NZ611912B2 - Transporting system - Google Patents
Transporting system Download PDFInfo
- Publication number
- NZ611912B2 NZ611912B2 NZ611912A NZ61191212A NZ611912B2 NZ 611912 B2 NZ611912 B2 NZ 611912B2 NZ 611912 A NZ611912 A NZ 611912A NZ 61191212 A NZ61191212 A NZ 61191212A NZ 611912 B2 NZ611912 B2 NZ 611912B2
- Authority
- NZ
- New Zealand
- Prior art keywords
- stop
- stops
- stoppers
- crossing
- over
- Prior art date
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- 230000000875 corresponding Effects 0.000 claims description 8
- 229910052729 chemical element Inorganic materials 0.000 claims 1
- 229920000136 polysorbate Polymers 0.000 claims 1
- UIIMBOGNXHQVGW-UHFFFAOYSA-M buffer Substances [Na+].OC([O-])=O UIIMBOGNXHQVGW-UHFFFAOYSA-M 0.000 abstract description 3
- 230000035939 shock Effects 0.000 description 4
- 239000006096 absorbing agent Substances 0.000 description 3
- 239000003990 capacitor Substances 0.000 description 2
- 238000010276 construction Methods 0.000 description 2
- 238000011068 load Methods 0.000 description 2
- 238000004519 manufacturing process Methods 0.000 description 2
- 238000000034 method Methods 0.000 description 2
- 210000003414 Extremities Anatomy 0.000 description 1
- 238000002835 absorbance Methods 0.000 description 1
- 238000006073 displacement reaction Methods 0.000 description 1
- 230000000694 effects Effects 0.000 description 1
- 230000003116 impacting Effects 0.000 description 1
- 230000003993 interaction Effects 0.000 description 1
- 238000011144 upstream manufacturing Methods 0.000 description 1
Abstract
611912 An in-house track-bound transporting system with self-propelling carriages (1) that move on rails (3) is disclosed. At the ends of the rail lines there are buffers or stops which restrain the vehicles are provided for safety reasons. This is important, for example, in the event of malfunctions, in order to prevent a crash etc. involving the vehicles or even undesired entry of the vehicles into specific rail areas. The system has stoppers (7) that interact with stops (8) to prevent the carriages from crossing over open rail ends or track borders. The stoppers (7) collide with the stops (8) in order to prevent a crossing-over, the stops (8) having first and second fixed stop elements (9a, b). The stoppers (7) can be moved (5) between a first crossing-over position and a second crossing-over position such that the first stop elements (9a) can be crossed over in the first crossing-over position of the stoppers (7), and the second stop elements (9b) can be crossed over in the second crossing-over position of the stoppers (7), wherein the first stop elements (9a) cannot be crossed over in the second crossing-over position of the stoppers (7), and the second stop elements (9b) cannot be crossed over in the first crossing-over position of the stoppers (7). The stoppers may be spring loaded to cushion any impact. ns, in order to prevent a crash etc. involving the vehicles or even undesired entry of the vehicles into specific rail areas. The system has stoppers (7) that interact with stops (8) to prevent the carriages from crossing over open rail ends or track borders. The stoppers (7) collide with the stops (8) in order to prevent a crossing-over, the stops (8) having first and second fixed stop elements (9a, b). The stoppers (7) can be moved (5) between a first crossing-over position and a second crossing-over position such that the first stop elements (9a) can be crossed over in the first crossing-over position of the stoppers (7), and the second stop elements (9b) can be crossed over in the second crossing-over position of the stoppers (7), wherein the first stop elements (9a) cannot be crossed over in the second crossing-over position of the stoppers (7), and the second stop elements (9b) cannot be crossed over in the first crossing-over position of the stoppers (7). The stoppers may be spring loaded to cushion any impact.
Description
WO
Dematic Accounting Services GmbH June 5, 2013
Transporting system
The invention relates to an in-plant rail-bound transport system with automotive
vehicles which travel on rails, wherein the system has stop bars to secure against
overrunning of open rail ends or boundaries of travel paths, and is provided with
stops, wherein the stop bars bounce against the stops to prevent overrunning.
Transport systems of this type are used both in the warehousing area and also in the
production area and comprise automotive vehicles. These are usually single-level
rack serving machines, or so-called shuttles or satellite vehicles, which transport
goods, with or without containers, and place them into, and remove them from,
storage in the warehousing and production areas.
