DE102020122388A1 - Shuttle for a shelving system and shelving system - Google Patents

Abstract

The invention relates to a shuttle (8) for a shelving system (2) with a load handling device (10) for load carriers (12) with a current collector (61) for supplying power to the shuttle (8) via a busbar (60) of the shelving system (2), the shuttle (8) being set up to be operated with an AC voltage of 230V applied to the current collector (61). The invention also relates to a shelf system (2) for a corresponding shuttle (8), the shelf system (2) comprising a power rail (60) to which 230V AC voltage is applied.

Description

The invention relates to a shuttle for a shelf system and a shelf system.

In the automated storage technology in the sub-area of small load carriers, the load carriers are usually transported by a shuttle system in a rack system, which is therefore also referred to as a shuttle warehouse. Small load carriers, which are often designed as boxes, are load carriers with a maximum dimension of usually 400x600mm, a maximum height of 600mm and a maximum weight of 50kg.

The associated shelving system includes several shelves arranged side by side, each of which can comprise several levels. Aisles for at least one shuttle are arranged between each two shelves. This transports the load carriers to a shelf compartment assigned by the logistics system and stores them there. Conversely, the shuttle can also remove a load carrier from a shelf and transport it to a transfer station. The transfer station is usually arranged on a front side of a shelf and interacts with elevators that transport the load carriers to the different levels of the shelves. At the transfer station, the load carrier is transferred from the elevators to the latter, it being possible for the transfer station to be driven and/or non-driven. From the transfer station, the load carrier is taken over by the shuttle and then transported by it to the assigned shelf compartment. There the shuttle is positioned to the shelf and the load carrier is brought to the specified position in the shelf. Existing shuttle systems can be divided into two different designs. A first embodiment are shuttles that are permanently supplied with voltage and are operated with low voltage, ie with a maximum voltage of 24V. The voltage of 24V can be supplied by busbars, which are often designed as double busbars (2 phases). However, particularly in the case of long aisles, the low voltage causes voltage drops in the busbars, which, according to the prior art, can be compensated for by further feed points along the busbar. However, this has the disadvantage that additional cable connections to the feed points are required, which has a negative effect on the manufacturing costs of the shelving systems.

The second embodiment are autonomous shuttles with high-performance capacitors, so-called supercapacitors or supercaps, or with accumulators, both of which also provide a 24V-60V voltage. If the power requirement increases, for example due to the demand for higher acceleration or higher shuttle speeds, the power requirement increases accordingly and systems with 24V-60V voltage reach their performance limit.

The object of the present invention is to specify a shuttle and a racking system which enables an improved energy supply to the shuttles.

This object is achieved by a device having the features of independent claim 1. The subclaims relate to advantageous developments and variants of the invention.

A shuttle according to the invention for a shelving system comprises a load handling device for load carriers and a current collector for supplying power to the shuttle via a power rail of the shelving system. According to the invention, the shuttle is set up to be operated with an AC voltage of 230V applied to the pantograph.

The use of 230V AC voltage has the advantage that even in a long aisle in a shelving system, the voltage drop along the power rail is so low that it can be neglected. This eliminates the need for additional feed-in points on the busbar, which simplifies the structure of the shelf.

In particular, the drive of the shuttle can be designed in such a way that it can be operated with 230V AC voltage. This has the advantage that travel drives or motors, in particular for the drive wheels of the shuttle, can be used with a sufficient power reserve. Both shuttles with only two driven wheels and shuttles with four driven wheels, i.e. with all-wheel drive, are possible. The power reserve prevents the engines and/or travel drives from reaching their performance limits in the event of future increasing demands on the shuttle's acceleration and/or speeds. Furthermore, compared to the 24V-60V technology, it is often possible to use more cost-effective travel drives.

An advantage of AC voltage is that the voltage can be transmitted over longer distances with less power loss. This makes feeding in longer lengths easier, and more cost-effective materials can be used for the voltage transmission. white Furthermore, due to the lower currents that occur, thinner cables can be used and the power supply is more robust to dirty or corroded contacts due to the higher voltage.

In addition, there is a large selection of standardized components, in particular protective devices (RCD/FI) for 230V technology. In the case of an existing 400V network, it can be switched to 230V without a converter.

In addition, the use of the 230V AC voltage enables data transmission via the live elements.

In an advantageous variant of the invention, a displacement unit of the load handling device can be designed in such a way that it can be operated with 230V AC voltage.

In particular, a lifting device of the load handling device can be designed in such a way that it can be operated with 230V AC voltage.

