CN215398265U - Transfer device for battery replacement - Google Patents

Abstract

The utility model provides a trade electric transfer device, includes lifting frame, is provided with the elevating platform in the lifting frame, is provided with the bearing part that supplies power battery to place on the elevating platform, is provided with the transmission device who adjusts the power battery position of placing on the bearing part. According to the utility model, the transmission device is arranged on the lifting table, so that the power conversion transfer device can complete the conveying of the battery, the power conversion station does not need to be additionally provided with conveying equipment such as a stacker and the like, the power conversion precision and efficiency of the power conversion transfer device are improved, and the area of the power conversion station is further reduced.

Description

Transfer device for battery replacement

Technical Field

The utility model relates to the field of charging and battery changing, in particular to a battery changing transfer device.

Background

With the popularization of new energy automobiles, how to effectively provide quick and effective energy supply for automobiles with insufficient energy becomes one of the bottlenecks which hinder the development of pure electric automobiles; the traditional mode is that the adoption fills electric pile quick charge, but this mode has a great deal of shortcoming: the efficiency is still far less than that of fast oiling, the service life of the battery is shortened, and the maintenance cost of the battery is high. In order to solve the efficiency problem, the existing solution is to use a battery replacement mode to directly replace the battery on the electric vehicle, replace the fully charged battery from a battery replacement station, and charge the battery in the battery replacement station after replacing the insufficient battery, which improves the endurance efficiency of the electric vehicle, but the most important battery replacement efficiency is the battery replacement mode. The battery replacement scheme is generally completed in a charging and replacing station, the transmission capability of a lifting platform of a power replacing transfer device of the current power replacing station is single, and a driving mechanism and a transmission mechanism (such as a stacker) need to be additionally arranged on a battery frame to realize battery exchange between the lifting platform and the battery frame, so that the whole power replacing station is large in area, the carrying position of the stacker is inaccurate, and the success rate of point changing is low.

Accordingly, there is a need in the art for a new transfer relay device to solve the above-mentioned problems

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the defects of the prior art and provides a power conversion transfer device, wherein a lifting platform is designed to have four-direction transmission capability on a horizontal plane so as to solve the problem that the lifting platform of the conventional power conversion transfer device has single transmission capability.

The utility model aims to provide a power conversion transfer device which comprises a lifting frame, wherein a lifting table is arranged in the lifting frame, a bearing part for placing a power battery is arranged on the lifting table, and a transmission device for adjusting the direction of the placed power battery is arranged on the bearing part.

Further, the bearing part comprises a first bearing part and a second bearing part, and the first bearing part and/or the second bearing part can be lifted relative to the lifting platform.

Further, a first transmission roller group and a second transmission roller group are respectively arranged on the first bearing part and the second bearing part;

the first transmission roller group and the second transmission roller group are respectively used for moving the placed power battery in a first direction and a second direction, and the first direction and the second direction are perpendicular.

Further, the first transmission roller group comprises a plurality of first rollers which are uniformly arranged along a first direction, the top surfaces of the first rollers are positioned on the same plane, and the axes of the first rollers are arranged in parallel;

the second transmission roller group comprises a plurality of second rollers which are uniformly arranged along a second direction, the top surfaces of the second rollers are positioned on the same plane, and the axes of the second rollers are arranged in parallel;

at least one first roller and one second roller are arranged in the first transmission roller group and the second transmission roller group and are connected with a motor to form a driving roller, and the rest first rollers and the rest second rollers are driven rollers.

Further, the setting of elevating platform liftable is in lifting frame, and the elevating platform includes the buffering elevating platform of transfer elevating platform, all is provided with the portion of bearing on the buffering elevating platform of transfer elevating platform.

Further, the transfer lifting platform and the buffer lifting platform are parallel to each other and are arranged at intervals up and down; the height difference between the transfer lifting platform and the buffer lifting platform is at least greater than the height of the power battery; the transfer lifting platform and the buffer lifting platform are mutually fixed through a connecting rod.

Further, at least one side of the lifting frame is provided with a battery rack;

the battery frame is of a multilayer structure, and the distance between every two adjacent layers of the battery frame is at least larger than the height of the power battery.

Further, the distance between two adjacent bearing surfaces of the battery rack is the same as the distance between the bearing surface of the transfer lifting platform and the bearing surface of the buffer lifting platform.

