the inner cavity.

The pushing part is a sliding support, a containing bin is arranged in the sliding support, an outlet of the containing bin is perpendicular to the direction of the electronic device entering the inner cavity, and the outlet is used for allowing the electronic device to pass through and be placed in the containing bin.

The inner cavity comprises a first inner wall opposite to the outlet and a second inner wall opposite to the first inner wall, the elastic energy storage part is fixedly arranged on one side of the shell close to the first inner wall, and the speed reducing part is arranged on one side of the shell close to the second inner wall.

The electronic device is provided with a data line, and a groove is formed in the inner wall of one side of the inner cavity and used for accommodating the data line when the electronic device enters the inner cavity.

The electronic device or the pushing part is provided with a clamping groove matched with the lock catch, and when the electronic device is accommodated in the inner cavity, the lock catch stretches into the clamping groove to lock the electronic device in the inner cavity.

The electronic device access mechanism further comprises a circuit board, the lock catch is an electric control lock catch, the circuit board is electrically connected with the lock catch, and the circuit board is used for controlling unlocking action of the lock catch.

The electronic device comprises a relative extending end and a pushing end, the extending end extends into the inner cavity before the pushing end, the extending end is provided with a charging port, the inner cavity comprises a bottom wall opposite to the opening, the bottom wall is provided with a charging connector, the charging port is matched with the charging connector in position, and when the electronic device is locked in the inner cavity by the lock catch, the charging connector is in contact with the charging port and charges the electronic device.

The pushing part is provided with a stop part in a protruding way at one side far away from the electronic device, the shell is provided with a stop surface matched with the stop part, and the stop surface is used for propping against the stop part to control the pushing-out stroke of the pushing part in the process that the pushing part pushes the electronic device out of the inner cavity.

The opening is provided with an openable dust cover, and the dust cover is used for sealing the opening.

The leasing equipment is used for storing a leasable mobile power supply or a portable electronic terminal.

According to the leasing equipment, the electronic device is stored through the access mechanism. The access mechanism is opened at one side of the hollow shell, so that the electronic device enters from the opening and is accommodated in the inner cavity. And locking the electronic device in the inner cavity through the lock catch. The action of pushing the electronic device out of the inner cavity is realized through the elastic energy storage part fixedly arranged on the shell and the pushing part connected with the elastic energy storage part. The electronic device is slowed down relative to the moving speed of the inner cavity through the action of the speed reducing part which is also fixedly arranged on the shell, so that the danger that the electronic device is rapidly pushed out of the inner cavity to drop due to overlarge elasticity of the elastic energy storage part is avoided. Therefore, the elastic force of the elastic energy storage part can be correspondingly increased, and the electronic device can be smoothly pushed out of the inner cavity. The renting equipment can automatically and stably send out the electronic device through the access mechanism, and has the characteristics of simple structure and higher reliability compared with an electric driving scheme.

Drawings

FIG. 1 is a schematic diagram of an access mechanism of the rental apparatus of the present application;

FIG. 2 is a schematic view of an elastic energy storage section according to the present application;

FIG. 3 is a schematic view of the access mechanism of the present application from another perspective than that of FIG. 1;

FIG. 4 is a schematic view of the deceleration section of the present application;

FIG. 5 is a schematic cross-sectional view of an access mechanism according to the present application;

FIG. 6 is a schematic diagram of a front view of the access mechanism of the present disclosure;

FIG. 7 is a schematic cross-sectional view of another embodiment of the access mechanism of the present application.

Detailed Description

The following description of the embodiments of the present application will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the application. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

For convenience of description, the rental device of the present application is specifically described with a rental device capable of renting a mobile power supply as a specific embodiment. It can be understood that the mobile power supply 200 in the following embodiments is an electronic device in the present application. The rental device of the present application stores the portable power source 200 through the access mechanism 100. However, the rental apparatus of the present application is not limited to the portable power source 200 that can be rented as an electronic device, and the electronic device may include portable electronic terminals that can be rented such as a portable lecturer, a portable navigator, a portable translator, a portable telephone, and the like.