In one embodiment of the invention, the shuttle can include a power pack for converting and reducing the 230V AC voltage to 12V and/or 24V and/or 48V DC voltage.

This has the advantage that in addition to the 230V AC voltage, DC voltage is also available on the shuttle. In particular, this opens up the possibility of using, for example, a programmable logic controller (PLC), which is usually operated with 24V, for the load handling device.

In particular, the displacement unit and/or the lifting device can be designed in such a way that they can be operated with 12V or 24V or 48V.

This makes it possible to use smaller and therefore lighter motors or drives for the lower power required by the displacement unit and the lifting device.

In a further variant of the invention, the shuttle can include an emergency power device. In the event of a power failure, the emergency power supply can still supply the shuttle with power, at least for a limited time. As a result, at least the receipt of the data of the current transport order transmitted from a central controller to the shuttle can be ensured. The emergency power device can include, for example, a backup battery, a charger and an inverter. During operation, the backup battery can be charged, for example, via a charger from the 230V AC voltage present on the power rail.

In particular, the emergency power device can be designed in such a way that it can provide a 12V and/or a 24V and/or a 48V DC voltage and a 230V AC voltage.

The 230V AC voltage can be provided by an inverter. A DC voltage can be provided by the output voltage of the backup battery. If a second DC voltage is required, this can be transformed from the output voltage of the buffer battery by an additional transformer in conjunction with an inverter. As a result, all of the shuttle's systems can continue to be used at least for a certain period of time and/or with limited performance.

Furthermore, the emergency power device can be designed in such a way that in the event of a power failure, the load carrier on the load handling device can be moved to a position suitable for moving the shuttle or to the predetermined position of the shelf and the shuttle can be driven to a service point.

This ensures that the shuttle can still be driven to a service point, such as the load carrier transfer station, in the event of a power failure. The shuttle can be moved with a reduced acceleration and speed compared to normal operation. The backup battery can also ensure that the shuttle job stored in the PLC is not lost. This includes the load carrier and the location, i.e. the shelf number, the compartment and the position in the compartment to which the load carrier is to be brought.

Additionally, the shuttle may include a light source. This can also be powered by the backup battery and ensures that in the event of a failure of the shuttle, a light source designed as a light or lamp is available on the shuttle, which also works when the power rail is dead. This can simplify the localization of the shuttle, for example. In case of damage to the shuttle, the light source can support a repair and the installation of additional light sources on the shelf can be avoided. Similarly, it is conceivable a device for monitoring the surroundings, in particular attaching a camera to the shuttle, which records the shuttle itself and its immediate surroundings and transmits the recorded image to an operator or maintenance or repair personnel. In this way, a more complex on-site inspection can become unnecessary in the event of a fault; it is advantageous if the device for monitoring the surroundings or the camera is supplied with energy by the emergency power device.

In an advantageous embodiment of the invention, the load handling device can comprise a receiving platform, a shifting unit and a lifting device, with the load receiving device comprising the receiving platform for receiving the load carrier, the shifting unit for shifting the load carrier into a shelf compartment of the racking system and the lifting device, and with the receiving platform having such a connected to the displacement unit so that it is moved along with the load carrier when it is displaced.

A shelving system for a shuttle as described above includes at least one power rail to which 230V AC voltage is applied.

The busbars can be arranged in all aisles of the shelving system.

In particular, each phase of the power supply to the busbars can be individually secured. This can be part of a safety concept intended to prevent damage to people and the shuttle itself.

Furthermore, the shelving system can include a protective device to protect against contact with a 230V AC power rail.

The conductor rail is usually designed as part of the shuttle's rail and can be painted from above, from the side or from below. It is often arranged in such a way that it is protected from accidental contact by a cover. As a result, short circuits and/or damage to persons or objects can advantageously be avoided. In addition to the cover, further safety concepts can be added for operation, which, for example, effectively prevent access to the shelving system with 230V AC voltage applied to the power rails. These include, for example, barriers, light barriers and/or cameras.

In particular, the protective device can be designed in such a way that the busbars can be switched off based on a signal. The signal can be triggered, for example, by one of the devices described above.

• 1 den prinzipiellen Aufbau eines Shuttle-Regalsystems, in welchem die Erfindung verwirklicht sein kann,
• 2 eine Detailansicht des erfindungsgemäßen Shuttles, und
• 3 eine schematische Darstellung eines mit einem erfindungsgemäßen Regalsystem ausgestatteten Shuttlelagers.

