Patent Application
20170306641
The present disclosure generally relates to a field of garage and, particularly, relates to three-dimensional circulating garage.
In the related art, since the current vertical three-dimensional circulating garage includes a lower guiding wheel of the tray and a guiding wheel rail, a vehicle stored in the vertical three-dimensional circulating garage cannot run straight. That is, the vehicle should be driven in forward and then be driven out backward, or the vehicle should be driven in backward and then be driven out forward. Therefore, the vertical three-dimensional circulating garage provides a poor user experience. In addition, when a first vehicle needs to be stored in the garage when a second vehicle is being driven out, an enough space should be reserved to make sure that the second vehicle can be driven out normally, and thus the vertical three-dimensional circulating garage occupies more area of land and has a single form.
Embodiments of the present disclosure seek to solve at least one of the problems existing in the related art to at least some extent.
According to embodiments of the present disclosure, a three-dimensional circulating garage is provided. The three-dimensional circulating garage includes: a fixing frame including a first fixing support and a second fixing support spaced apart from and opposing to each other; a transmission system including a transmission device disposed on the fixing frame, and a tray track disposed on at least one of the first fixing support and the second fixing support; a plurality of tray units, and a driving device connected with the transmission device to drive the transmission device so as to drive the tray unit to move up and down reciprocally in a cyclical manner along the tray track. Each tray unit includes: a tray frame connected with the transmission device and having two rollers disposed on a top thereof, at least one roller of the tray frame being adapted to move in the tray track, a vehicle carrying plate connected to a lower end of the tray frame and configured to park a vehicle, and a tray stabilizing beam disposed on top of the tray frame. When two adjacent tray units move in a vertical direction, a lower surface of the vehicle carrying plate of an upper tray unit of the two adjacent tray units is supported on the tray stabilizing beam of a lower tray unit of the two adjacent tray units.
With the three-dimensional circulating garage according to embodiments of the present disclosure, by disposing two rollers on the top of the tray frame, when the tray unit moves, at least one roller fits with the tray track. Compared with a traditional three-dimensional circulating garage, a guiding wheel disposed at a lower end of the tray frame and a corresponding guiding wheel rail are cancelled. When the tray unit arrives at a lowermost position, the roller of the tray unit fits with a lowermost part of the tray track. Since no tray track is provided around the vehicle carrying plate, the vehicle can be driven into and out of the vehicle carrying plate straightly without being reversed, and thus a user experience is improved and it is convenient for a user to store or get the vehicle out, in addition, with the tray stabilizing beam, two adjacent tray units are supported by each other via the vehicle carrying plate and the tray stabilizing beam when moving in a vertical direction, and thus a stability of the tray unit can be improved when the tray unit moves in the vertical direction.
Additional aspects and advantages of embodiments of present disclosure will be given in part in the following descriptions, become apparent in part from the following descriptions, or be learned from the practice of the embodiments of the present disclosure.
The disclosure is illustrated in the accompanying drawings, in which:
Reference will be made in detail to embodiments of the present disclosure. The same or similar elements and the elements having same or similar functions are denoted by like reference numerals throughout the descriptions. The embodiments described herein with reference to drawings are explanatory, illustrative, and used to generally understand the present disclosure. The embodiments shall not be construed to limit the present disclosure.
In the specification, unless specified or limited otherwise, relative terms such as “center”, “longitudinal”, “lateral”, “width”, “thickness” “front”, “rear”, “right”, “left”, “lower”, “upper”, “vertical”, “above”, “below”, “up”, “top”, “bottom”, “clockwise”, “anticlockwise”, “axial direction”, “radial direction”, “circumferential direction”, as well as derivative thereof (e.g., “downwardly”, “upwardly”, etc.) should be construed to refer to the orientation as then described or as shown in the drawings under discussion. These relative terms are for convenience of description and do not require that the present disclosure be constructed or operated in a particular orientation.
In addition, terms such as “first” and “second” are used herein for purposes of description and are not intended to indicate or imply relative importance or significance. Thus, features limited by “first” and “second” are intended to indicate or imply including one or more than one these features. In the description of the present disclosure, “a plurality of” relates to two or more than two.
In the description of the present disclosure, unless specified or limited otherwise, it should be noted that, terms “mounted,” “connected” “coupled” and “fastened” may be understood broadly, such, as permanent connection or detachable connection, electronic connection or mechanical connection, direct connection or indirect connection via intermediary, inner communication or interaction between two elements. Those having ordinary skills in the art should understand the specific meanings in the present disclosure according to specific situations.