Referring to fig. 1,3 and 5, the access mechanism 100 includes a housing 10, an elastic energy storage portion 20, a deceleration portion 30 and a latch 40. The housing 10 is hollow and includes an inner cavity 11. One side of the housing 10 is provided with an opening 12 communicating with the inner cavity 11. The portable power source 200 is accessible from the opening 12 and is housed in the cavity 11. In the embodiment of fig. 1, the mobile power supply 200 is completely contained in the inner cavity 11, and the protection of the mobile power supply 200 by the housing 10 is more comprehensive. However, in other embodiments, the portable power source 20 may also partially extend out of the cavity 11, so that the portable power source is convenient for the user to take, and on the other hand, the user can be informed intuitively whether the portable power source 200 is stored in the current access mechanism 100. The elastic energy storage part 20 is fixedly connected with the shell 10, the elastic energy storage part 20 is connected with the pushing part 50 in a sliding way, and at least part of the pushing part 50 stretches into the inner cavity 11 to be abutted with the mobile power supply 200. The speed reducing portion 30 is slidably connected between the housing 10 and the pushing portion 50, the lock catch 40 is also fixed on the housing 10, and both the speed reducing portion 30 and the lock catch 40 act on the mobile power supply 200, wherein the speed reducing portion 30 is used for controlling a sliding speed of the mobile power supply 200 relative to the inner cavity 11, and the lock catch 40 is used for locking the mobile power supply 200 after the mobile power supply 200 enters the inner cavity 11.

The direction in which the mobile power source 200 enters the inner cavity 11 is defined as a first direction 001, and the sliding direction of the pushing portion 50 is also parallel to the first direction 001. The access mechanism 100 of the present application requires a user to manually push the mobile power source 200 from the opening 12 into the cavity 11. The mobile power supply 200 abuts against the pushing portion 50 during the process of entering the inner cavity 11, and drives the pushing portion 50 to slide along the first direction 001 in a direction away from the opening 12. The pushing part 50 continuously elastically deforms the elastic energy storage part 20 fixed to the housing 10 in the sliding process, and stores elastic potential energy for the elastic energy storage part 20. When the mobile power supply 200 slides in place, the lock catch 40 is triggered to lock the mobile power supply 200, i.e. the lock catch 40 locks the mobile power supply 200 in the inner cavity 11. When the user needs to take out the portable power source 200, the lock catch 40 is controlled to unlock, the elastic potential energy of the elastic energy storage portion 20 is released, and the elastic energy storage portion 40 drives the pushing portion 50 to slide towards the opening 12. Since the pushing portion 50 is abutted against the mobile power source 200, the pushing portion 50 pushes the mobile power source 200 out of the inner cavity 11 step by means of the elastic force of the elastic energy storage portion 20. Since the speed reducing portion 30 acts on the mobile power supply 200 in the same manner by the sliding connection with the case 10 and the pushing portion 50, the pushing speed of the mobile power supply 200 by the pushing portion 50 is limited by the speed reducing portion 30 and is reduced. The mobile power supply 200 extends out of the opening 12 in the first direction 001 at a slower speed, leaving the user with sufficient time to hold and remove the mobile power supply 200. In one embodiment, the mobile power supply 200 can also exit the inner cavity 11 in a uniform state under the action of the speed reducing portion 30, so that a user can conveniently hold and take out the mobile power supply 200.

According to the mobile power supply access device 100, the elastic energy storage part 20 and the pushing part 50 are matched, so that the mobile power supply 200 stores energy for the elastic energy storage part 20 in the process of entering the inner cavity 11. After the lock catch 40 unlocks the mobile power supply 200, the speed reducing portion 30 can control the ejection speed of the mobile power supply 200, so as to prevent the mobile power supply 200 from falling out of the inner cavity 11 due to the excessive elastic force of the elastic energy storage portion 20. Therefore, by matching the elastic energy storage portion 20 and the deceleration portion 30, the mobile power supply access device 100 of the present application can ensure that a sufficient pushing force is applied to the mobile power supply 200 to push the mobile power supply 200 out of the inner cavity 11, and can also ensure that the moving speed of the mobile power supply 200 is slow enough to give a user enough time to hold and take out the mobile power supply 200. The access mechanism 100 of the present application adopts a mechanical structure to realize the function of semi-automatic access to the mobile power supply 200, and compared with a motor-driven access scheme, the structure of the present application is simpler and the volume is smaller. And the reliability of the mechanical structure is higher, and the manufacturing cost is lower.