Exemplary embodiments and variants of the invention are explained in more detail below with reference to the drawing. Show it

• 1 the basic structure of a shuttle shelving system in which the invention can be implemented,
• 2 a detailed view of the shuttle according to the invention, and
• 3 a schematic representation of a shuttle warehouse equipped with a racking system according to the invention.

1 shows a top view of a section of a level of a storage system designed as a shuttle warehouse 1 for small load carriers (load carriers) 12, in which two shelves 3 of a shelf system 2 are shown. Small load carriers usually have a base area of 400x600mm and a maximum weight of 50kg, with a maximum height of 600mm. Between the two shelves 3 is an aisle 6 with a rail 9, which is attached to risers 4 of the two adjacent shelves 3, respectively. A shuttle 8 with a load handling device 10 transports a load carrier 12, which is designed as a box in the example shown, along the aisle 6. The load carriers 12 are first transported by elevators 14, which connect the individual shelf levels, from a feed (not shown) to the shown level of the Shelves 3 transported. The load carriers 12 are then transferred by the elevators 14 to a transfer station 13 arranged on the end face of the shelves 3, it being possible for the transfer station 13 to be driven and/or non-driven. The load carrier 10 takes over the load carrier 12 from the transfer station 13 with the aid of the displacement unit 20. The load carrier 12 can now be transported to a shelf compartment 7 provided for storage in the shelves 3. The movement of the shuttle 8 in the lane 6 is illustrated in the figure with a double arrow. The load carrier 12 is stored by the load handling device 10 in one of the four possible positions in the shelf compartment 7 in the example shown. For this purpose, the displacement unit 20 includes a lifting device, not shown in the figure, for lifting the load carrier 12 . In the example shown, the displacement unit 20 also includes a horizontal drive designed as a telescopic drive 30 . The load handling device 10 including the lifting device is pushed into the shelf 7 by the telescopic drive 30 on support profiles 11 . The support profiles 11 are on each side of the shelf 7 on the risers 4 arranged. The load carrier 12 is raised by the lifting device in such a way that it hovers above the support profiles 11 at a distance of 1 mm to 25 mm. At the predetermined position in the shelf 7 , the load carrier 12 is lowered by the lifting device so that it comes to rest on the support profiles 11 . In the example shown, the support profiles 11 are designed in such a way that they are used both as a rail for the load-carrying means 10 and as a support for the load carrier 12 . Alternatively, the rail for the load handling device 10 and the support for the load carrier 12 can also be designed as two independent components. The shuttle 8 runs on the rail 9 and draws its energy from a power rail 60 which is arranged on the rail 9 . The power rail 60 is connected to the front side of the shelf 3 with a cable 71 via which a 230V AC voltage can be fed in from a power supply 70 . The 230V AC voltage has the advantage that the voltage drop and thus the power loss over the length of aisle 6 is negligible when the shuttle is in operation. It is therefore not necessary to arrange any further feed points along the aisle 6 .