And further, each layer of the battery rack is provided with a third transmission roller group along the battery conveying direction, and the third transmission roller group is used for driving the power battery to move between the battery rack and the lifting platform.

Further, at least one side of the lifting frame is provided with a fire box.

Compared with the prior art, the utility model has the beneficial technical effects that:

according to the utility model, the transmission device is arranged on the bearing surface of the lifting table, so that the transfer device can convey the battery, the transfer station does not need to be additionally provided with conveying equipment such as a stacker and the like, the transfer accuracy and efficiency of the transfer device are improved, and the area of the transfer station is further reduced. Meanwhile, the lifting platform is designed to have transmission capability in 4 directions on the horizontal plane, so that the power battery can be stored and taken by the battery rack and transmitted to the battery replacement platform, and the transmission distance of the battery is saved. In addition, the fire box is additionally arranged to rapidly process the thermal runaway battery, and the thermal runaway power battery is transmitted to the fire box, so that the safety of the power conversion transfer device is improved.

Drawings

The utility model is further illustrated in the following description with reference to the drawings.

FIG. 1 is an overall view of the power conversion transfer apparatus of the present invention;

FIG. 2 is an assembly view of the lift frame and the lift table of the present invention;

FIG. 3 is a schematic diagram of a distribution of a transmission device according to the present invention;

FIG. 4 is a schematic view of the elevating platform of the present invention;

FIG. 5 is a schematic view of a connection structure of the transfer lifting table and the buffer lifting table according to the present invention;

FIG. 6 is a schematic structural diagram of a power conversion transfer device with a battery rack according to the present invention;

FIG. 7 is a schematic structural view of a power conversion transfer device with battery racks mounted on both sides thereof according to the present invention;

FIG. 8 is a schematic diagram of a power-shortage-power battery received by the power conversion transfer device according to the present invention;

FIG. 9 is a schematic diagram of the battery change transfer device of the present invention transmitting full electric power;

description of reference numerals: 101. a lifting frame; 101a, a column; 101b, a cross bar; 102. a lifting platform; 102a, a transfer lifting platform; 102b, a buffer lifting platform; 102c, a connecting rod; 1020. a bearing part; 1021. a first bearing part; 1022. a second bearing part; 1010. a transmission device; 1011. a first set of transfer rollers; 1012. a second transport roller set; 20. a battery holder; 20a, a first battery holder; 20b, a second battery holder; 30. a power battery; 30a, full electric power battery; 30b, a deficient power battery; 40. a battery replacement mechanism; 50. a fire box.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and the following embodiments are used for illustrating the present invention and are not intended to limit the scope of the present invention.

In the description of the present invention, it should be noted that the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance, and therefore should not be construed as limiting the present invention, and those skilled in the art can understand the specific meaning of the above terms in the present invention in a specific case. Furthermore, the terms "upper", "lower", "inner", "outer", and the like, indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience in describing and simplifying the description, but do not indicate or imply that the referred devices or elements must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted" and "connected" are to be interpreted broadly, e.g., as being either fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

The present invention will be described in further detail with reference to examples.

As shown in fig. 1 to 9, an embodiment of the present invention provides a power conversion transfer apparatus, which includes a lifting frame 101 and a lifting table 102 disposed in the lifting frame 101, wherein the lifting table 102 is movable up and down in a vertical direction in an internal space of the lifting frame 101 to transport a power battery 30 in the vertical direction. The lifting platform 102 is provided with a transmission device 1010 capable of transporting the power battery 30 along four directions, namely, front, back, left and right directions, so as to drive the power battery 30 to move on a horizontal plane.

As shown in fig. 1, any side of the lifting frame corresponds to the battery replacing platform, at least one side of the rest side surfaces of the lifting frame 101 is provided with a battery frame 20, and the battery frame 20 is used for storing a low-electric-power battery 30b and a full-electric-power battery 30a and charging the low-electric-power battery 30 b. The storage capacity of the power conversion transfer device is increased by adding the battery rack 20 to the power conversion transfer device. In the embodiment of the utility model, the lifting platform 102 is designed to have transmission capability in 4 directions, so that the battery rack 20 can store and take the power battery 30, the power battery 30 is transmitted to the switching platform, and the thermal runaway power battery 30 is transmitted to the fire box 50, thereby improving the safety of the switching point transfer device, saving the transmission distance of the power battery 30 and improving the switching efficiency of the switching point transfer device.