At the ends of the rail lines, buffers or stops which restrain the vehicles are provided
for safety reasons. This is important, for example, in the event of malfunctions, in
order to prevent a crash etc involving the vehicles or even undesired entry of the
vehicles into specific rail areas.
From DE 37 34 068 C2, for example, an in-plant rail-bound transport system is known
having automotive vehicles which travel in a rail system with stationary rails and
moveable rails, shunting wagons, lifts, turntables etc. To prevent overrunning of open
rail ends, the vehicles have at least one shock absorber and both the stationary and
also the moveable rails each have at least one stop element which can move between
an operational position, in which they stop the vehicle by abutment of the shock
absorber, and an inoperative position in which they permit passage of the vehicle.
The transfer of the stop elements from the operational position to the inoperative
position is effected by an actuation device only if a moveable rail is positioned in such
a way with respect to the stationary rail that a vehicle can run over the impact point.
However, it has proved to be the case that this type of buffer or stop does not offer
sufficient security in all cases. In addition, construction thereof is troublesome in that
the pivotable stop elements or levers must be provided on each rail end, which is
associated with complex cabling and control and monitoring. In addition, it is also
necessary to monitor how the moveable rails are positioned in relation to the
stationary rails. It is also unclear what happens in the event of a problem with the
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stop elements and their springs (for example, fracture), since then the adoption of the
position which stops the vehicles is not ensured. Furthermore, accessibility to these
parts and maintenance thereof is troublesome and extremely difficult during operation
of the system, especially as the travel paths are adapted to the size of the vehicle and
are often spatially confined.
This object is achieved by the transport system defined in claim 1.
Owing to the fact that the stops have first and second immoveable stop elements and
that the stop bars are able to move between a first overrunning position and a second
overrunning position, wherein the first stop elements can be run over in the first
overrunning position of the stop bars, the second stop elements can be run over in the
second overrunning position of the stop bars and that the first stop elements cannot
be run over in the second overrunning position of the stop bars and that the second
stop elements cannot be run over in the first overrunning position of the stop bars, it is
possible to provide a particularly secure system which prevents overrunning even if a
component fails.
In accordance with the invention, overrunning of the rail ends is possible only if the
stop bars are moved twice, wherein in the first position only the first stop element can
be overrun but the stop bar strikes or bounces against the second stop element. Only
by the second movement, i.e. backwards movement of the stop bar, can the second
stop element then also be overrun. This redundancy therefore ensures that
accidental overrunning cannot take place.
The stop bars are preferably disposed on the vehicles and the stops on the rails.
By using the immoveable stops on the rails only monitoring of the vehicles which is
already provided needs to be carried out. The stops are purely passive and thus do
not need to be monitored. Owing to the generally high number of required overrun
barriers, the fixed stops are extremely inexpensive compared with known solutions.
The monitoring of the stop bars on the vehicles can be carried out by on-board
electronics.
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In addition, the stop bars are preferably formed in such a way that the second
overrunning position, i.e. to some degree the first bounce position, is automatically
adopted by itself, for example, by spring action, if the system fails.
In a preferred embodiment, the first and second stop elements are spaced apart from
each other in the longitudinal direction of the rail line, i.e. in the travel direction of the
vehicles on the rail.
It is then constructionally particularly simple to move the stop bars between the first
and second overrunning position, for example, by pivoting by 90°.
It is thus also useful if the stop bars are formed as driven stops which can move
between the first overrunning position and a second overrunning position, and then
possibly also the driven stops can also move about a pivot axis oriented in the travel
direction. In so doing, the driven stops can be formed to be able to move or pivot
between the first overrunning position and a second overrunning position by at least
° and at most 90° about a pivot axis oriented in the travel direction.
In order to protect the vehicles in the event of the stop bars impacting against the
stops, it is preferred if the stop bars are formed as spring-loaded stops or shock
absorbers which are mounted on both sides in the travel direction of the vehicles. The
impact is therefore absorbed and the vehicle remains undamaged.
It is also feasible to use the interaction between the stop bars and stops for controlled
braking of the vehicles, i.e. combating the kinetic energy during impact not (only) by
shock absorbance but by friction. For this purpose, the stop bars can be provided
with a brake lining which interacts with an inclined braking surface on one of the stop
elements to brake the vehicle in the corresponding non-overrunning position. In other
words, a surface provided with a brake lining is provided on the driven stop of the stop
bar and rubs against an inclined braking surface during "impact" on the stationary stop
on the rail or its stop element, wherein the friction continually increases owing to the
inclined course of the braking surface. More preferably, the inclined braking surface is
disposed on the first stop element and extends approximately vertically and forms a
laterally increasing inclined plane in the direction of travel towards the rail end.