In the scheme of the mobile power access device 100 of the present application, the mechanical structure capable of implementing the function of the elastic energy storage portion 20 includes various embodiments such as a coil spring, a torsion spring, a spring, and an elastic multi-link. Referring to fig. 2, the elastic energy storage portion 20 adopts a structure of a coil spring 21 in the embodiment of fig. 2. The coil spring 21 includes a fixing base 211 fixed to the housing 10, and a winding shaft 212 passing through the fixing base 211. The reed 213 of the coil spring 21 is wound on the spool 212, and the free end 2131 of the reed 213 is connected to the pushing portion 50. The sliding direction of the pushing portion 50 is perpendicular to the spool 212. When the pushing portion 50 slides with respect to the housing 10, the degree of curling of the reed 213 with respect to the reel 212 changes accordingly, thereby achieving the action of storing energy and releasing elastic potential energy. The stroke of the reed 213 is long, and thus the embodiment of the coil spring 21 can cope well with the characteristic of the large sliding stroke of the mobile terminal 200.

On the other hand, the action of the speed reducing unit 30 on the portable power source 200 adopts a method in which the speed reducing unit 30 acts on the pushing unit 50 and then indirectly acts on the portable power source 200. Referring to fig. 3, in the embodiment of fig. 3, the speed reducing portion 30 acts on the pushing portion 50, and the speed reducing portion 30 controls the sliding speed of the mobile power source 200 by limiting the sliding speed of the pushing portion 50. Among the existing mechanical structures, the mechanical structures capable of realizing the function of the speed reducing part 30 comprise gear sets, dampers and the like, wherein the dampers also comprise damping gears, damping springs, damping hinges, damping sliding rails, hydraulic dampers, pulse dampers, rotary dampers, pneumatic dampers, viscous dampers and the like. As with the elastic energy storage portion 20, the access mechanism 100 of the present application is not limited to the specific structure and principle of the deceleration portion 30. Referring to the enlarged view of fig. 4, in the example of fig. 4, the reduction portion 30 employs an embodiment of a damper gear 31. Specifically, the damper gear 31 includes a gear shaft 311 fixed to the pushing portion 50, and a gear 312 rotatably mounted on the gear shaft 311. The housing 10 is provided with a rack 15 which meshes with a gear 312, the gear 312 being further connected with a damper 313. When the pushing portion 50 slides relative to the damping gear 31, the rack 15 and the gear 312 are engaged to rotate the gear 312. The gear 312 is limited in rotational speed by the force of the damper 313, and thus the sliding speed of the pushing portion 50 is also limited, thereby achieving the effect of decelerating the pushing portion 50 by the damping gear 31.

The pushing portion 50 may be in the form of a push rod that abuts against the portable power source 200, or may be provided as a slide holder 51 as shown in fig. 5. The sliding support 51 is provided with a storage compartment 511, and the mobile power supply 200 is placed in the storage compartment 511 and extends into or slides out of the inner cavity 11 along with the sliding of the sliding support 51. Specifically, the sliding support 51 is provided with an outlet (not shown) in a second direction 002 perpendicular to the first direction 001, and the portable power source 200 enters and exits the housing compartment 511 from the outlet. The mobile power supply 200 is generally provided with a data line drawn out of the mobile power supply 200 for connection with and charging of the mobile terminal. Because the data line is not fixed relative to the mobile power supply 200, the mobile power supply 200 is usually jammed due to the dislocation of the data line when extending into the inner cavity 11. If the gap between the mobile power supply 200 and the inner cavity 11 is small, the data line is easily damaged, so that the mobile power supply 200 cannot normally charge the mobile terminal. After the mobile power supply 200 is placed in the accommodating bin 511 and accommodated in the inner cavity 11, the data lines are accommodated in the accommodating bin 511 along with the mobile power supply 200, so that the data lines of the mobile power supply 200 can be effectively accommodated, and the clamping stagnation of the data lines caused by dislocation can be avoided.

It will be appreciated that, when the pusher 50 is provided as an embodiment of the sliding support 51, the sliding support 51 is preferably provided with a profile matching the shape of the inner cavity 11. By the support of the sliding support 51 by the inner cavity 11, a stable posture of the sliding support 51 during the reciprocating sliding with respect to the inner cavity 11 is ensured. It can also be described that the inner cavity 11 forms a track matching the profile of the sliding support 51, which track is parallel to the first direction 001, for ensuring a smooth sliding posture of the sliding support 51 in the first direction 001. In this embodiment, the matching between the mobile power supply 200 and the housing compartment 511 does not need to be strictly positioned, i.e. a part of the gap between the housing compartment 511 and the mobile power supply 200 or a housing space for the data line of the mobile power supply 200 may be provided.

