CN216859788U - Multi-stage telescopic arm and battery replacement station - Google Patents

Abstract

The utility model relates to the field of battery replacement assemblies, and provides a multi-stage telescopic arm and a battery replacement station comprising the same. This multistage telescopic boom includes: a drive mechanism; the driving mechanism is arranged on one mechanical arm and is in driving connection with other mechanical arms; the first transmission mechanism is connected among the mechanical arms and used for driving the mechanical arms to stretch; drive power is provided through a actuating mechanism, through a drive mechanism's transmission, realizes the flexible of a plurality of arms, and then realizes long-range flexible for flexible arm tongs snatchs the scope wider, adopts single actuating mechanism drive, and the structure of having avoided installation motor and speed reducer on each grade arm is complicated, investment cost height and the loaded down with trivial details drawback of control. The multi-stage telescopic boom has the advantages of simple structure, low cost and simple control; and utilize a plurality of arms of mechanical transmission mode drive, have fast and the high advantage of work efficiency of response time.

Description

Multi-stage telescopic arm and battery replacement station

Technical Field

The utility model relates to the technical field of battery replacing assemblies, in particular to a multi-stage telescopic arm and a battery replacing station.

Background

Trade power station and trade tongs of trolley-bus and often use multistage flexible arm to carry out snatching of battery, and the motor of one-level arm drives rack and pinion through the gear reducer and drives the second grade arm, and the motor of second grade arm drives rack and pinion through the gear reducer and drives tertiary arm to realize that the tongs removes the assigned position. Among the prior art, the flexible arm of each grade all need set up motor and speed reducer, causes the flexible arm overall structure of multistage complicacy, still has investment cost height, and response time is long, and work efficiency is low, controls loaded down with trivial details drawback.

SUMMERY OF THE UTILITY MODEL

The utility model provides a multi-stage telescopic arm and a battery replacement station, which are used for solving the defects of complex structure, high cost and complicated control caused by the fact that the multi-stage telescopic arm is driven by a plurality of motors and speed reducers in the prior art, and only one driving mechanism is used for driving a plurality of mechanical arms to do telescopic motion through a first transmission mechanism.

The utility model provides a multi-stage telescopic boom, comprising:

a drive mechanism;

the driving mechanism is arranged on one of the mechanical arms and is in driving connection with the other mechanical arms;

and the first transmission mechanism is connected among the mechanical arms and is used for driving the mechanical arms to stretch.

According to the multi-stage telescopic arm provided by the utility model, the first transmission mechanism comprises a gear set, the gear set comprises a plurality of tooth surfaces, and the plurality of mechanical arms are connected through the tooth surfaces.

According to the multistage telescopic arm provided by the utility model, the mechanical arm comprises a first mechanical arm, a second mechanical arm and a third mechanical arm, and the driving mechanism is arranged on the first mechanical arm.

The multi-stage telescopic arm further comprises a second transmission mechanism, wherein the second transmission mechanism comprises a first gear and a first rack, the first rack is arranged on the second mechanical arm, and the first gear is connected between the driving mechanism and the first rack in a meshed mode;

or the like, or a combination thereof,

still include third drive mechanism, third drive mechanism includes sprocket and chain, the chain is located on the second arm, the sprocket meshing connect in actuating mechanism with between the chain.

According to the multi-stage telescopic arm provided by the utility model, the first mechanical arm is connected with one of the tooth surfaces of the gear set, and the third mechanical arm is connected with one of the tooth surfaces of the gear set.

According to the multi-stage telescopic arm provided by the utility model, the first transmission mechanism further comprises a second rack, the second rack is respectively arranged on the first mechanical arm and the third mechanical arm, the first mechanical arm is meshed with one of the tooth surfaces of the gear set through the second rack on the first mechanical arm, and the third mechanical arm is meshed with one of the tooth surfaces of the gear set through the second rack on the third mechanical arm.

The multistage telescopic arm further comprises a square steel connecting piece, and the third mechanical arm is connected with a second rack on the third mechanical arm through the square steel connecting piece.