As shown in
As shown in
The transmission system 2 includes a transmission device and a tray track 26. The tray track 26 is disposed on at least one of the first fixing support 10 or the second fixing support 11, and the transmission device is disposed on the fixing frame 1. It should be noted that when the tray track 26 is disposed on the first fixing support 10, the tray tack 26 should be disposed on a side wall of the first fixing support 10 facing the second fixing support 11; when the tray track 26 is disposed on the second fixing support 11, the tray tack 26 should be disposed on a side wall of the second fixing support 11 facing the first fixing support 10.
The tray unit 3 includes a tray frame 34 and a vehicle carrying plate 30 configured to park vehicles. The vehicle carrying plate 30 is connected to a lower end of the tray frame 34. The tray frame 34 has two rollers 31 disposed on a top thereof and at least one of the two rollers 31 of the tray frame 34 is configured to move in the tray track 26. The tray frame 34 of the tray unit 3 is connected with the transmission device. A tray stabilizing beam 33 is disposed on a top of the tray frame 34 of the tray unit 3.
Specifically, the tray track 26 includes two sub-tracks 260 and each sub-track 250 includes a vertical segment 261 and two bending segments 262. The vertical segment 261 extends in a vertical direction, and two bending segments 262 of one sub-track 260 are bent and extended from as upper end and a lower end of the vertical segment 261 of the one sub-track 260 to the other sub-track 260 respectively, The bending segment 262 is configured as an arc segment. When the tray unit 3 slides on the vertical segment 261, one roller 31 of the tray unit 3 rolls on the vertical segment 261. When the tray unit 3 moves to an uppermost position or a lowermost position of the tray track 26, the two rollers 31 of the tray unit 3 are located on the two sub-tracks 260 respectively, such that the tray unit 3 can move from one sub-track 260 to the other sub-track 260, and thus the tray unit 3 can move up and down reciprocally in a cyclical manner along the tray track 26.
The driving device 4 is connected with the transmission device to drive the transmission device so as to drive the tray unit 3 to move up and down reciprocally in the cyclical manner along the tray track 26. When two adjacent tray units 3 move in a vertical direction, a lower surface of the vehicle carrying plate 30 of an upper tray unit 3 of the two adjacent tray units 3 is supported on the tray stabilizing beam 33 of a lower tray unit 3 of the two adjacent tray units 3. That is, when two tray units 3 move on the vertical segment 261, the tray stabilizing beam 33 of the lower tray unit 3 supports the lower surface of the vehicle carrying plate 30 of the upper tray unit 3 so as to support the upper tray unit 3.
It should be noted that the tray unit 3 moves up and down reciprocally in the cyclical manner along the tray track 26, which means a motion path of the tray unit 3 has an annular shape, and the tray unit 3 moves reciprocally along the motion path. It should be pointed out that the fit between the tray unit 3 and the transmission device should make sure that the vehicle carrying plate 30 is stable during a moving process of the tray unit 3. That is, a gravity center of the vehicle should always be kept downward in order to guarantee a safety of the vehicle placed on the vehicle carrying plate 30.
It should be noted that the transmission device may be configured as any common structure, as long as the transmission device can drive the tray unit 3 to move reciprocally up and down in the cyclical manner. Also, the driving device 4 may be configured as any common structure, as long as the driving device 4 can drive the transmission device to drive the tray unit 3 to move reciprocally up and down in the cyclical manner.
According to an embodiment of the present disclosure, the three-dimensional circulating garage 100 further includes a control device (not shown), and the control device is connected with the driving device 4 so as to control the driving device 4 to run or stop. In some embodiments, the control device includes a manual operation interface, and thus a user can control the driving device 4 via the manual operation interface (for example through swiping a card or pressing a button) to love the tray unit 3 to the lowermost position so as to take out the vehicle. Also the user can control the driving device 4 to run or stop via the manual operation interface.
With the three-dimensional circulating garage 100 according to the present disclosure, by disposing two rollers 31 on the top of the tray frame 34, when the ray unit 3 moves, at least one roller 31 fits with the tray track 26. Compared with a traditional three-dimensional circulating garage, a lower guiding wheel of the tray disposed one lower end of the tray frame and a corresponding guiding wheel rail are cancelled. When the tray unit 3 arrives at the lowermost position, the roller 31 of the tray unit 3 is fitted with the lowermost part of the tray track 26. Since no tray track 26 is provided around the vehicle carrying plate 30, the vehicle can be driven into or out of the vehicle carrying plate 30 straightly without being reversed, and thus a user experience is improved and it is convenient for a user to store or get the vehicle out. In addition, with the tray stabilizing beam 33, two adjacent tray units 3 may be supported by each other via the vehicle carrying plate 30 and the tray, stabilizing beam 33 when the two adjacent tray units 3 moves in the vertical direction, and thus stability of the tray unit 3 can be improved when the tray unit 3 moves in the vertical direction.