With continued reference to fig. 5, one embodiment of the present application includes an inner chamber 11 including a first inner wall 111 opposite the outlet and a second inner wall 112 opposite the first inner wall 111. The elastic energy storage portion 20 is fixedly arranged on one side of the housing 10 close to the first inner wall 111, and the deceleration portion 30 is arranged on one side of the housing 10 close to the second inner wall 112. Namely, the elastic energy storage portion 20 and the deceleration portion 30 are arranged on both sides of the mobile power supply 200 at the position in the inner chamber 11. Because the elastic energy storage portion 20 and the deceleration portion 30 have a certain space size and a certain working space requirement, if the elastic energy storage portion 20 and the deceleration portion 30 are disposed on the same side of the sliding support 51 at the same time, the structure of the first inner wall 111 or the second inner wall 112 may be too complex, and the difficulty of arrangement during design may be increased. The elastic energy storage portion 20 and the deceleration portion 30 are arranged on the inner walls of the inner cavity 11, so that the structure of the access mechanism 100 of the present application can be simplified, and the mutual interference between the elastic energy storage portion 20 and the deceleration portion 30 can be avoided.

As mentioned in the foregoing, the mobile power supply 200 is externally provided with a data line. When the pushing portion 50 is provided in the form of a push rod or the like and the data line cannot be accommodated in the accommodating chamber 511, the embodiment shown in fig. 6 may be adopted in which the groove 13 is provided on one side inner wall of the inner cavity 11. The recess 13 may be used to receive a data line when the mobile power supply 200 enters the cavity 11. The position of the recess 13 may be set according to the specific orientation of the data in the mobile power supply 200, as in the embodiment of fig. 6 the recess 13 is arranged at the second inner wall 112. During the process of entering the inner cavity 11, the data wire automatically slides into the groove 13 because of approaching to the groove 13, and meanwhile, the mobile power source 200 can be smoothly pushed into the inner cavity 11 because of accommodating the data wire. In the embodiment of fig. 5, the groove 13 is also disposed at the first inner wall 111, and the position of the groove 13 corresponds to the position of the groove 13 at the second inner wall 112, so that the groove 13 can effectively accommodate the data line no matter the data line slides into the groove 13 at the side of the first inner wall 111 or the groove 13 at the side of the second inner wall 112. Further, the groove 13 can also accommodate the bulge of the mobile power supply 200 under the condition that the mobile power supply 200 has the bulge after long-term use, so that the accommodating volume of the inner cavity 11 is increased, and the defect that the mobile power supply 200 has the bulge and is interfered with the inner cavity 11 to be blocked, so that the mobile power supply cannot smoothly enter and exit the inner cavity 11 is avoided.

For the locking action of the shackle 40 with the mobile power supply 200, one embodiment, as shown in fig. 7, the shackle 40 may comprise a movable lock cylinder 41. The portable power source 200 or the pushing part 50 is provided with a clamping groove 512 matched with the lock catch 40. Specifically, the card slot 512 mates with the lock cylinder 41 of the lock catch 40. When the mobile power supply 200 is accommodated in the inner cavity 11, the position of the clamping groove 512 just corresponds to the position of the lock cylinder 41, and the lock cylinder 41 stretches into the clamping groove 512 to lock the mobile power supply 200 in the inner cavity 11. It can be understood that the locking action of the lock catch 40 on the mobile power supply 200 is locking along the first direction 001, so as to prevent the mobile power supply 200 from being pushed out of the inner cavity 11 along the first direction 001 by the elastic energy storage portion 20. When the lock cylinder 41 is locked with the mobile power source 200 or the pushing portion 50, the mating surface is preferably perpendicular to the first direction 001. Of course, in other embodiments, the latch may be provided by an electromagnet, etc., so that the latch 40 and the mobile power source 200 or the pushing portion 50 can avoid the mobile power source 200 from being pushed out of the inner cavity 11 by a larger magnetic attraction force. The electromagnet embodiment can eliminate the provision of the clamping groove 512, improve the uniformity of the appearance of the mobile power supply 200, or simplify the structure of the pushing part 50.

It should be noted that the lock catch 40 is preferably disposed in the inner cavity 11 at a position away from the opening 12 along the first direction 001, so as to prevent human factors from contacting the lock catch 40 from the outside as much as possible to take out the mobile power supply 200.

The access mechanism 100 of the rental equipment can be used in the field of public equipment, and can protect and store portable electronic devices such as the mobile power supply 200 and the like better under the use situation of individuals or families because the access mechanism 100 of the application has higher reliability. Further, in some embodiments in which the access mechanism 100 can be used to charge portable electronic devices such as the portable power source 200, the access mechanism 100 of the rental apparatus of the present application can be used in a home or office, and can reliably store and charge the portable electronic devices of the users, so that the access mechanism has a high anti-theft capability, and further expands the application range of the access mechanism 100 of the rental apparatus of the present application.