Preferably, in this embodiment, a third transmission roller set is disposed on each bearing surface of the battery rack 20 along the battery conveying direction, and the third transmission roller set pushes the power battery 30 to move between the battery rack 20 and the lifting platform 102.

The present invention will be described in further detail with reference to examples.

Example one

As shown in fig. 1 to 3, the present embodiment describes an electric power conversion relay apparatus, which includes: the lifting frame 101, the lifting frame 101 is provided with a lifting platform 102.

In this embodiment, the lifting frame 101 is a metal frame and is used for supporting the lifting platform 102, the lifting frame 101 includes four upright posts 101a and a plurality of cross bars 101b, and the upright posts 101a and the cross bars 101b are fixedly connected by bolts. The lifting table 102 is mounted on the lifting frame 101 by means of a drive mechanism and/or a transmission mechanism.

In this embodiment, a motor, an electric cylinder, an air cylinder, etc. may be used as the driving force, and a vertical slide rail, a cam mechanism, a rigid chain, a lead screw, a gear, etc. may be used as the transmission device.

Preferably, in this embodiment, the lifting platform 102 is mounted on the lifting frame 101 through four guide rails, so that the lifting platform 102 can slide up and down.

In this embodiment, the lifting platform 102 is provided with a bearing part 1020 for placing the power battery 30, and the bearing part 1020 is provided with a transmission device 1010 for adjusting the orientation of the placed power battery 30.

In this embodiment, the bearing unit 1020 includes a first bearing unit 1021 and a second bearing unit 1022, a first transmission roller set 1011 and a second transmission roller set 1012 are respectively disposed on the first bearing unit 1021 and the second bearing unit 1022, and the first transmission roller set 1011 and the second transmission roller set 1012 are respectively used for moving the placed power battery in a first direction and a second direction, which are perpendicular to each other.

In this embodiment, the first and second transmission roller sets 1011 and 1012 transmit power between two sets of opposite sides of the lifting frame 101, respectively.

The first transmission roller set 1011 and the second transmission roller set 1012 are arranged on the lifting platform 102, so that the lifting platform 102 has the capability of transporting the power battery 30 in four directions of front, back, left and right on a horizontal plane, the transportation capability of the power conversion transfer device for the power battery 30 is enhanced, and the power conversion efficiency of the power conversion station is improved.

In this embodiment, a motor, an electric cylinder, an air cylinder, etc. may be used as the driving force, and a vertical slide rail, a cam mechanism, a rigid chain, a lead screw, a gear, etc. may be used as the transmission device.

Preferably, in the present embodiment,

the first transmission roller set 1011 includes a plurality of first rollers uniformly arranged along a first direction, the second transmission roller set 1012 includes a plurality of second rollers uniformly arranged along a second direction, the central axis of each roller is fixed in the elevating platform 102, and the top surface of each roller extends out of the upper surface of the elevating platform 102 for supporting the power battery 30. The top surfaces of the first rollers are positioned on the same plane, and the axes of the first rollers are arranged in parallel; the top surfaces of the second rollers are positioned on the same plane, and the axes of the second rollers are arranged in parallel.

Preferably, in this embodiment, at least one of the first roller and the second roller is disposed in each of the first transmission roller set 1011 and the second transmission roller set 1012 and is connected to a motor to form a driving roller, and the remaining first roller and second roller are driven rollers. The roller of the driving roller for providing power is driven by a motor to rotate, and driving forces in the front direction, the rear direction, the left direction and the right direction are provided for the power battery 30. Therefore, the lifting platform 102 has transmission capability in 4 directions, the battery frame 20 can store and take the power battery 30, the power battery 30 is transmitted to the power conversion platform, the transmission distance of the power battery 30 is saved, and the power conversion efficiency of the power conversion transfer device is improved.

Example two

As shown in fig. 1 to 3, the present embodiment describes an electric power conversion relay apparatus, which includes: the lifting frame 101 is provided with a lifting platform 102 inside the lifting frame 101, the lifting platform 102 is provided with a bearing part 1020 for placing the power battery 30, and the bearing part 1020 is provided with a transmission device 1010 for adjusting the direction of the placed power battery 30.

In this embodiment, the lifting platform 102 is mounted on the lifting frame 101 through four guide rails, so that the lifting platform 102 can slide up and down.