According, to some embodiments of the present disclosure, the three-dimensional circulating garage 100 further includes a tray positioning device 9 disposed on an upholder. In some embodiments, the upholder may be the ground, In another embodiment, the fixing frame further includes a base 14 configured to support the first fixing support 10 and the second fixing support 11, and the upholder includes the base 14.
The tray positioning device 9 includes a positioning arm 90 rotatable between a horizontal position and a vertical position. When the positioning arm 90 rotates to the vertical position, the positioning arm 90 contacts a lower surface of the vehicle carrying plate 30 of a lowermost tray unit 3 so as to play a role of positioning. That is, when the vehicle is needed to be placed on the vehicle carrying plate 30 or taken out from the vehicle carrying plate 30, first an empty tray unit 3 or a tray unit 3 with a vehicle is driven to the lowermost position of the tray track 26, and then the positioning arm 90 of the tray positioning device 9 rotates to the vertical position to contact the lower surface of the vehicle carrying plate 30 so as to position the tray unit 3, and therefore, the tray unit 3 is prevented from shaking due to a gravity center displacement generated by the vehicle running into or out of the tray unit 3.
When the tray unit 3 moves upward from the lowermost position of the tray track 26, the positioning arm 90 rotates to the horizontal position make sure that the tray unit 3 can pass normally. Therefore, with the tray positioning device 9, the security and stability can be ensured when the vehicle moves into or out of the garage. It should be noted that, when the positioning arm 90 rotates to the vertical position, the positioning arm 90 should be strong enough to bear relatively large impact force so as to ensure that the positioning arm 90 can position the vehicle carrying plate 30 in the vertical position.
According to some embodiments of the present disclosure, the tray positioning device 9 further includes a positioning bracket, two rotation shafts 92 and a driving assembly. The rotation shaft 92 is disposed on and penetrated through the positioning bracket, and the positioning arm 90 is disposed on each end of the rotation shaft 90 extended out the positioning bracket. The driving assembly is connected with the two rotation shafts 92 to drive the two rotation shafts 92 to rotate so as to rotate the positioning arm 90.
That is, the tray positioning device 9 includes four positioning arms 90. The four positioning arms 90 are divided into two groups, and each group of positioning arms 90 includes two positioning arms 90 which are driven to rotate by one rotation shaft 92. When the tray unit 3 is needed to be positioned and supported, the driving assembly drives the two rotation shafts 92 to rotate so as to rotate the four positioning arms 90 to the vertical position; and when it is needed to keep clear of the tray unit 3, the driving assembly drives the two rotation shafts 92 to rotate so as to rotate the four positioning arms 90 to the horizontal position. With the four positioning arms 90 and the two rotation shafts 92, the positioning stability of the tray positioning device 9 is improved, and a structure of the tray positioning device 9 is simple.
It should be noted that, the driving assembly may be configured as any commonly known structure, as long as the driving assembly can drive the rotation shaft 92 to rotate so as to drive the positioning arms 90 to rotate between the vertical position and the horizontal position.
In some embodiments of the present disclosure, as shown in
In some embodiments of the present disclosure, as shown in
It should be noted that a work principle of the linear actuator is common known by those skilled in the related art, and thus detailed description is omitted herein. It should be noted that the first driver 930 may be configured as any other structure, as long as the first driver 930 can drive the first rotation shaft 935 to move horizontally. For example, in one embodiment, the first driver 930 includes an air cylinder.
In one embodiment, the gear and rack assembly includes a gear (not shown) and a rack 932 engaged with the gear. The gear is fitted over the rotation shaft 92, and the rack 932 is horizontally movably disposed on the positioning bracket. A first end of the first connecting rod 933 is rotatably disposed on a first end of the second connecting rod 934 via the first rotation shaft 935, and a second end of the first, connecting rod 933 and a second end of the second connecting rod 934 are rotatably disposed on two racks 932 respectively. The first driver 930 is connected to the first rotation shaft 935 so as to drive the first rotation shaft 935 to move between a first position and a second position. When the first rotation shaft 935 moves to the first position, the positioning arm 90 rotates to tie vertical position, and when the first rotation shaft 935 moves to the second position, the positioning arm 90 rotates to the horizontal position.
That is, the rotation shaft 92 has a gear disposed thereon, and the gear is engaged with one rack 932. When the first driver 930 drives the first rotation shaft 935 to move horizontally, an included angle between the first connection rod 933 and the second connecting rod 934 varies, and at the same time, the first connecting, rod 933 and the second connecting rod 934 drive the rack 932 to move horizontally. Then, as the rack 932 is engaged with the gear, the rack 932 drives the gear to rotate, and also, as the gear is disposed on the rotation shaft 92, the gear drives the rotation shaft 92 to rotate. Thus, the positioning arm 90 is driven to rotate between the horizontal position and the vertical position. As a result, the driving assembly according to embodiments of the present disclosure has a simple and reliable structure.