With continued reference to fig. 7, one embodiment of the access mechanism 100 further includes a circuit board (not shown). At this time, the lock catch 40 needs to adopt an electric control principle, that is, the lock catch 40 can realize the locking and unlocking functions through the control of an electric signal. The circuit board is electrically connected with the lock catch 40, and is used for controlling the unlocking action of the lock catch 40. Specifically, the circuit board receives an external control instruction, and sends an unlocking signal to the lock catch 40 of the electric control principle, and after the lock catch 40 receives the unlocking signal, the lock of the mobile power supply 200 or the pushing part 50 is released by means of power on and power off, so that the elastic energy storage part 20 and the speed reduction part 30 can jointly act to send the mobile power supply 200 out of the inner cavity 11.

As mentioned above, the access mechanism 100 of the present application may also include embodiments for charging the mobile power source 200. Specifically, referring to fig. 7, the mobile power supply 200 includes an opposite extending end 201 and a pushing end 202 in a first direction 001. The insertion end 201 of the mobile power supply 200 is inserted into the cavity 11 before the pushing end 202, and the user pushes the pushing end 202 or the pushing portion 50 to insert the mobile power supply 200 into the cavity 11. The charging port 203 is arranged at the extending end 201, the inner cavity 11 comprises a bottom wall 113 opposite to the opening 12, and the bottom wall 113 is provided with a charging connector 70 matched with the charging port 203 in position. After the mobile power supply 200 stretches into the inner cavity 11 and the lock catch 40 locks the mobile power supply 200 in the inner cavity 11, the charging connector 70 contacts with the charging port 203, the charging connector 70 is connected with an external power supply, and the charging port 203 maintains a contact posture with the charging connector 70 under the locking of the lock catch 40, so that the charging connector 70 can continuously charge the mobile power supply 200. It should be noted that the charging connector 70 may be configured by a spring-coupled probe, a spring, or the like, so as to counteract the system tolerance stack-up of the access mechanism 100 of the present application. Meanwhile, due to the arrangement of the speed reducing portion 30, the speed of the mobile power supply 200 is limited by the speed reducing portion 30 in the process of extending into the inner cavity 11, so that the charging port 203 of the mobile power supply 200 contacts with the charging connector 70 at a slower speed, and the charging port 203 is prevented from being damaged by the charging connector 70 due to the impact of the charging port 203 on the charging connector 70 at a high speed.

In one embodiment, a stop 52 is protruded on a side of the pushing portion 50 away from the mobile power source 200. A stop surface 14 is provided in the housing 10 that mates with the stop 52. Specifically, the stop surface 14 needs to be in communication with the interior cavity 11. The stop surface 14 needs to form a certain angle with the first direction 001, that is, the mating surfaces of the stop surface 14 and the stop portion 52 cannot be arranged in parallel with respect to the first direction 001. During the pushing portion 50 pushes the mobile power supply 200 out of the inner cavity 11, the stop surface 14 is used for abutting against the stop portion 52 to control the pushing stroke of the pushing portion 50. It will be appreciated that if the pushing portion 50 does not control the pushing stroke of the mobile power source 200, the pushing portion 50 may cause the mobile power source 200 to drop out of the access mechanism 100 of the present application after completely pushing the mobile power source 200 out of the cavity 11. It is therefore necessary to control the pushing-out stroke of the pushing portion 50. The stop portion 52 is disposed on a side of the pushing portion 50 away from the mobile power source 200, so that the stop portion 52 does not interfere with the contact between the pushing portion 50 and the mobile power source 200. Particularly, in the embodiment in which the pushing portion 50 is a sliding bracket 51, the stopper portion 52 does not extend into the housing compartment 511 to affect the engagement between the housing compartment 511 and the portable power source 200. The cooperation of the stop portion 52 and the stop surface 14 refers to the dimension design of the mobile power supply 200 along the first direction 001, so as to ensure that the stop portion 52 contacts with the stop surface 14 before the mobile power supply 200 is completely pushed out of the inner cavity 11, and the sliding stroke of the push portion 50 is smaller than the dimension of the mobile power supply 200 along the first direction 001, so as to prevent the mobile power supply 200 from being completely pushed out of the inner cavity 11.