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A preferred variation of the transport system includes a design in which the rails are
formed as essentially C-shaped profiled rails, wherein the opening of the "C" is
disposed inwards and downwards in such a way that the stop bars disposed on the
vehicles can protrude into the essentially C-shaped profile and interact with stop
elements disposed inside the "C". The stop elements can therefore be "hidden in the
rail" and the vehicle can travel on the upper side of the rail.
The described transport system is suitable, in particular, for use in storage and
transport systems with single-level rack serving machines or so-called shuttles or with
satellite vehicles. For example, so-called MultiShuttles are used as single-level rack
serving machines. These are described, for example, in EP 1 254 852 A1.
The system concept is based on autonomous, rail-guided vehicles for transporting
stored goods or containers, which travel inside and outside the storage system. The
system has travel rails which are installed in the preliminary zone, standing or
suspended in a level or in a plurality of levels in each level of the warehouse along the
storage sections. In the case of the MultiShuttles, the vehicles may change levels via
highly dynamic lifts. A corresponding arrangement also applies for possible variations
of other vehicles.
In a further variation, the shuttle or satellite vehicle travels from a transfer machine
such as, for example, a rack serving machine, into the different sections of a storage
system. The transfer within the storage aisle itself is then effected via a transfer
machine which travels to the respective storage section. The shuttle itself then travels
into the storage section where it sets down the load or picks it up and then travels to
the transfer machine. The stops are also provided at the end of the travel path in this
case in order to limit the travel path and prevent a crash.
In many cases the performance of the whole system can be scaled as required by the
addition of further vehicles, which makes this solution extremely economical.
Within the framework of the invention it is clear that stops or stop bars in accordance
with the invention can be provided on the travel paths wherever the rail lines require
corresponding overrunning barriers for safety reasons or for technical reasons or even
to regulate and control the process.
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Further details, features and advantages of the invention will become clear from the
following description of exemplified embodiments with the aid of the drawing in which:
Fig. 1 is a schematic view of a vehicle at a rail end piece in a view from the
front;
Fig. 2a is a side view of the stop bar of the vehicle of Figure 1;
Fig. 2b is a cross-sectional view of the stop bar along the line A-A of Fig. 2a;
Fig. 3 is a plan view of the stop bar of the vehicle of Figure 1 and
Fig. 4 is a view, corresponding to Figure 1, of an alternative embodiment.
Figures 1 to 3 show a shuttle or the satellite, designated as a whole by 1, of a storage
and transport system which conveys goods and/or containers of varying sizes along
the travel path. For this purpose, it includes a load-picking-up means, not shown,
which picks up or sets down the goods and/or containers. The loading space of the
shuttle 1 is between a front and rear region, the mutual spacing of which can be
adjusted according to the goods being transported. In the front region or rear region,
the housing 2 is formed in a box-like manner in each case and accommodates the on-
board electronics, super-capacitors for short-term power supply and to cover power
peaks, radio equipment etc.
The actual power supply and charging of the super-capacitors is effected via current
collectors which "tap" a contact line. The contact line is conventionally formed either
as a separate line or by the travel rail 3.
The travel rail 3 is formed by two parallel rails laterally defining the travel path. The
figures each show only one side thereof since the sides are formed in a corresponding
manner.
The shuttle runs on the travel rail 3 with four wheels 4, two wheels per side.
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The actual running surface 5 for the wheels 4 is formed by the upper side of the rail 3.
The rails 3 are formed as essentially C-shaped profiled rails, wherein the opening 6 in
the "C" is disposed inwards and downwards in such a way that the stop bars 7
disposed on both sides of the shuttle 1 can protrude into the essentially C-shaped
profile and interact with stop elements 9 of the stops 8 disposed inside the "C".
The stops 8 are screwed onto the rail 3 in a fixed position and are formed by a first
stop element 9a and a second stop element 9b which are spaced apart from each
other in the travel direction, i.e. in the longitudinal direction of the rail line and form
mutually offset stop surfaces 10a, b for the stop bars 7.