In some embodiments of the present disclosure, as shown in
In some embodiments, the first sensor 97 and the second sensor 98 may include a proximity sensor respectively. The first sensor 97 is disposed close to the first position, and the second sensor 98 is disposed close to the second position. It should be noted that a work principle of the proximity sensor is well known by those skilled in the related art, and therefore detailed descriptions thereof are omitted herein.
The tray positioning device 9 according embodiments of the present disclosure will be described hereafter by referring to
As shown in
The two connecting rods 912 are spaced apart from each other, two ends of each connecting rod 912 are connected with the first bracket 910 and the second bracket 911 respectively, two ends of each rotation shaft 92 are extended out from the first bracket 910 and the second bracket 911, and the driving assembly is disposed between the first bracket 910 and the second bracket 911. Thus, the positioning bracket has a simple structure. In addition, as the tray positioning device 9 has a relative small volume, an occupied space of the tray positioning device 9 can be reduced.
In some embodiments, the first bracket 910 includes a bracket body 913 and two protection boxes 914. The bracket body 913 is parallel to the second bracket 911, the two protection boxes 914 are disposed on a side wall of the bracket body 913 facing the second bracket 911, and the two protection boxes 914 are spaced apart from each other and disposed on outsides of the two connecting rods 912 respectively. Furthermore, each protection box 914 is connected with one corresponding connecting rod 912.
A first end of the rotation shaft 92 passes through the protection box 914 and the bracket body 913 respectively, and a second end of the rotation shaft. 92 passes through the second bracket 911. A sliding groove 915 communicated with an interior of the protection box 914 is formed in an upper surface of the protection box 914.
In some embodiments, the driving assembly includes a linear actuator 930, two gear and rack assemblies, a first connecting rod 933 and, a second connecting rod 934. Each gear and rack assembly includes a gear and a rack 932. The gear is disposed in the protection box 914 and fitted over the rotation shaft 92. The rack 932 is movably disposed in the sliding groove 915 of the protection box 914. The rack 932 is engaged with a corresponding gear, and thus damage to people from the gear and rack assembly during an operation thereof can be avoided.
As shown in
In some embodiments, a first end of the first connecting rod 933 is connected with a first end of the second connecting rod 934 via the first rotation shaft 935, and a second end of the first connecting rod 933 and a second end of the second connecting rod 934 are rotatably disposed on two racks 932 respectively via the second rotation shaft 936. In some embodiments, the linear actuator 930 includes a push rod connected with the first rotation shaft 935 so as to drive the first rotation shaft 935 to move horizontally.
In some embodiments, the tray positioning device 9 further includes a push plate assembly 99, the push plate assembly 99 includes a fixing base 991 and a push plate 990 horizontally movably disposed on an upper surface of the fixing base 991 and connected with the push rod, and the first rotation shaft 935 is connected with the push plate 990. With the push plate component 99, it is convenient to install the first rotation shaft 935. The first sensor 97 is disposed on the fixing base 991 and the second sensor 98 is disposed on a surface of the bracket body 913 facing the second bracket 911. In some embodiments, the first sensor 97 and the second sensor 98 include a proximity sensor respectively.