2 shows a detailed side view of a shelf 7, in which a shuttle 8 is shown on a rail 9. The shuttle 8 comprises a load handling device 10 with a displacement unit 20 and a lifting device 40. The displacement unit 20 can bring the load carrier 12 to a predetermined position in a predetermined compartment 7 perpendicular to the direction of travel of the shuttle 8. When the load carrier 12 is moved, it is raised by the lifting device 40 and only lowered again when the target position in the compartment 7 is reached. The shuttle 8 moves on the rail 9 via wheels 15 driven by a motor 64. The shuttle 8 shown in the figure is driven by the motor 64 on all four wheels 15. The energy for the shuttle 8 is supplied via a power rail 60 and is taken from the shuttle 8 by current collectors 61 . The current collectors 61 are connected directly, for example by cables, to the motors 64 of the drive wheels 15 which are operated with 230V alternating current. In addition, the pantographs 61 are in the in 2 shown embodiment connected to a power supply 62. This has an output voltage of 24V DC, whereby power supply units with 12V DC or 48V DC can also be used as the output voltage. Thus, both 230V AC voltage and 24V DC voltage are available on the shuttle 8 and the drives and motors 64 of the wheels 15, the displacement unit 20, in particular the in 1 already mentioned telescopic drive 30 and the lifting device 40 can be operated either with 230V AC or with 24V DC. Im in the 2 shown embodiment, only the drive wheels 15 of the shuttle 8 are operated with 230V AC voltage. All other electrical and electronic components are operated with 24V. The connection of the drives and motors 64 with the voltage sources is in the 2 represented by simple lines, not provided with reference numbers, between the power supply line, ie the current collector 61 or the power pack 62 and the components 10, 20, 30, 40, 64. The various electronic components 10, 20, 30, 40 are controlled via a programmable logic controller 63, a so-called PLC, which is also arranged on the shuttle 8. This is usually operated via 24V DC voltage. Furthermore, an emergency power device 65 is arranged on the shuttle 8, which includes a charger 66, a backup battery 67 and an inverter 68. The charger 66, which is directly connected to the 230V AC voltage, charges the buffer battery 67 during operation. If the power supply via busbar 60 is interrupted, electronic components 10, 20, 30, 40 can be operated directly via buffer battery 67, which expediently provides an output voltage (24V) corresponding to components 10, 20, 30, 40. The inverter 68 is connected to the backup battery 67 and the motors 64 of the drive wheels 15 in order to generate 230V AC voltage. The backup battery 67 is designed in such a way that the shuttle 8 can first bring the load carrier 12 safely onto the shuttle 8 or lower it into the shelf 7 in the event of a power failure. The shuttle 8 can then be driven to a service point or to the transfer station 13 . If necessary, the load carrier 12 can be unloaded there and the shuttle 8 can be examined for any damage. A light 69 is also arranged on the shuttle 8, which can turn on automatically in the event of a power failure. This allows the shuttle 8, in the event of a shuttle defect, to be localized more easily in the shelf 3, which may be dark due to the power failure. The displacement unit 20 is arranged on a receiving platform 21 of the load handling device 10 which is connected to the telescopic drive 30 . The telescope drive 30 comprises a motor 45 and a plurality of extension elements 35 connected to form a telescope, with the motor 45 being able to be arranged inside the telescope or outside the telescope. In the illustrated embodiment, the motor 45 is located outside of the telescope. The receiving platform 21 has two U-shaped depressions on both sides of the centrally arranged telescopic drive 30, in each of which a lifting device 40 is arranged. The receiving platform 21 comprises rollers 22 arranged on its outer sides, which are designed in such a way forms are that they are in the in 1 already mentioned U-shaped, horizontally arranged on the risers 4 of the shelf 3 support profiles 11 can run, whereby the receiving platform 21 with the lifting devices 40 and the load carrier 12 placed thereon can be pushed into the shelf 7. The rollers 22 run in the horizontally aligned inner part of the U-shaped support profile 11. When the position in the shelf 7 is reached, the lifting devices 40 are lowered and the load carrier 12 is placed on top of the support profile 11. The load handling device 10 is retracted by the telescopic drive 30 of the displacement unit 20 and the shuttle 8 can carry out another transport job. The lifting device 40 is usually lowered when the shuttle 8 is moving (but can of course also be raised), as a result of which a load carrier 12 located on the load handling device 10 rests on the two lifting devices 40 and on the top of the receiving platform 21 located between the two lifting devices 40. It is also conceivable for the load carrier 12 to rest on supports (not shown) designed for this purpose on the shuttle 8 itself. As a result, the load carrier 12 can be prevented from slipping even when the shuttle 8 accelerates and decelerates more quickly than the load handling device 10 .

3 shows a front view of a shuttle warehouse 1, in which a shelf system 2 with four shelves 3, four elevators 14, four areas with transfer stations 13 and two aisles 6 is shown. The shelves 3 extend into the plane of the drawing to the left and right of the two aisles 6 behind the elevators 14 and the areas with transfer stations 13 and are shown in FIG 3 Front view shown covered by the elevators 14 and the areas with transfer stations 13. The elevator platforms 79 of the elevators 14 are all shown in the lower area of the shelves 3 provided for loading the shelf system 2 . In addition, elevator platforms 79, partially loaded with a load carrier 12, are shown in dashed lines, which are intended to illustrate the movement of the load carriers 12 in the elevator 14. In addition to the elevators 14, each level includes a transfer station 13. In an aisle 6, 2 conductor rails 60 are shown as an example, which are connected to a power supply 70 via a cable 71. The end of the lanes 6, which is formed directly next to the transfer stations 13, can also be used as a service point 78. There, the shuttle 8 can be removed from the aisle 6 of the shelf 3, for example for maintenance or repair. In the lower area of the shelving system 2, access to the shelves 3 extending into the plane of the drawing is blocked by a barrier 72. This can be part of a safety concept which is intended to prevent an operator from entering the shelving system 2 to protect against contact with a busbar 60 connected to the power supply 70 . If one of the doors 73 is opened, a contact (not shown) is broken, for example, whereupon the current supply to the bus bar 60 via the cable 71 is interrupted instantaneously. Other possible safety systems can include a light barrier 74, a camera 75, in particular an infrared camera, or other suitable sensors. These can be used individually or in combination. In addition to interrupting the power supply to the conductor rail 60, warning tones can also be emitted via a loudspeaker 76 or one or more light signals can be emitted via a warning lamp 77. A safety concept for protection against the partially exposed busbars 60 during operation can be ensured by these and other measures not described in detail here.

