The present invention relates to an automatic guided vehicle for handling reels and a related control method.
Laser-guided vehicles, hereafter referred to alternatively as LGVs, are used to handle load units, comprising loads such as reels, or goods on pallets as an alternative to manually operated forklifts.
In order to optimize the handling operations of the load units within predefined areas in the absence of operators, automatic guided vehicles are able to autonomously pick up a pre-determined load placed in a particular area to transfer it and deposit it, again autonomously, in another predefined area, which can be identified on a shelf of a specific storage shelving.
The shelves of such storage shelving are suitably sized to allow pallets with goods and/or similar loads to be placed on top of the shelf itself.
In the case of reels laid out, they must be handled in the following two configurations:
The main difficulties in this application are coordinating the two modes of picking and switching from one to the other.
Moreover, in both cases, reliability and efficiency must be ensured despite the very small tolerable margins of error.
Particularly critical is the working condition in which the reels are made of relatively expensive materials, i.e., when contact with the external surface of the load units must be limited so as not to damage them, and when working with reels with a diameter of less than 300 mm.
The object of the present invention is to make an automatic guided vehicle for handling reels and a related control method capable of reliably and repeatably handling reels laid out indifferently according to the two different configurations.
A further object of the present invention is to make an automatic guided vehicle for handling reels and a related control method which allows switching from one handling configuration to another in a fully automatic manner.
These objects according to the present invention are achieved by making an automatic guided vehicle for handling reels and a related control method as set forth in the independent claims.
Further features are comprised in the dependent claims.
The features and advantages of an automatic guided vehicle for handling reels and a related control method according to the present invention will be more apparent from the following description, which is illustrative and not limiting, referring to the accompanying schematic drawings in which:
With reference to the figures, an automatic guided vehicle, overall indicated with 10, for handling reels 100 is shown.
A first load unit 110, shown in
A second load unit 120, shown in
The automatic guided vehicle 10 comprises a telescopic upright 11 integral with a vehicle frame 10 and bearing a fork carriage 13 provided with one or more pairs of forks 12 (
An equipment 14 is interposed between the fork carriage 13 and the upright 11, which controls the essential movements of the forks 12, namely the tilting of the fork carriage 13, the global translation of the fork carriage 13 and the symmetrical positioning of the pair of forks 12.
The equipment 14 comprises a plurality of actuators and relative support plates, as well as a plurality of photocells for detecting the environment surrounding the forks and a plurality of sensors for detecting the position of the forks 12 and thereby controlling said essential movements of the forks 12.
The equipment 14 comprises a pair of actuators 15, preferably cylinder actuators, articulated at opposite sides of the fork carriage 13 and acting in a plane orthogonal to the lifting plane of the forks 12, identified by the telescopic uprights 11, to change the inclination of the forks 12 with respect to the ground. The tilting movement is used to recover the flexion of the forks 12 when transporting loads with high mass.
The equipment 14 comprises an actuator 16, preferably a cylinder actuator, connected between the upright 11 and the fork carriage 13, to control the overall translation of the fork carriage 13 laterally along straight guides 17 in the lifting plane of the forks 12.
The equipment 14 further comprises a pair of actuators 18, preferably cylindrical actuators, each connected between the upright 11 and a respective fork 12, for symmetrically moving the forks 12 towards and away from each other in the lifting plane of the forks 12.
According to an embodiment shown in the figures, by way of non-limiting example, the two forks 12 are mechanically connected by means of a pinion 19 and a rack 20 so as to obtain the movement of the forks in mutual approach and distancing with a perfectly symmetrical positioning. Alternatively, the symmetrical positioning can be achieved by an independent movement of the forks.
The movement of the individual forks 12 in relation to the fork carriage 13, when approaching and moving away from each other, occurs along straight guides 21, which are parallel to each other and lie in the lifting plane of the forks.
The automatic guided vehicle 10 according to the present invention, has a pair of forks 12 having a specific profile designed to perform both the operations of picking up the reel 100 with unknown diameter, arranged longitudinally to the vehicle on a cradle 111, and the operations of picking up the reel 100 with unknown diameter, arranged transversely to the vehicle raised from the ground and supported by the pole 122 positioned on the shelving structure 121 (
According to the invention, each fork 12 has a substantially rectangular section with a height significantly greater than the base, preferably twice the height with respect to the base.