When it is needed to move the positioning arm 90 to the vertical position, first the linear actuator 930 is activated to drive the push plate 990 to move toward the first position, and then the first rotation shaft 935 is driven by the push plate 990 to move horizontally toward the first position. At the same time, the second end of the first connecting rod 933 and the second end of the second connecting rod 934 move far away from each other, so that two racks 932 are driven to move far away from each other. Movements of the two racks 932 drive two gears to rotate, so as to drive the rotation shafts 92 to rotate, and thus four positioning arms 90 rotate toward the vertical position. When the first rotation shaft 935 moves to the first position, the first sensor 97 detects that the first rotation shaft 935 is located in the first position, the first sensor 97 then sends a detected signal to the linear actuator 930. Then the linear actuator 930 stops running, the push plate 990 stops moving, and the four positioning arms 90 are positioned in the vertical position. As shown in
When it is needed to move the positioning arm 90 to the horizontal position, first the linear actuator 930 is activated to drive the push plate 990 to move toward the second position, and then the first rotation shaft 935 is driven by the push plate 990 to move horizontally toward the second position. At the same time, the second end of the first connecting rod 933 and the second end of the second connecting rod 934 move toward each other, and thus two racks 932 are driven to move toward each other. Movements of the two racks 932 drive two gears to rotate, so as to drive the two rotation shafts 92 to rotate, and thus the four positioning arms 90 rotate toward the horizontal position. When the first rotation shaft 935 moves to the second position, the second sensor 98 detects that the first rotation shaft 935 is located in the second position, and the second sensor 98 then sends, a detected signal to the linear actuator 930. Then the linear actuator 930 stops running, the push plate 990 stops moving, and the four positioning arms 90 are positioned in the horizontal position. As shown in
As shown in
Specifically, as shown in
As shown in
As shown in
The transmission system 2 includes a driving shaft 20, two support wheels 23 and two first chains 24 having a ring shape. Two second chain wheels 21 are disposed on two ends of the driving shaft 20 respectively, and a third chain wheel 22 configured to be engaged with the first chain wheel 41 is disposed on one end of the driving shaft 20. The two ends of the driving shaft 20 with the third chain wheel 22 and two second chain wheel 21 are installed on the first fixing support 10 and the second fixing support 11 via a standard bearing seat 17. It should be noted that the term “standard” used herein refers drat the bearing seat 17 is a standard element. It should be noted that the third chain wheel 22 and the first chain wheel 41 may be fitted with each other by any common means, as long as the first chain wheel 41 can drive the third chain wheel 22 to rotate so as to rotate the driving shaft 20.
The two support wheels 23 are disposed on two side walls of the first fixing support and the second fixing support 11 facing each other respectively, and each support wheel 23 is configured as a chain wheel structure. The two first chains 24 are disposed on the first fixing support 10 and the second fixing support 11 respectively. Two sliding grooves (not shown) are formed in the two side walls of the first fixing support 10 and the second fixing support 11 facing each other respectively, and each first chain 24 is adapted to slide in a corresponding sliding groove. Each first chain 24 is fitted on the support wheel 23 and the second chain wheel 21 respectively, and thus the support wheel 23 plays a role of supporting the first chain 24, and the second chain wheel 21 plays, a role of driving the first chain 24 to rotate, and the support wheel 23 and the second chain wheel 21 are fitted with the corresponding first chain 24 via wheel-chain transmission. A plurality of tray supporting plates 25 are evenly disposed on each first chain 24, two ends of the tray frame 34 of each tray unit 3 are connected with corresponding tray supporting plates 25 disposed on the two first chains 24 respectively. In some embodiments, each tray frame 34 includes a tray shaft 32, and the tray shaft 32 of each tray unit 3 is rotatably connected with the corresponding tray supporting plates 25 of the two first chains 24.
Specifically, the second driver 40 operates to drive the first chain wheel 41 to rotate, then the first chain wheel 41 drives the third chain wheel 22 to rotate as the first chain wheel 41 is fitted with the third chain wheel, and the third chain wheel 22 drives the driving shaft 20 to rotate so as to drive the two second chain wheel 21 to rotate. As the two second chain wheel 21 are fitted with the two first chains 24 respectively, each first chain 24 are driven by the second chain wheel 21 to slide in the corresponding sliding groove, and thus the plurality of tray supporting plates 25 are driven to rotate, so as to move each tray unit 3 up and down reciprocally in a cyclical manner along the tray track. Thus, in embodiments of the present disclosure, the driving device 4 and the transmission system 3 have a simple structure. In some embodiments, as shown in
It should be noted that the first chain 24 may be lengthened due to deformation during a use process thereof, and thus the two support wheels 23 should be moveably disposed on the first fixing support 10 and the second fixing support 11 respectively. When the first chain 24 is lengthened, a location of the support wheel 23 can be adjusted so as to ensure that the first chain 24 is supported on the support wheel 23 all the time.
In some embodiments of the present disclosure, as shown in
As shown in
In some embodiments, the three-dimensional circulating garage 100 further includes a power supply device 5. The power supply device 5 is connected with each tray unit 3 so as to charge a vehicle placed on the vehicle carrying plate 30. That is, the vehicle placed on the vehicle carrying plate 30 can be charged by the power supply device 5. It should be noted that not only the power supply device 5 can charge the vehicle placed on the vehicle carrying plate 30, but also the power supply device 5 should guarantee electrical safety to avoid personal injury, such as electric shock, to a user when the vehicle placed on the vehicle carrying plate 30 is cut off from the power supply device 5. It should be noted that the power supply device may be configured as any common structure, as long as it can charge the vehicle placed on the vehicle carrying plate 30.
Also, it should be understand that the power supply device should include a charging gun (not shown), and the vehicle includes a charging port matched with the charging gun. Each tray unit 3 should include one charging gun thereon, and the charging gun is adapted to be inserted into the charging port, such that the power supply device can charge the vehicle.