In this embodiment, the bearing unit 1020 includes a first bearing unit 1021 and a second bearing unit 1022, a first transmission roller set 1011 and a second transmission roller set 1012 are respectively disposed on the first bearing unit 1021 and the second bearing unit 1022, and the first transmission roller set 1011 and the second transmission roller set 1012 respectively transmit power between two sets of opposite sides of the lifting frame 101.

In this embodiment, the first transmission roller set 1011 and the second transmission roller set 1012 are disposed on the carrying surface of the lifting table 102, so that the lifting table 102 has the capability of transporting the power battery 30 in four directions, i.e., forward, backward, left, and right, on the horizontal plane, the transportation capability of the power conversion transfer device for the power battery 30 is enhanced, and the power conversion efficiency of the power conversion station is improved.

As shown in fig. 3, in the present embodiment, the first supporting portion 1021 includes two portions disposed on the supporting surface of the lifting platform 102 near the edges of the two long sides, a first transmission roller set 1011 is disposed on each of the two portions of the first supporting portion 1021, the first transmission roller set 1011 is parallel to the two long sides of the lifting platform 102 and has the same length, and the transmission direction of the first transmission roller set 1011 is horizontally transmitted along the long sides of the lifting platform 102. The second bearing part 1022 is disposed in the middle of the bearing surface of the lifting platform 102, a second transmission roller set 1012 is disposed on the second bearing part 1022, and the transmission direction of the second transmission roller set 1012 is perpendicular to the transmission direction of the first transmission roller set 1011.

EXAMPLE III

As shown in fig. 1 to 4, the present embodiment describes a power conversion relay apparatus, which includes: the lifting frame 101 is provided with a lifting platform 102 inside the lifting frame 101, the lifting platform 102 is provided with a bearing part 1020 for placing the power battery 30, and the bearing part 1020 is provided with a transmission device 1010 for adjusting the direction of the placed power battery 30. The bearing part 1020 comprises a first bearing part 1021 and a second bearing part 1022, wherein a first transmission roller set 1011 and a second transmission roller set 1012 are respectively arranged on the first bearing part 1021 and the second bearing part 1022, and the first transmission roller set 1011 and the second transmission roller set 1012 respectively transmit power between two sets of opposite side surfaces of the lifting frame 101. The first transmission roller set 1011 and the second transmission roller set 1012 are arranged on the bearing part 1020 of the lifting platform 102, so that the lifting platform 102 has the capability of transporting the power battery 30 in four directions of front, back, left and right on a horizontal plane, the transportation capability of the power conversion transfer device for the power battery 30 is enhanced, and the power conversion efficiency of the power conversion station is improved.

In this embodiment, the lifting frame 101 is a metal frame and is used for supporting the lifting platform 102, the lifting frame 101 includes four upright posts 101a and a plurality of cross bars 101b, and the upright posts 101a and the cross bars 101b are fixedly connected by welding. The lifting table 102 is mounted on the lifting frame 101 by means of a drive mechanism and/or a transmission mechanism. The driving force can be achieved by adopting a motor, an electric cylinder, an air cylinder and the like as driving forces and adopting a vertical sliding rail, a cam mechanism, a rigid chain, a screw rod, a gear and the like as a transmission device.

Preferably, in this embodiment, the lifting platform 102 is mounted on the lifting frame 101 through four guide rails, so that the lifting platform 102 can slide up and down.

In this embodiment, the second carrying portion 1022 can be lifted and lowered relative to the lifting platform 102.

Preferably, in this embodiment, first bearing parts 1021 with a height that is fixed relative to the lifting table 102 are disposed on two sides of the plane on the lifting table 102, a first transmission roller set 1011 is disposed on the first bearing parts 1021, a second bearing part 1022 that can move up and down relative to the lifting table 102 along the vertical direction is disposed in the middle of the lifting table 102, a second transmission roller set 1012 is disposed on the second bearing part 1022, top surfaces of the first rollers in the first transmission roller set 1011 are located on the same plane, and top surfaces of the second rollers in the second transmission roller set 1012 are located on the same plane. The top surface of the second transmission roller set 1012 is a bearing surface of the second bearing part 1022, and the bearing surface of the first transmission roller set 1011 is a bearing surface of the first bearing part 1021. When the second bearing part 1022 rises, the bearing surface of the second bearing part 1022 is slightly higher than the bearing surface of the first bearing part 1021, so that the transmission of the power battery 30 by the second transmission roller set 1012 is not affected by the first transmission roller set 1011. When the second supporting part 1022 descends, the supporting surface of the second transmission roller set 1012 is slightly lower than the supporting surface of the first transmission roller set 1011, so that the transmission of the power battery 30 by the first transmission roller set 1011 is not affected by the second transmission roller set 1012.