Opposite facing walls 22 of the forks 12 are flat and approachable in direct contact with each other, so that the two joined forks 12, in a fully closed configuration, are inserted into the core 101 for handling the reel 100 in the first load unit 110 and behave as if they were a single fork.
Moreover, each fork 12 bears only on its outer wall two bevelled edges 23, while the wall facing 22 the other fork bears no bevelled edges. When the pair of forks 12 is in a juxtaposed configuration, i.e., forming a single compound fork, the joined forks 12 have bevels 23 along all the four outward facing edges to facilitate the forking.
The profile of the forks 12 is such as to ensure a margin of about 25 mm in each direction, both laterally and vertically, with respect to the hole of the core 101 of the first load unit 110 to be forked for handling.
The handling of the reel 100 in the configuration 120 is instead performed with the forks 12 of the pair of forks in an open configuration, i.e., separated from each other, and each gripping on opposite sides of the reel 100 on the support pole 122.
According to the invention, each fork 12 has on its upper face a “V” shaped seat 24 as an invitation for the pole 122 of the second load unit 120.
In order to grip the pole 122, the forks 12 will be positioned with an opening established by software in order to have a lateral margin of at least 35 mm for forking the second load unit 120.
According to the invention, switching from one configuration to another is fully automatic and managed by the vehicle, without the need for operator intervention.
Furthermore, along each of the forks 12, seats 25 are included for the sensors and photocells embedded in the forks 12 so as not to create additional protruding space with respect to the profile of the forks 12.
Preferably, a tapered tip portion 26 is included on the lower face of each fork 12, which accomplishes a lightening without however compromising the flexion of the forks and facilitates the forking of the second load unit 120.
This dimensioning of the two forks 12 which can be placed side by side advantageously allows to reconcile structural and geometric requirements. In fact, knowing the weight of the maximum load, it is necessary to ensure a correct flexion value and to verify the tensional state, with the appropriate safety coefficients. Furthermore, given the size of the load units available for fork entry, it is necessary to ensure sufficient margins to ensure the correct operation of all the sensors, particularly during the deposit and picking operations.
The automatic guided vehicle 10 further comprises a plurality of photocells preferably placed on the equipment 14 or on the forks 12, shown in
At least one lateral photocell 30, 30′, preferably of the laser distance measuring type, verifies the positioning of the fork carriage 13 with respect to the shelving 121. The lateral photocell 30, 30′ is used to check that the fork carriage 13 is in the correct position in the lateral direction in relation to the shelving. The at least one lateral photocell 30, 30′ is placed on board the fork carriage 13 or the vehicle frame 10 depending on the geometry of the shelving and the load units to be handled, in an external lateral position with respect to the forks 12.
A pair of photocells for checking the shape of a transversal reel 31, is located in the lower area of the fork carriage 13, integral with the latter or with the forks 12, and is front-facing.
These are preferably laser distance measuring photocells used to verify the correct position of the reel 100 on its pole 122 in the second load units 120.
A reading photocell for reading the transversal reel diameter 32, is positioned in the center of the equipment 14 and facing outwards. This is preferably a laser distance measuring photocell used to measure the diameter of the second load unit 120, when it is positioned in the special V seat 24 of the forks 12.
At the base of each fork 12, on the external face and facing frontally in a direction parallel to the extension of the fork, a photocell for core searching 33a, 33b of the first load unit 110 is integrally fixed. It is preferably a laser distance measuring photocell.
The two photocells 33a, 33b are preferably arranged, one at the upper face of the forks 12 and the other at the lower face of the forks 12, substantially in diagonal positions with respect to each other when looking at the front of the forks 12 placed side by side, i.e., in a closed position.
The photocells for core searching 33a, 33b read the hole of the core 101 of the reel 100 of the first load unit 110, when the forks 12 are fully closed.
On the lower face of at least one of the two forks 12, near the base thereof, a photocell is positioned for detecting the forked core 34 of the reel 100 of the first load unit 110. It is preferably a direct reflection photocell which reads in a vertical downward direction. It is used to check that the first load unit 110 has been forked correctly up to the stroke end by the forks in the closed position.
Photocells for pole detection 35, which detect the presence of the pole 122 in the V seat 24 of the forks 12, for the second load unit 120 with transversal reel are placed on both forks 12 facing upwards at the V seat 24.