When it is needed to park a vehicle into the three-dimensional circulating garage, firstly, the vehicle runs onto the lowermost vehicle carrying plate 30 of the plurality of vehicle carrying plates 30, in which when the vehicle is an electric vehicle and needs to be charged, the user can connect the electric vehicle with the power supply device. Then the tray unit 3 with the vehicle in a charging state moves upward, and also, an empty vehicle carrying plate 30 moves to the lowermost position so as to prepare for a subsequent vehicle.
When it is needed to take the well, charged vehicle out of the three-dimensional circulating garage, by controlling the driving device 4 to operate, the vehicle carrying plate 30 on which the vehicle is placed is driven to move to the lowermost position, and then the user cuts off the vehicle front the power supply device and drives, the vehicle out of the three-dimensional circulating garage from the vehicle carrying plate 30.
In some embodiments, as shown in
In some embodiments, the sliding wire guide rail 51 is disposed a side wall of the first fixing support 10 facing the second fixing support 11 and configured to connect with an external power supply. In some embodiments, the sliding wire guide rail 51 has an obround shape. The plurality of current collectors 52 are electrically connected with the sliding wire guide rail 51 and moveable on the sliding wire guide rail 51, and each current collector 52 is electrically connected with one charger 50 so as to transport electricity collected from the sliding wire guide rail 51 to the charger 50. It should be noted that the current collector 52 may be disposed on the transmission device or on the tray unit 3 such that the collector 52 can move in the sliding wire guide rail 51 along with the tray unit 3. In some embodiments, the current collector 52 is disposed on the tray supporting plate 25 so as to move along with the tray supporting plate 25.
Specifically, each of the sliding wire guide rail 51 and the current collector 52 is configured as a sliding wire. A plurality of copper wires (not shown) are disposed within the sliding wire guide rail 51, an electricity extracting head 520 of each current collector 52 has an electric point (not shown) in correspondence with each of the plurality of the copper wires. That is, each current collector 52 has one electric point for each copper wire, and each current collector 52 can slide on or in the sliding wire guide rail 51 and extract electricity from the copper wires in the sliding wire guide rail 51 by contacting the copper wires. It should be noted that a shape of the sliding wire guide rail 51 is consistent with a motion path of each tray unit 3 to assure that the tray unit 3 can move up and down reciprocally in a cyclical manner and the vehicle placed on each vehicle carrying, plate 30 can be charged. Thus, the power supply device 5 has a simple structure.
In some embodiments, as shown in
In some embodiments, as shown in
In some embodiments, the stator 530 is sleeved on the tray shaft 32 and connected to the tray supporting plate 25, and the stator 530 is still relative to the tray supporting plate 25. The rotor 531 is sleeved on the tray shaft 32 and still relative to the tray shaft 32. Specifically, the rotor 531 may be fixed on the tray shaft 32 via a jackscrew 536, and thus the rotor 531 is still relative to the tray shaft 32.
In some embodiments, an lead-in terminal 534 configured to connect with the power supply is disposed on n end surface of the stator 530 facing the tray supporting plate 25, and an lead-out terminal 535 configured to connect with the charger 50 is disposed on an end surface of the rotor 531 away from the stator 530. A first outside cable connected with the power supply is connected to the lead-in terminal 534 such that the conductive slip ring 53 can be electrically connected to the power supply, and a second outside cable connected with the charger 50 is connected to the lead-out terminal 535 such that the conductive slip ring 53 cab be electrically connected to the charger 50. That is, since the stator 530 is still relative to the tray supporting plate 25 and the rotor 531 is still relative to the tray shaft 32, when the tray shaft 32 rotates relative to the tray supporting plate 25, the rotor 531 rotates relative to the stator 530.
With the three-dimensional circulating garage 100 according to embodiments of the present disclosure, the stator 530 and the rotor 531 are fitted over the tray shaft 32, the stator 530 is still relative to the tray supporting plate 25 and the rotor 531 is still relative to the rotation shaft 92, so that the installation of the conductive slip ring 53 cannot influence the installation of other pans, and a space occupation of the conductive slip ring 53 in a length direction of the tray shaft 32 is not limited, and thus it is suitable for conditions in which a large current is required. Also, since each of the stator 530 and the rotor 531 has a hollow structure, and the lead-in terminal 534 and the lead-out terminal 535 are disposed on two ends of the conductive slip ring 53, there is no need to route an electric cable inside the tray shaft when installing the electric cable. Thus, the manufacturing difficulty of the tray unit 3 is simplified, and the manufacturing cost is reduced.