In this embodiment, the second transmission roller set 1012 can be lifted and lowered by using a motor, an electric cylinder, an air cylinder, etc. as a driving force and using a vertical slide rail, a cam mechanism, a rigid chain, a screw rod, a gear, etc. as a transmission device.

Example four

As shown in fig. 1 to 5, the present embodiment describes an electric power conversion relay apparatus, which includes: the lifting frame 101 is provided with a lifting platform 102 inside the lifting frame 101, the lifting platform 102 is provided with a bearing part 1020 for placing the power battery 30, and the bearing part 1020 is provided with a transmission device 1010 for adjusting the direction of the placed power battery 30. The bearing part 1020 comprises a first bearing part 1021 and a second bearing part 1022, wherein a first transmission roller set 1011 and a second transmission roller set 1012 are respectively arranged on the first bearing part 1021 and the second bearing part 1022, and the first transmission roller set 1011 and the second transmission roller set 1012 respectively transmit power between two sets of opposite side surfaces of the lifting frame 101. The first transmission roller set 1011 and the second transmission roller set 1012 are arranged on the lifting platform 102, so that the lifting platform 102 has the capability of transporting the power battery 30 in four directions of front, back, left and right on a horizontal plane, the transportation capability of the power conversion transfer device for the power battery 30 is enhanced, and the power conversion efficiency of the power conversion station is improved.

Preferably, in this embodiment, the first carrying part 1021 and/or the second carrying part 1022 can be lifted and lowered relative to the lifting table 102. Therefore, in the process that the lifting platform 102 transmits the power battery 30 in the horizontal direction, the first transmission roller set 1011 and the second transmission roller set 1012 cannot influence each other, and the smoothness of the transmission process is improved.

As shown in fig. 4 and 5, in this embodiment, the lifting platform 102 is disposed in the lifting frame 101 in a liftable manner, the lifting platform 102 includes a transfer lifting platform 102a and a buffering lifting platform 102b, the transfer lifting platform 102a and the buffering lifting platform 102b are parallel to each other and are disposed at intervals up and down, and a height difference between the transfer lifting platform 102a and the buffering lifting platform 102b is at least greater than a height of the power battery 30.

Preferably, in this embodiment, the transfer lifting platform 102a and the buffering lifting platform 102b are fixed to each other through a connecting rod 102 c. The bearing portions 1020 of the relay lifting platform 102a and the buffer lifting platform 102b are respectively provided with a first transmission roller set 1011 and a second transmission roller set 1012.

Preferably, in this embodiment, the transfer lifting platform 102a and the buffering lifting platform 102b are provided with connecting rods 102c at four corners, and the transfer lifting platform 102a and the buffering lifting platform 102b are fixed to each other to form the lifting platform 102.

In this embodiment, by providing the buffer lifting table 102b, the buffer lifting table 102b can bear and transfer the insufficient-power battery 30b while the transfer lifting table 102a bears and transfers the full-power battery 30a, or after the transfer lifting table 102a bears the full-power battery 30a, so that the lifting table 102 can store two batteries at the same time, and the battery replacement time is greatly shortened.

Preferably, in this embodiment, a third transmission roller set is disposed on each layer of bearing surface of the battery rack 20 along the battery conveying direction, the third transmission roller set includes a plurality of third rollers, top surfaces of the third rollers are in the same plane, and axes of the third rollers are disposed in parallel; at least one third roller is arranged in the third transmission roller group and connected with a motor to form a driving roller, and the rest third rollers are driven rollers. The drive rollers push the power battery 30 into contact with the transmission 1010 on the lift table 102.