According to the multi-stage telescopic arm provided by the utility model, the gear set further comprises a gear column connected between the tooth surfaces, and the second mechanical arm is connected with the gear column through a bearing.

According to the multistage telescopic arm provided by the utility model, the multistage telescopic arm further comprises a sliding part, the mechanical arms form a sliding groove, and the sliding part is arranged on the mechanical arm and is in sliding fit with the sliding groove of the adjacent mechanical arm.

The utility model also provides a power exchanging station, comprising: the multi-stage telescopic arm according to the above embodiment of the present invention.

According to the multi-stage telescopic arm provided by the utility model, the driving force is provided by one driving mechanism, the plurality of mechanical arms are stretched through the transmission of the first transmission mechanism, and further the long-distance stretching is realized, so that the grasping range of the telescopic arm gripper is wider, and the defects of complex structure, high investment cost and complicated control of mounting a motor and a speed reducer on each stage of mechanical arm are overcome by adopting the driving of a single driving mechanism. The multi-stage telescopic boom has the advantages of simple structure, low cost and simple control; and utilize a plurality of arms of mechanical transmission mode drive, have fast and the high advantage of work efficiency of response time.

The multi-stage telescopic arm is driven by only one driving mechanism, and the plurality of mechanical arms are driven to perform telescopic motion through the first transmission mechanism, so that the multi-stage telescopic arm has the advantages of simple structure, low cost, simplicity in control, small occupied space and the like.

Drawings

In order to more clearly illustrate the technical solutions of the present invention or the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

FIG. 1 is a schematic structural view of a multi-stage telescopic boom provided by the present invention;

FIG. 2 is a front view of the multi-stage telescoping arm provided by the present invention;

FIG. 3 is a side view of a multi-stage telescoping arm provided by the present invention;

FIG. 4 is a top view of a multi-stage telescopic boom provided by the present invention;

reference numerals:

100: a drive mechanism; 201: a first robot arm; 202: a second mechanical arm;

203: a third mechanical arm; 300: a gear set; 301: a tooth surface;

302: a gear post; 401: a first gear; 402: a first rack;

500: a second rack; 600: a sliding member; 700: a chute.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, the technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings, and it is obvious that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

A multi-stage telescopic arm of the present invention will be described with reference to fig. 1 to 4. This multistage telescopic boom includes: a drive mechanism 100, a plurality of robotic arms, and a first transmission mechanism. The driving mechanism 100 can provide driving force by using a motor or a hydraulic motor, and the like, and one driving mechanism 100 enables a plurality of mechanical arms to be mechanically linked through a first transmission mechanism, so that the driving mechanism is not required to be respectively installed on each level of mechanical arm.

The driving mechanism 100 is arranged on one of the mechanical arms and is in driving connection with other mechanical arms; the first transmission mechanism is connected among the mechanical arms and used for driving the mechanical arms to stretch.

Specifically, the mechanical arm is divided into multiple stages, the driving mechanism 100 is installed on the first-stage mechanical arm, the second-stage mechanical arm is connected with the first-stage mechanical arm in a sliding mode through the driving mechanism 100, the third-stage mechanical arm and the subsequent multi-stage mechanical arms stretch synchronously through the first transmission mechanism, the second-stage mechanical arm is directly driven to stretch through the driving mechanism 100, and the third-stage mechanical arm and the subsequent mechanical arms achieve multi-stage stretching movement through the first transmission mechanism. The first transmission mechanism can adopt transmission components such as a gear rack or a chain wheel and a chain.

Furthermore, the plurality of mechanical arms can be of a nested structure, the first transmission mechanism is arranged in the mechanical arms, so that the second-stage mechanical arms and the subsequent mechanical arms can be retracted into the first-stage mechanical arms, the structure is compact, the occupied space is small, and the spatial layout of the multi-stage telescopic arms is realized.