A pair of load cells 36 is placed on board the equipment 14 between the fork carriage 13 and the actuators 15 for tilting the plate 13 (
The load cells 36 are used for:
Known sensors (encoders) are also installed on board the equipment 14 of the automatic guided vehicle 10 to measure the position of the equipment 14 at all times. In particular, the following positions should be noted:
In the automatic guided vehicle 10 according to the invention, a step of switching from a configuration for handling a longitudinal reel 100 in the first load unit 110 to a configuration for handling a transverse reel 100 in the second load unit 120 is implemented by automatically bringing the forks 12 from a closed position, with the forks side by side in contact with each other, to an open position, with the forks separated at the distance for gripping, and vice versa.
The automatic guided vehicle 10 according to the invention performs four different types of movements:
All the handling operations of the equipment 14 are controlled by the vehicle software, in a currently known manner, through the sensors for measuring the position of the equipment 14 in every moment.
All the types of handling use sensors installed on board the vehicle to align the equipment 14 and/or forks 12 to each individual tunnel for each operation.
For all of the described handlings, the automatic guided vehicle 10 according to the invention is placed in a known manner by means of the laser guidance system of the vehicle, which has the plant as a reference, in a so-called “target position”, i.e., in a position with the equipment in the correct longitudinal and lateral position for performing a picking or depositing operation.
The picking cycle of the first load unit 110 performed by the vehicle 10 in automatic mode (cycle a)) comprises the following steps:
The calculation of the diameter of the reel of the first load unit 110 arranged longitudinally with respect to the vehicle 10 is performed during the picking operation, after having identified the hole of the reel core with the photocells for core searching 33a, 33b. Therefore, if the height of the forks 12 in the indicated position (measured dynamically with a wire encoder) and the height and geometry of the support surface (constant for the application) are known, the diameter of the first load unit 110 can be calculated.
The deposit cycle of the first load unit 110 carried out by the vehicle 10 in automatic mode (cycle b)) comprises the following steps:
The picking cycle of the second load unit 120 carried out by the vehicle 10 in automatic mode (cycle c)) comprises the following steps:
The calculation of the diameter of the reel of the second load unit 120 arranged transversely with respect to the vehicle 10 is carried out at the end of the picking operation. Knowing the distance of the reel axis from the shoulder of the forks (constant because the product axis is always at the V-shaped seat 24 on the forks 12), the distance of the reel circumference is measured with the photocell for reading the transverse reel diameter 32 and the diameter is calculated.
The deposit cycle of the second load unit 120 carried out by the vehicle 10 in automatic mode (cycle d)) comprises the following steps:
The automatic guided vehicle for handling reels and a related control method object of the present invention has the advantage of allowing the passage from handling reels in a longitudinal configuration to handling reels in a transverse configuration in a fully automatic manner with the same equipment.
The automatic guided vehicle for handling reels and a related control method thus devised is susceptible to numerous modifications and variants, all of which are within the scope of the invention; furthermore, all the details can be replaced by technically equivalent elements. In practice, the materials used, as well as their dimensions, can be of any type according to the technical requirements.
Number | Date | Country | Kind |
---|---|---|---|
102021000009353 | Apr 2021 | IT | national |
Number | Name | Date | Kind |
---|---|---|---|
20130259618 | McGrane | Oct 2013 | A1 |
20180319594 | Blevins et al. | Nov 2018 | A1 |
20220332555 | Schiavi | Oct 2022 | A1 |
20220375206 | Onoda | Nov 2022 | A1 |
20230073066 | Chien | Mar 2023 | A1 |
Number | Date | Country |
---|---|---|
108584803 | Sep 2018 | CN |
108584803 | Sep 2018 | CN |
07-315785 | Dec 1995 | JP |
H07315785 | Dec 1995 | JP |
WO 9108164 | Jun 1991 | WO |
Entry |
---|
Italian Search Report dated Jan. 18, 2022 in Italian Application 102021000009353 filed on Apr. 14, 2021, citing documents AA & AO-AQ therein, 11 pages (with English Translation of Categories of Cited Documents & Written Opinion). |
Number | Date | Country | |
---|---|---|---|
20220332555 A1 | Oct 2022 | US |