EXAMPLE five

As shown in fig. 1 to 6, the present embodiment describes a power conversion relay apparatus, which includes: the lifting frame 101 is provided with a lifting platform 102 inside the lifting frame 101, the lifting platform 102 is provided with a bearing part 1020 for placing the power battery 30, and the bearing part 1020 is provided with a transmission device 1010 for adjusting the direction of the placed power battery 30. The transmission means 1010 includes a first transmission roller set 1011 and a second transmission roller set 1012, and the first transmission roller set 1011 and the second transmission roller set 1012 transmit power between two sets of opposite sides of the lifting frame 101, respectively. The first transmission roller set 1011 and the second transmission roller set 1012 are arranged on the bearing surface of the lifting platform 102, so that the lifting platform 102 has the capability of transporting the power battery 30 in four directions, namely, the front direction, the rear direction, the left direction and the right direction, on the horizontal plane, the transportation capability of the power conversion transfer device for the power battery 30 is enhanced, and the power conversion efficiency of the power conversion station is improved.

Preferably, in this embodiment, the first supporting portion 1021 and/or the second supporting portion 1022 can be lifted relative to the supporting surface of the lifting table 102. Therefore, in the process that the lifting platform 102 transmits the power battery 30 in the horizontal direction, the first transmission roller set 1011 and the second transmission roller set 1012 cannot influence each other, and the smoothness of the transmission process is improved.

In this embodiment, the lifting platform 102 is disposed in the lifting frame 101 in a lifting manner, the lifting platform 102 includes a transfer lifting platform 102a and a buffering lifting platform 102b, the transfer lifting platform 102a and the buffering lifting platform 102b are parallel to each other and are disposed at an interval from top to bottom, and a height difference between the transfer lifting platform 102a and the buffering lifting platform 102b is at least greater than a height of the power battery 30.

Preferably, in this embodiment, the transfer lifting platform 102a and the buffering lifting platform 102b are fixed to each other through a connecting rod 102 c.

The transfer lifting platform 102a and the buffering lifting platform 102b are respectively provided with a first bearing part 1021 and a second bearing part 1022, and the first bearing part 1021 and the second bearing part 1022 are respectively provided with a first transmission roller set 1011 and a second transmission roller set 1012.

In this embodiment, by providing the buffer lifting table 102b, the buffer lifting table 102b can bear and transfer the insufficient-power battery 30b while the transfer lifting table 102a bears and transfers the full-power battery 30a, or after the transfer lifting table 102a bears the full-power battery 30a, so that the lifting table 102 can store two batteries at the same time, and the battery replacement time is greatly shortened.

Preferably, in this embodiment, a battery rack 20 is disposed on one side of the lifting frame 101, and the battery rack 20 is detachably mounted on the lifting frame 101 by bolts to store the power battery 30 and charge the power-deficient battery 30 b.

Preferably, in this embodiment, the battery rack 20 has a multi-layer structure, and a distance between two adjacent layers of the battery rack 20 is at least greater than a height of the power battery.

Preferably, in this embodiment, the distance between two adjacent bearing surfaces of the battery rack 20 is the same as the distance between two bearing surfaces of the lifting platform 102.

By setting the distance between two adjacent bearing surfaces of the battery racks 20 and the distance between the bearing surfaces of the relay lifting table 102a and the buffer lifting table 102b to be the same, the buffer lifting table 102b can convey the electric power deficient battery 30b to the battery rack 20 of the corresponding level while the relay lifting table 102a receives the full electric power battery 30a on any layer of the battery racks 20, and the working efficiency of the electric power conversion relay device is improved.

Preferably, in this embodiment, a third transmission roller set is disposed on each layer of bearing surface of the battery rack 20 along the battery conveying direction, the third transmission roller set includes a plurality of third rollers, top surfaces of the third rollers are in the same plane, and axes of the third rollers are disposed in parallel; at least one third roller is arranged in the third transmission roller group and connected with a motor to form a driving roller, and the rest third rollers are driven rollers. The drive rollers push the power battery 30 into contact with the transmission 1010 on the lift table 102.

EXAMPLE six

As shown in fig. 7, in the present embodiment, the battery racks 20, namely, the first battery rack 20a and the second battery rack 20b, are connected to both sides of the lifting frame 101.

Preferably, in this embodiment, the first battery rack 20a and the second battery rack 20b have the same number of layers, and the bearing surfaces of the layers correspond to each other one by one.

Preferably, in the present embodiment, the first battery rack 20a is used for placing the fully-charged electric power battery 30a and transmitting the fully-charged electric power battery 30a to the relay lifting platform 102a, and the second battery rack 20b is used for receiving and carrying the undercharged electric power battery 30b from the buffer lifting platform 102b and has a charging function.