According to the multi-stage telescopic arm provided by the utility model, the driving force is provided by one driving mechanism 100, the telescopic arms are stretched through the transmission of the first transmission mechanism, so that the long-distance telescopic is realized, the grabbing range of the telescopic arm gripper is wider, and the defects of complex structure, high investment cost and complicated control of a motor and a speed reducer which are arranged on each stage of mechanical arm are overcome by adopting the driving of the single driving mechanism 100. The multi-stage telescopic boom has the advantages of simple structure, low cost and simple control; and utilize a plurality of arms of mechanical transmission mode drive, have fast and the high advantage of work efficiency of response time.

According to one embodiment of the present invention, the first transmission mechanism comprises a gear set 300, the gear set 300 comprises a plurality of tooth surfaces 301, and the plurality of mechanical arms are connected through the tooth surfaces 301. In the embodiment, the first transmission mechanism is in the form of a gear set 300, and the gear set 300 has a plurality of tooth surfaces 301, and is in transmission connection with the mechanical arm through the tooth surfaces 301, so that the multi-stage telescopic arm is driven to move. It should be understood that tooth surface 301 of gear set 300 matches the number direction of the mechanical arm, the modulus of tooth surface 301 is unchanged, and the diameter of tooth surface 301 is changed, so that mechanical transmission with different rotation speed ratios can be realized, and double-speed transmission of the telescopic arm can be realized.

According to one embodiment of the present invention, the robot arm includes a first robot arm 201, a second robot arm 202, and a third robot arm 203, and the driving mechanism 100 is provided on the first robot arm 201. As shown in fig. 1 to 4, the following embodiments are described by taking a three-stage telescopic arm as an example, in which the first robot arm 201 does not perform telescopic motion and is mainly used for carrying the driving mechanism 100, and the second robot arm 202 and the third robot arm 203 perform telescopic motion. Of course, the number of stages of the telescopic boom can be increased, and different numbers of transmission mechanisms are correspondingly increased according to different numbers of stages, so that the multi-stage telescopic boom is driven by one driving mechanism 100.

According to one embodiment of the present invention, the multi-stage telescopic arm further comprises a second transmission mechanism, the second transmission mechanism comprises a first gear 401 and a first rack 402, the first rack 402 is disposed on the second mechanical arm 202, and the first gear 401 is engaged and connected between the driving mechanism 100 and the first rack 402. In this embodiment, the driving mechanism 100 disposed on the first robot arm 201 is connected to the second robot arm 202 through a rack-and-pinion mechanism, so as to drive the second robot arm 202 to extend and retract. Alternatively, a third transmission mechanism is used to replace the second transmission mechanism, the third transmission mechanism includes a chain wheel and a chain, the chain is disposed on the second mechanical arm 202, the chain wheel is engaged and connected between the driving mechanism 100 and the chain, and the transmission manner of the chain wheel and the chain is used to replace the gear-rack transmission described above, so as to drive the second mechanical arm 202 to extend and retract. It should be understood that other transmission mechanisms may be used instead of the rack and pinion transmission described above, and the present invention is not limited thereto. Of course, the gear and rack modules are kept unchanged, and the diameter of the first gear 401 is changed, so that mechanical transmission with different rotation speed ratios can be realized, and double-speed transmission of the telescopic boom can be realized.

According to one embodiment of the present invention, the first robot arm 201 is connected to one of the flanks 301 of the gear set 300, and the third robot arm 203 is connected to one of the flanks 301 of the gear set 300. Specifically, the first robot arm 201 is connected to the top flank 301 of the gear train 300, the third robot arm 203 is connected to the bottom flank 301 of the gear train 300, and the gear train 300 is disposed inside the first robot arm 201, and a form in which the second robot arm 202 and the third robot arm 203 are embedded inside the first robot arm 201 as shown in fig. 3 may be formed.

According to one embodiment of the present invention, the first transmission mechanism further includes a second rack 500, the second rack 500 is respectively disposed on the first mechanical arm 201 and the third mechanical arm 203, the first mechanical arm 201 is engaged with one of the tooth surfaces 301 of the gear set 300 through the second rack 500 thereon, the third mechanical arm 203 is connected with the second rack 500 thereon through a square steel connecting member, and is engaged with one of the tooth surfaces 301 of the gear set 300 through the second rack 500.