Referring to fig. 1, an openable dust cover 80 is provided at the opening 12. The dust cap 80 completely covers the opening 12 when the dust cap 80 is closed, and the dust cap 80 is used to seal the opening 12. When the access mechanism 100 of the present application is disposed in a public place, the sealing of the dust cover 80 against the opening 12 can prevent external moisture, impurities, etc. from entering the inner cavity 11, regardless of whether the mobile power supply 200 is stored in the inner cavity 11, so that the access mechanism 100 and the mobile power supply 200 of the present application are effectively protected. The dust cap 80 may be provided rotatably attached to the housing 10 to maintain a closed relationship to the opening 12 by means of a spindle and torsion spring.

At least one access mechanism 100 described above is provided on the rental apparatus of the present application. It will be appreciated that when two or more access mechanisms 100 are included in the rental apparatus of the present application, the two or more access mechanisms 100 may be disposed side-by-side in the rental apparatus to save the space of the rental apparatus. The renting equipment can realize semi-automatic access action due to the adoption of the access mechanism 100, has compact structure and higher reliability, can avoid damage to the electronic device in the access process, effectively protects the electronic device and prolongs the service life of the electronic device.

The above-described embodiments do not limit the scope of the present invention. Any modifications, equivalent substitutions and improvements made within the spirit and principles of the above embodiments should be included in the scope of the present invention.

Claims (10)

1. The access mechanism is used for storing at least one electronic device which can be leased, and is characterized by comprising a hollow shell, wherein an opening is formed in one side of the shell, the electronic device enters the shell from the opening and is contained in an inner cavity of the shell, an elastic energy storage part and a lock catch are further fixedly arranged on the shell, the elastic energy storage part is slidably connected with a pushing part, a speed reducing part is slidably connected between the pushing part and the shell, the pushing part at least partially stretches into the inner cavity and is propped against the electronic device under the elastic action of the elastic energy storage part, the sliding direction of the pushing part is parallel to the direction of the electronic device entering the inner cavity, the lock catch is used for locking the electronic device in the inner cavity, when the lock catch unlocks the electronic device, the elastic force of the elastic energy storage part drives the pushing part to push the electronic device out of the opening from the inner cavity, and the speed reducing part comprises a damper or a gear set, and the speed reducing part acts on the electronic device through the damper or the gear set to control the electronic device to move relative to the inner cavity.

2. The rental apparatus of claim 1, wherein the pushing portion is a sliding bracket, a housing compartment is provided in the sliding bracket, an outlet of the housing compartment is perpendicular to a direction in which the electronic device enters the cavity, and the outlet is configured to allow the electronic device to pass therethrough and be placed in the housing compartment.

3. The rental apparatus of claim 2, in which the interior cavity comprises a first interior wall opposite the outlet and a second interior wall opposite the first interior wall, the elastic energy storage portion is fixedly disposed on a side of the housing adjacent the first interior wall, and the deceleration portion is disposed on a side of the housing adjacent the second interior wall.

4. The rental apparatus of claim 1, wherein the electronic device is provided with a data line, and wherein the inner wall of the one side of the interior cavity is provided with a recess for receiving the data line when the electronic device enters the interior cavity.

5. The rental apparatus of any one of claims 1-4, wherein the electronic device or the push portion is provided with a slot that mates with the catch, and when the electronic device is received in the cavity, the catch extends into the slot to lock the electronic device in the cavity.

6. The rental apparatus of claim 5, in which the electronic device access mechanism further comprises a circuit board, the latch is an electrically controlled latch, the circuit board is electrically connected to the latch, and the circuit board is configured to control an unlocking action of the latch.

7. The rental apparatus of claim 5, in which the electronic device includes opposing access and pushing ends along a direction in which the electronic device extends into the interior cavity, the access end extending into the interior cavity prior to the pushing end, the access end having a charging port, the interior cavity including a bottom wall facing the opening, the bottom wall having a charging connector, the charging port being positioned to mate with the charging connector such that the charging connector contacts the charging port and charges the electronic device when the locking device is locked in the interior cavity by the locking device.

8. The rental apparatus of any one of claims 1-4, wherein a stop portion projects from a side of the push portion remote from the electronic device, the housing has a stop surface that mates with the stop portion, and the stop surface is configured to abut against the stop portion to control an ejection stroke of the push portion during the push portion pushes the electronic device out of the cavity.

9. The rental apparatus of any one of claims 1-4, wherein the opening is provided with an openable dust cover for sealing the opening.

10. The rental device of claim 1, in which the rental device is configured to store a rentable mobile power source or a portable electronic terminal.