Reference List

1

Shuttle warehouse

2

shelving system

3

shelf

4

riser

5

cross member

6

alley

7

academic subject

8th

shuttles

9

rail

10

load handling equipment

11

U profile

12

charge carrier

13

transfer station

14

elevator

15

wheel

20

transfer unit

21

recording platform

22

casters

30

telescopic drive

35

pull-out element

40

lifting device

45

engine

60

power rail

61

pantograph

62

power adapter

63

Programmable logic controller (PLC)

64

engine

65

emergency power device

66

charger

67

backup battery

68

inverter

69

light source

70

power supply

71

cable

72

barrier

73

door

74

Photoelectric barrier

75

camera

76

speaker

77

lamp

78

service point

79

elevator platform

Claims (16)

Shuttle (8) for a shelving system (2) with a load handling device (10) for load carriers (12) with a current collector (61) for supplying power to the shuttle (8) via a busbar (60) of the shelving system (2), characterized in that the shuttle (8) is set up to be operated with an AC voltage of 230V applied to the current collector (61). Shuttle (8) to claim 1 , characterized in that the drive of the shuttle (8) is designed such that it can be operated with 230V AC voltage. Shuttle (8) to one of the Claims 1 or 2 , characterized in that a displacement unit (20) of the load handling device (10) is designed in such a way that it can be operated with 230V AC voltage. Shuttle (8) according to one of the preceding claims, characterized in that a lifting device (40) of the load-carrying means (10) is designed in such a way that it can be operated with 230V AC voltage. Shuttle (8) according to one of the preceding claims, characterized in that the shuttle (8) comprises a power pack (62) for converting and reducing the 230V AC voltage to 12V and/or 24V and/or 48V DC voltage. Shuttle (8) to one of the claims 3 until 5 , characterized in that the displacement unit (20) is designed in such a way that it can be operated with 12V or 24V or 48V. Shuttle (8) to one of the Claims 4 until 6 , characterized in that the lifting device (40) is designed such that it can be operated with 12V or 24V or 48V. Shuttle (8) according to one of the preceding claims, characterized in that the shuttle (8) comprises an emergency power device (65). Shuttle (8) to claim 8 , characterized in that the emergency power device (65) is designed in such a way that it can provide a 12V and/or a 24V and/or a 48V DC voltage and a 230V AC voltage. Shuttle (8) to one of the Claims 8 or 9 , characterized in that the emergency power device (65) is designed in such a way that, in the event of a power failure, the load carrier (12) located on the load handling device (10) can be moved to a position suitable for moving the shuttle (8) or to the predetermined position of the shelf compartment (7) can be spent and the shuttle (8) can be driven to a service point. Shuttle (8) according to one of the preceding claims, characterized in that the shuttle (8) comprises a light source (69). Shuttle (8) according to one of the preceding claims, characterized in that the load-carrying means (10), a receiving platform (21), a displacement unit (20) and a lifting device (40), the load-carrying means (10) comprising the receiving platform (21) for receiving the load carrier (12), the shifting unit (20) for shifting the load carrier (12) into a shelf compartment (7) of the shelving system (2) and the lifting device (40) and wherein the receiving platform (21) is connected to the shifting unit ( 20) is connected to the fact that it is moved along with the charge carrier (12) when it is shifted. Shelving system (2) for a shuttle (8) according to one of Claims 1 until 12 , characterized in that the shelving system (2) comprises a power rail (60) to which 230V AC voltage is applied. Shelving system (2) according to Claim 13 , characterized in that each phase of Power supply of the busbars (60) is individually secured. Shelving system (2) according to one of Claims 13 or 14 , characterized in that the shelving system (2) comprises a protective device for protection against contact with a 230V AC voltage applied busbar (60). Shelving system (2) according to one of Claims 13 until 15 , characterized in that the protective device is designed in such a way that the current rails (60) can be switched off on the basis of a signal.

Images