EXAMPLE seven

As shown in fig. 1 to 9, in the present embodiment, one side of the lifting frame 101 faces the power exchanging platform, the fire box 50 is disposed on the corresponding side, and the first battery rack 20a and the second battery rack 20b are disposed on the other two sides of the lifting frame 101.

Preferably, in the present embodiment, the first bearing parts 1021 are arranged on both sides of the lifting platform 102, and the first transmission roller sets 1011 thereon perform transmission of the power battery 30 between the battery rack 20 and the lifting platform 102. The second bearing part 1022 is disposed in the middle of the bearing surface of the lifting platform 102, and is of a liftable structure, and the second transmission roller set 1012 thereon transmits the power battery 30 among the power exchanging platform, the lifting platform 102 and the fire box 50.

In this embodiment, when the second supporting portion 1022 is lifted, the supporting surface of the second transmission roller set 1012 is slightly higher than the supporting surface of the first transmission roller set 1011, so that the transmission of the power battery 30 by the second transmission roller set 1012 is not affected by the first transmission roller set 1011. When the second bearing part 1022 descends, the bearing surface of the second transmission roller set 1012 is slightly lower than that of the first transmission roller set 1011, so that the transmission of the power battery 30 by the first transmission roller set 1011 is not affected by the second transmission roller set 1012, and the smoothness of the transmission process is improved.

In this embodiment, the second supporting portion 1022 can be lifted and lowered by using a motor, an electric cylinder, an air cylinder, etc. as a driving force and using a vertical slide rail, a cam mechanism, a rigid chain, a lead screw, a gear, etc. as a transmission device.

In this embodiment, the lifting platform 102 is disposed in the lifting frame 101 in a lifting manner, the lifting platform 102 includes a transfer lifting platform 102a and a buffering lifting platform 102b, the transfer lifting platform 102a and the buffering lifting platform 102b are parallel to each other and are disposed at an interval from top to bottom, and a height difference between the transfer lifting platform 102a and the buffering lifting platform 102b is at least greater than a height of the power battery 30.

Preferably, in this embodiment, the battery rack 20 has a multi-layer structure, the distance between two adjacent layers of the battery rack 20 is the same and at least greater than the height of the power battery, and the distance between two adjacent layers of the bearing surfaces of the battery rack 20 is the same as the distance between the bearing surfaces of the relay lifting platform 102a and the bearing surfaces of the buffer lifting platform 102 b. By setting the distance between two adjacent bearing surfaces of the battery racks 20 and the distance between the bearing surfaces of the transfer lifting table 102a and the buffer lifting table 102b to be the same, when the transfer lifting table 102a receives a full battery on any layer of the battery racks 20, the buffer lifting table 102b can convey a deficient battery on the transfer lifting table to the battery rack 20 of the corresponding layer, so that the work efficiency of the electricity transfer device is improved.

Preferably, in this embodiment, the first battery rack 20a and the second battery rack 20b have the same number of layers, and the bearing surfaces of the layers correspond to each other one by one. The first battery rack 20a is used for placing the full-electric-power battery 30a and transmitting the full-electric-power battery 30a to the transfer lifting platform 102a, and the second battery rack 20b is used for receiving and bearing the insufficient-electric-power battery 30b from the buffer lifting platform 102b and has a charging function. The working mode of the battery rack 20 is increased, and meanwhile, the capacity of the battery of the power conversion transfer device is expanded.

In this embodiment, through set up fire hose 50 in the side that corresponds of trading electric platform, can trade the thermal runaway power battery 30 of electric in-process and carry out rapid processing, improved the security that trades the electric process.

As shown in fig. 7 to 9, the process of using the present invention is as follows: (1) when the vehicle starts to switch the battery, the lifting platform 102 is lifted to a proper position, the switching station control system sends a command to the proper position, and the transfer lifting platform 102a transmits the full-electric-power battery 30a on the first battery rack 20a to the transfer lifting platform 102a through the first transmission roller set 1011; (2) after the power battery 30 is taken out, the lifting platform 102 descends to a connection position, at this time, the second bearing part 1022 on the buffer lifting platform 102b ascends, and the power battery 30b with insufficient voltage is transmitted to the buffer lifting platform 102b through the battery replacing mechanism 40 and the second transmission roller group 1012; (3) after the electric power-deficient battery 30b is transferred to the position, the lifting platform 102 is lowered to the transfer position again, at this time, the second bearing part 1022 on the transfer lifting platform 102a is lifted, and the full-electric power battery 30a is transferred to the electricity conversion mechanism 40; (4) the elevating platform 102 is raised to align the buffer elevating platform 102b with the empty floor on the second battery rack 20b, the second bearing part 1022 on the buffer elevating platform 102b is lowered, and the first transmission roller set 1011 on the buffer elevating platform 102b transmits the electric power loss battery 30b to the second battery rack 20b for charging.