According to one embodiment of the present invention, the gear set 300 further comprises a gear post 302 connected between the tooth surfaces 301, and the second mechanical arm 202 is connected with the gear post 302 through a bearing. In the present embodiment, the gear set 300 transmits rotation to the tooth surface 301 through the gear column 302, and the second mechanical arm 202 is connected to the driving mechanism 100 through the second transmission mechanism or the third transmission mechanism, so the gear column 302 only needs to pass through the second mechanical arm 202 through a bearing, and the second mechanical arm 202 may not transmit the rotation through the gear set 300.

According to one embodiment of the present invention, the multi-stage telescopic arm further includes a sliding member 600, and a plurality of robot arms form the sliding groove 700, and the sliding member 600 is provided to the robot arm and slidably engaged with the sliding groove 700 of the adjacent robot arm. In the present embodiment, the slide member 600 is disposed inside the robot arms, so that adjacent robot arms are slidably engaged with each other. Specifically, the sliding member 600 may be a pulley, a slider, or the like, and accordingly, the sliding groove 700 may be a guide groove or a linear guide rail for guiding the extending and retracting direction of the robot arm. For the N-level telescopic arms, N-1 sliding parts 600 are correspondingly arranged, so that the sliding connection among the N-level telescopic arms is realized.

The utility model further provides a power swapping station. Should trade the power station and include: the multi-stage telescopic arm of the above embodiment.

According to the power station provided by the utility model, the multi-stage telescopic arm is driven by only one driving mechanism 100, and the plurality of mechanical arms are driven to perform telescopic motion through the first transmission mechanism, so that the power station has the advantages of simple structure, low cost, simplicity in control, small occupied space and the like.

Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims (10)

1. A multi-stage telescopic boom, comprising:

a drive mechanism;

the driving mechanism is arranged on one of the mechanical arms and is in driving connection with the other mechanical arms;

and the first transmission mechanism is connected among the mechanical arms and is used for driving the mechanical arms to stretch.

2. The multi-stage telescoping arm of claim 1, wherein the first gear comprises a gear set comprising a plurality of toothed surfaces through which the plurality of robotic arms are connected.

3. The multi-stage telescopic arm according to claim 2, wherein the mechanical arm comprises a first mechanical arm, a second mechanical arm and a third mechanical arm, and the driving mechanism is arranged on the first mechanical arm.

4. The multi-stage telescopic arm according to claim 3,

the second transmission mechanism comprises a first gear and a first rack, the first rack is arranged on the second mechanical arm, and the first gear is connected between the driving mechanism and the first rack in a meshed mode;

or the like, or a combination thereof,

still include third drive mechanism, third drive mechanism includes sprocket and chain, the chain is located on the second arm, the sprocket meshing connect in actuating mechanism with between the chain.

5. The multi-stage telescopic arm according to claim 3, wherein said first mechanical arm is connected to one of said toothed surfaces of said gear set, and said third mechanical arm is connected to one of said toothed surfaces of said gear set.

6. The multi-stage telescopic arm according to claim 5, wherein the first transmission mechanism further comprises a second rack, the second rack being respectively provided on the first mechanical arm and the third mechanical arm, the first mechanical arm being engaged with one of the gear faces of the gear set through the second rack thereon, and the third mechanical arm being engaged with one of the gear faces of the gear set through the second rack thereon.

7. The multi-stage telescopic arm according to claim 6, further comprising a square steel connecting piece, wherein the third mechanical arm is connected with the second rack thereon through the square steel connecting piece.

8. The multi-stage telescoping arm of claim 3, said gear train further comprising a gear post connected between said gear faces, said second mechanical arm connected to said gear post by a bearing.

9. The multi-stage telescopic arm according to any one of claims 1 to 8, further comprising a sliding member, wherein the plurality of robot arms form a sliding slot, and the sliding member is provided to the robot arm and slidably engages with the sliding slot of the adjacent robot arm.

10. A power swapping station, comprising: a multi-stage telescopic arm according to any one of claims 1 to 9.

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