In some embodiments, as shown in
In further embodiments, as shown in
In some embodiments, the rotation stopping fork 250 includes a cylindrical rod, and thus the rotation stopping fork 250 has a simple structure and a low manufacturing cost. In some embodiments, as shown in
In some embodiments, each of the lead-in terminal 534 and the lead-out terminal 535 includes an aviation plug, and thus it is convenient for installation and maintenance, and the conductive slip ring 53 can be protected from being scraped due to cable damage so as to reduce the usage cost.
In some embodiments, as shown in
In some embodiments, as shown in
In other words, each two adjacent sub-sliding wire 510 are separated from each other by one insulation segmentation element 511, and the plurality of sub-sliding wires 510 and the plurality of insulation segmentation elements 511 are connected with one another to form the sliding wire guide rail 51 which has the ring shape. The external power supply supplies power to each sub-sliding wire 510, i.e., the sliding wire guide rail 51 is supplied with power through multiple points, namely in a multi-point power supply manner. Thus, due to the multi-point power supply, an electric current passing through each sub-sliding wire 510 is reduced, and each sub-sliding wire 510 cannot influence one another, so that the whole system can run normally and safely, and it is convenient for maintenance and troubleshooting of the whole system.
In some embodiments, each sub-sliding wire 510 has two electric contacts located at two ends of each sub-sliding wire 510 respectively. Specifically, in one embodiment, the insulation segmentation element 511 includes two cable connectors 55 which are configured as the electric. contacts of the corresponding sub-sliding wire 510. It should be noted that a part of the insulation segmentation element 511 located between the two sub-sliding wires 510 connected therewith should be made of insulating material, such that the two adjacent sub-sliding wires 510 are insulated and spaced apart from each other by the insulation segmentation element 511. And, a part of the insulation segmentation element 511 used for installing the cable connector 55 may be made of conductive material such that electric cu rent can be easily transmitted into the sub-sliding wire 510.
In some embodiments, each sub-sliding wire 510 has an equal length, and a number of the sub-sliding wires 510 is equal to that of the vehicle carrying plates 30. For example, in one embodiment, the three-dimensional circulating garage includes twelve vehicle carrying plates and twelve sub-sliding wires 510, and thus the electric current passing through the sliding wire guide rail 51 is reduced, and the three-dimensional circulating garage 100 can operate normally and safely. It should be noted that, when the sub-sliding wire 510 is configured to have an arc shape, the length of the sub-sliding, wire 510 refers to an arc length of the sub-sliding wire 510.
In some embodiments, as shown in
With the sliding wire guide rail 51 according to embodiments of the present disclosure, each sub-sliding wire 510 includes the plurality of single-stage sliding contact wire 512, and then an electric current in each single-stage sliding contact wire 512 is decreased, and a number of the single-stage sliding contact wires 512 connected to the live wire can be regulated according to a needed electric quantity. Therefore, stability of the power supply device can be improved and an early cost can be reduced. In addition, it is convenient for later maintenance and troubleshooting of the power supply device.
In one embodiment, two single-stage sliding contact wires 512 connected with each other in parallel are connected to a same live wire, and thus the electric current in each single-stage sliding contact wire 512 can be further decreased. For example, in one embodiment, each sub-sliding wire 510 includes eight single-stage sliding contact wires 512, six of the eight single-stage sliding contact wires 512 are divided into three groups, and each group includes two single-stage sliding contact wires 512 connected with each other in parallel. Each group is connected to a live wire of a three phase power source, and the other two of the eight single-stage sliding contact wires 512 are connected to a null wire and a ground wire of the three phase power source respectively.
In some embodiments, as shown in
In some embodiments, as shown in
Specifically, a bottom end of the support frame 15 may be fixed on the top wall of the first fixing support 10 via welding or screw connection. It should be noted that there are no particular limitations for a shape of the support frame 15. For example, in one embodiment, the support frame 15 has a substantial L shape.
In some embodiments, the expansion and contraction device 6 includes an expansion and contraction frame 60, a second regulating plate 61 and a regulation fixing element (not shown). The expansion and contraction frame 60 is connected with the sliding wire guide rail 51, a regulating hole 601 having ate obround shape is formed in a lower portion of the expansion and contraction frame 60, the second regulating plate 61 over the first regulating plate 16 is disposed on the expansion and contraction frame 60, and the regulation fixing element passes through the regulating hole 601 and is fixed on the support frame 15. It should be noted that when there are two support frames 15, there are two second regulating plates 61 correspondingly. The two second regulating plates 61 are disposed on the expansion and contraction frame 60 respectively. The expansion and contraction frame 60 may be configured to be a frame whose bottom is open.