In this embodiment, if the power battery 30 on the battery rack 20 is out of control due to heat, the lifting platform 102 is lifted to a proper position, the transfer lifting platform 102a transfers the power battery 30 on the battery rack 20 to the transfer lifting platform 102a through the first transfer roller set 1011, and then the second carrying part 1022 on the transfer lifting platform 102a is lifted, and the second transfer roller set 1012 on the second carrying part 1022 transfers the power battery 30 out of control due to heat to the fire box 50.

If the power battery 30 on the transfer electric vehicle finds thermal runaway when the transfer is started, the transfer lifting platform 102a is lifted to a proper position, the power-shortage power battery 30b is transmitted to the transfer lifting platform 102a through the transfer mechanism 40, and then the second transmission roller set 1012 on the transfer lifting platform 102a is lifted to transmit the thermal runaway power battery 30 to the fire box 50.

The above-described embodiments are merely illustrative of the preferred embodiments of the present invention, and do not limit the scope of the present invention, and various modifications and improvements of the technical solutions of the present invention can be made by those skilled in the art without departing from the spirit of the present invention, and the technical solutions of the present invention are within the scope of the present invention defined by the claims.

Claims (10)

1. The utility model provides a trade electric transfer device, includes lifting frame, its characterized in that is provided with the elevating platform in the lifting frame, is provided with the bearing part that supplies power battery to place on the elevating platform, is provided with the transmission device who adjusts the power battery position of placing on the bearing part.

2. The transfer unit according to claim 1, wherein the carrying portion comprises a first carrying portion and a second carrying portion, and the first carrying portion and/or the second carrying portion is/are capable of being lifted relative to the lifting platform.

3. The transfer unit according to claim 2, wherein the first carrying portion and the second carrying portion are respectively provided with a first transmission roller set and a second transmission roller set;

the first transmission roller group and the second transmission roller group are respectively used for moving the placed power battery in a first direction and a second direction, and the first direction and the second direction are perpendicular.

4. The transfer station apparatus according to claim 3, wherein the first transport roller set comprises a plurality of first rollers uniformly arranged along a first direction, top surfaces of the first rollers are in the same plane, and axes of the first rollers are arranged in parallel;

the second transmission roller group comprises a plurality of second rollers which are uniformly arranged along a second direction, the top surfaces of the second rollers are positioned on the same plane, and the axes of the second rollers are arranged in parallel;

at least one first roller and one second roller are arranged in the first transmission roller group and the second transmission roller group and are connected with a motor to form a driving roller, and the rest first rollers and the rest second rollers are driven rollers.

5. The power conversion transfer device according to any one of claims 1 to 4, wherein the lifting platform is arranged in the lifting frame in a lifting manner, the lifting platform comprises a transfer lifting platform and a buffer lifting platform, and the transfer lifting platform and the buffer lifting platform are both provided with bearing parts.

6. The transfer power transfer device according to claim 5, wherein the transfer lifting platform and the buffer lifting platform are parallel to each other and are arranged at an interval from top to bottom; the height difference between the transfer lifting platform and the buffer lifting platform is at least greater than the height of the power battery; the transfer lifting platform and the buffer lifting platform are mutually fixed through a connecting rod.

7. The transfer station according to claim 6, wherein a battery rack is provided on at least one side of the lifting frame;

the battery frame is of a multilayer structure, and the distance between every two adjacent layers of the battery frame is at least larger than the height of the power battery.

8. The transfer electric transfer device of claim 7, wherein a distance between two adjacent bearing surfaces of the battery rack is the same as a distance between the bearing surface of the transfer lifting platform and the bearing surface of the buffer lifting platform.

9. The transfer station according to claim 8, wherein each layer of the battery rack is provided with a third transmission roller set along the battery conveying direction for driving the power battery to move between the battery rack and the lifting platform.

10. The switching power transfer apparatus according to any one of claims 1 to 4 and 6 to 9, wherein at least one side of the lifting frame is provided with a fire box.

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