The first stop element 9a is located in the longitudinal direction and travel direction of
the shuttle 1 upstream of the second stop element 9b.
The first stop element 9a is disposed in the upper region of the inner chamber of the
rail 3 and extends completely between the side walls of the rail 3.
The second stop element 9b is screwed as a block to the inside of the external side
wall of the rail 3 in the lower region and protrudes by approximately one third of the
width of the inner space of the rail 3 into this inner space.
The stop bars 7 are formed as driven stops which each have a driven stop 11 which
can be formed, for example, by a plate and is moveable between the first overrunning
position and a second overrunning position about a pivot axis 12 oriented in the travel
direction.
The driven stop 11 is able to move by 90°about the pivot axis 12, oriented in the travel
direction, between the first overrunning position and a second overrunning position.
In the first overrunning position, the stop 11 is approximately horizontal and in the
second overrunning position it is approximately vertical. It is dimensioned such that in
the first overrunning position it can run over the first stop element 9a and contacts the
second stop element 9b (or the stop surface 10b thereof) and in the second
overrunning position it can run over the second stop element 9b and contacts the first
stop element 9a (or the stop surface 10a thereof) when the shuttle 1 travels along the
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rail 3 and "meets" the stops 8.
In order to effect the pivot movement (indicated by the arrow S in Figure 1) of the
respective stop 11, an electric motor 13 is provided which is switched off upon
reaching the respective overrunning position by actuation of an appropriately placed
switch 14.
In a further application, in particular when the vehicle leaves the travel region only in
exceptional cases such as repair, the pivot movement can also be effected by a
manual actuating element.
The stop 11 of the stop bar 7 is spring-mounted on both sides in the travel direction of
the vehicles by means of a spring 15a, b. The stop 11 and its mechanism are
disposed for this purpose on a platform 16 forming a type of carriage, which platform
is disposed so as to be longitudinally displaceable inside a profile 17 which has an
approximately square cross-section. The displacement along the profile 17 is damped
by the spring 15 disposed inside the profile.
This type of construction also has the advantage that the stop bars 7 can therefore be
attached to the shuttles on both sides as an assembly, for which purpose the stop bar
has in each case corresponding studs 18 at the ends of the profile 17.
During operation, function is as follows:
The shuttle 1 moves in the travel direction along the rail 3, i.e. in the direction looking
towards Figure 1, and for these reasons should also always run over the stop 8 in a
controlled manner. For this purpose, when the first stop element 9a is reached, the
stop 11 is pivoted downwards by 90° from the vertical position into the horizontal
which means that the first stop element 9a can be passed. The stop 11 is then
pivoted back up by 90° into the vertical position upon reaching the second stop
element 9a after overcoming the distance between the two stop elements, which
means that the second stop element 9b can be passed.
This process is controlled and requires two specific movements of the stop bars 7 in
order to allow the shuttle 1 to pass.
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If a problem occurred, these two coordinated movements of the stop 11 to overcome
the respective stop elements 9a, b would not take place, which means that the shuttle
1 would become "stuck" at the stop 8.
Figure 4 shows an alternative embodiment of the stop bars and stops, wherein the
structure of the shuttles 1 and rails 3 correspond to the embodiment above. In order
to avoid repetition, only the differences will be discussed.
The first stop element 9a' is now formed analogously to the first stop element 9a but
screwed only to the inside of the inner side wall of the rail 3 in the upper region and
protrudes approximately by one third of the width of the inner space of the rail 3 into
this inner space.
In contrast to the embodiment above (or the second stop element 9b'), the first stop
element 9a' also has an inclined braking surface 19'.
The braking surface 19' extends approximately vertically and is formed by an inclined
plane which increases laterally in the direction of travel towards the rail end.
The stop bar 7' is formed as a lever 11' which can move about a pivot axis 12' and is
formed and dimensioned to contact the second stop element 9b' with its tip 20'. In
order to cooperate with the braking surface 19', the lever 11' has a brake lining 21'
which is disposed in a U-shaped recess 23' in the lever 11', and with which the lever
11' engages around the attachment wall 22' of the first stop element 9a' of the rail 3'.
For this purpose, the brake lining 21' is disposed on an approximately vertically
extending limb of the U of the recess 23' - as seen in the second overrunning position
- so that it interacts with the inclined braking surface 19' to brake the shuttle in the
corresponding non-overrunning position or second overrunning position, wherein the
friction increases as the "travel length" increases by reason of the inclination. A pivot
movement S' by about 20° is sufficient to pivot between the two positions of the lever
11'.