In some embodiments, the three-dimensional circulating garage 100 further includes a regulating element (not shown) fitted with the threaded hole 160, and an upper end of the regulating element passes through the threaded hole 160 and rests against a lower surface of the second regulating plate 61, such that a distance between the first regulating plate 16 and the second regulating plate 61 can be regulated by regulating a length of a portion of the regulating element stretched out of the threaded hole 160. It should be noted that the length of the portion of the regulating element stretched out of the threaded hole 160 is a length of a portion of the regulating element stretched out beyond the first regulating plate 16.
When an expansion amount of the sliding wire guide rail 51 needs to be regulated, the regulation fixing element s firstly loosen, so that the expansion and contraction frame 60 can move up and down relative to the support frame 15, and then the regulating element is turned to regulate the length of the portion of the regulating element stretched out of the threaded hole 160. As the upper end of the regulating element rests against the lower surface of the second regulating plate 61, the second regulating plate 61 is driven to move up and down by a movement of the regulating element, and thus the expansion and contraction frame 60 is driven to move up and down so as to drive the sliding wire guide rail 51 to stretch out and draw back. Thus, the sliding wire guide rail 51 can be regulated.
When the expansion and contraction frame 60 moves to a required position, the regulation fixing element is tighten, and thus the expansion and contraction frame 60 is fixed on the support frame 15 via the regulation fixing element.
With the expansion and contraction device 6 according to embodiments of the present disclosure, by providing the first regulating plate 16, the second regulating plate 61 and the regulating element, it is convenient to regulate an up and down movement of the expansion and contraction frame 60, thus facilitating the regulation of the sliding wire guide rail 51.
In some embodiments, as shown in
It should be noted that, as shown in
Specifically, as shown in
The second plate 802 has a through hole penetrated through the second plate 802 along a thickness direction thereof. The second plate 802 includes a first surface 803 and a second surface 804 opposite to each other. In some embodiments, the through hole has an obround shape so as to improve universality of the regulating device 8.
In some embodiments, a first end of the regulating column 81 is fixed on the first fixing support 10 and the regulating column 81 is placed on the first surface 803. In some embodiments, as shown in
In some embodiments, the positioning element 82 is configured to have a substantial U shape and fitted over the regulating column 81, and two ends of the positioning element 82 pass through the through hole and are fitted with a regulating nut 83 respectively. The regulating nut 83 rests against the second surface 804 so as to position the positioning element 82. When the regulating nut 83 rests against the, second surface 804, the positioning element 82 is fixed on the second plate 802, and thus the regulating column 81 is positioned on the second plate 802 so as to avoid a movement of the regulating, column 81.
The distance between the clamp 7 and the first fixing support 11 is regulated by regulating a length of a portion of the regulating column 81 placed on the first surface 803. As shown in
In some embodiments, as shown in
In some embodiments, as shown in
In some embodiments, as shown in
The working process of the three-dimensional circulating garage 100 according to embodiments of the present disclosure will be described in detail hereafter.
1) Storing, and Charging Vehicle
A driver drives the vehicle onto the lowermost vehicle carrying plate 30, and then inserts the charging gun into the charging port of the vehicle. By swiping card or pressing a storing button on the manual operation interface of the controller, the three-dimensional circulating garage 100 is activated, then the vehicle is moved and the charging function of the charger 50 is activated, and thus the vehicle is charged by the charger 50, and also, it is prepared for storing and charging subsequent vehicles.
2) Taking Out Vehicle
By swiping card or pressing a taking out button on the manual operation interface, the three-dimensional circulating garage 100 moves the vehicle carrying plate 30 on which the vehicle to be taken out is placed to the lowermost position and shuts off the charger 50, then the driver pulls the charging gun out of the charging port of the vehicle and puts the charging gun back to a set-down location, and then the driver can drive the vehicle out of the vehicle carrying plate 30 directly.
With the three-dimensional circulating garage 100 according to embodiments of the present disclosure, problems about storing and charging the electric vehicle are solved at the same time.
Reference throughout this specification to “an embodiment”, “some embodiments”, “an example”, “a specific example”, or “some examples” means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present disclosure. The appearances of the phrases throughout this specification are not necessarily referring to the same embodiment or example of the present disclosure. Furthermore, the particular features, structures, materials, or characteristics may be combined in any suitable manner in one or more embodiments or examples.
Although explanatory embodiments have been shown and described, it would be appreciated by those skilled in the art that the above embodiments cannot be construed to limit the present disclosure, and changes, alternatives, and modifications can be made in the embodiments without departing from spirit, principles and scope of the present disclosure.
| Number | Date | Country | Kind |
|---|---|---|---|
| 201410469382.2 | Sep 2014 | CN | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/CN2015/089558 | 9/14/2015 | WO | 00 |