Therefore this braking function thus achieved damps the shuttle 1 in a controlled
manner and it is optionally possible to dispense with the spring arrangement of the
embodiment above.
5520496_1 (GHMatters) P93934.NZ BRIDGETW
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Dematic Accounting Services GmbH June 5, 2013
Reference list
1 shuttle
2 housing
3 travel rail
4 wheels
running surface
6 opening
7 stop bars
8 stops
9 stop elements
9a, 9a' first stop element
9b, 9b' second stop element
stop surfaces
10a first stop surface
10b second stop surface
11 driven stop
11' lever
12, 12' pivot axis
13 electric motor
14 switch
spring
16 platform
17 profile
18 stud
19' braking surface
' tip
21' brake lining
22' attachment wall
23' U-shaped recess
S, S' pivot movement
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Claims (3)
- Claims 1 In-plant rail-bound transport system having automotive vehicles (1) which travel on rails (3), wherein the system has stop bars (7) to secure against overrunning 5 of open rail ends or boundaries of travel paths, and is provided with stops (8), wherein the stop bars (7) bounce against the stops (8) to prevent overrunning, characterised in that the stops (8) have first and second immoveable stop ele- ments (9a, b) and that the stop bars (7) are able to move between a first overrunning position and a second overrunning position, wherein the first stop 10 elements (9a) can be overrun in the first overrunning position of the stop bars (7), the second stop elements (9b) can be overrun in the second overrunning position of the stop bars (7) and that the first stop elements (9a) cannot be overrun in the second overrunning position of the stop bars (7) and that the second stop elements (9b) cannot be overrun in the first overrunning position of 15 the stop bars (7).
- 2 Transport system as claimed in claim 1, characterised in that the stop bars (7) are disposed on the vehicles (1) and the stops (8) are disposed on the rails (3).
- 3 Transport system as claimed in claim 1 or 2, characterised in that the first and second stop elements (9a, b) are spaced apart from each other in the longitudi- nal direction of the rail path (3). 25 4 Transport system as claimed in any one of the preceding claims, characterised in that the stop bars (7) are formed as driven stops (11) which can move be- tween the first overrunning position and a second overrunning position. 5 Transport system as claimed in claim 4, characterised in that the driven stops 30 (11) can move about a pivot axis (12) oriented in the travel direction. 6 Transport system as claimed in claim 4 or 5, characterised in that the driven stops (11) can move between the first overrunning position and a second over- running position by at least 20° and at most 90° about a pivot axis (12) oriented 35 in the travel direction. 5520496_1 (GHMatters) P93934.NZ BRIDGETW 110204WO Dematic Accounting Services GmbH June 5, 2013 7 Transport system as claimed in any one of the preceding claims, characterised in that the stop bars (7) are formed as spring-loaded stops (11) on both sides in the travel direction of the vehicles. 8 Transport system as claimed in any one of claims 1 to 7, characterised in that the stop bars (7') are provided with a brake lining (21') which interacts with an inclined braking surface (19') on one of the stop elements (9a') to brake the vehicle (1) in the corresponding non-overrunning position. 9 Transport system as claimed in claim 8, characterised in that the inclined braking surface (21') is disposed on the first stop element (9a') and extends approximately vertically and is formed by an inclined plane (21') which increases laterally in the direction of travel towards the rail end. 10 Transport system as claimed in any one of the preceding claims 2 - 9, characterised in that the rails are formed as essentially C-shaped profiled rails (3), wherein the opening (6) of the "C" is disposed inwards and downwards in such a way that the stop bars (7) disposed on the vehicles (1) can protrude into 20 the essentially C-shaped profile and interact with stop elements (9a, b) disposed inside the "C". 5520496_1 (GHMatters) P93934.NZ BRIDGETW
Applications Claiming Priority (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
DE102011000447.5 | 2011-02-01 | ||
DE102011000447A DE102011000447A1 (en) | 2011-02-01 | 2011-02-01 | transport system |
PCT/EP2012/050826 WO2012104154A1 (en) | 2011-02-01 | 2012-01-20 | Transporting system |
Publications (2)
Publication Number | Publication Date |
---|---|
NZ611912A NZ611912A (en) | 2015-01-30 |
NZ611912B2 true NZ611912B2 (en) | 2015-05-01 |
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