EP3733017A1

EP3733017A1 - Transportable device for the safekeeping of objects

Info

Publication number: EP3733017A1
Application number: EP20171763.4A
Authority: EP
Inventors: Nicola LODI
Original assignee: Grouper 66 Srl
Current assignee: Grouper 66 Srl
Priority date: 2019-04-29
Filing date: 2020-04-28
Publication date: 2020-11-04
Also published as: IT201900006436A1

Abstract

A transportable device (1) for the safekeeping of objects comprises:a transportable container (10), including a containing shell (101) which affords an internal space (101') and a closing shell (102) which is movable relative to the containing shell (101) between an open position (PA) and a closed position (PC);a locking unit (12) connected to the container (10) and movable between an unlocked position (PS) and a locked position (PB); an actuator (13), configured to receive drive signals (131) and connected to the locking unit (12) to move it between the locked position (PB) and the unlocked position (PS); a control unit (14) configured to receive access data (141) and to generate the drive signals (131); a grippable handle (11) connected to the container (10) and configured to be connected to an external restraining object. The control unit (14) is configured to receive an enabling signal (142) and, as a function of the enabling signal (142), to enable the generation of the drive signals (131) in response to the access data (141).

Description

This invention relates to a transportable safekeeping device. This disclosure addresses the technical field of devices used for the safekeeping of objects of various kinds in open places and spaces. More specifically, these devices must be able to be carried by user so they can be easily taken from one place to another. Devices of this kind usually comprise a containing shell, where the objects are housed, and a closing shell, which engages the containing shell to prevent access to the objects from the outside.
Various different methods for locking the closing shell onto the containing shell are known: for example, padlocks and lock and key systems. In some solutions, the use of an electric actuator is also known. The actuator is controlled by a control unit of the device, which is configured to lock and unlock the containing shell to and from the closing shell as a function of access data entered or sent by the user.
To ensure the objects are kept safe, the device must be secured to an external object from which it can be removed only by entering the access data.
Document US2016120321 A1 describes a solution in which a safekeeping enclosure is secured by mechanical fasteners, such as screws or bolts, to a beach bed. This solution has limited flexibility however because the features of the device are strictly correlated with the object it is connected to, making it substantially suitable only for that specific application.
Furthermore, in cases where the security device does not belong to a private individual but is offered as a service in establishments of various kinds, it is necessary to keep a check on how it is used and how access to it is enabled.
Other solutions for security storage devices are described in patent documents US2015/150349A1 , US2018/355638A1 and IT-RA20090037A1 .
Prior art solutions do not provide a system for managing the device which can ensure sufficient control on how the device is used by the establishments that offer it as a service to their customers.
The aim of this disclosure is to provide a transportable device and a method for the safekeeping of objects to overcome the above mentioned disadvantages of the prior art.
This aim is fully achieved by the transportable device and the corresponding method of this disclosure, for the safekeeping of objects, as characterized in the appended claims.
The safekeeping device (in an example application of it) is designed for use outdoors: for example at beach clubs or camping sites; in any case (in other example applications), the safekeeping device may be used indoors, inside confined structures, such as clinics, hospitals or museums, for example.
According to an aspect of it, this disclosure provides a transportable device for the safekeeping of objects.
In an embodiment, the device comprises a transportable container. The transportable container includes a containing shell having an internal space. The transportable container includes a closing shell. The closing shell is movable relative to the containing shell between an open position, where the internal space of the containing shell is accessible from the outside, and a closed position, where access to the internal space of the containing shell is prevented. It should be noted that the open position effectively indicates a position where the containing shell and the closing shell are detached from each other to allow access to the internal space of the containing shell. In the closed position, on the other hand, the containing shell and the closing shell, even if they are in contact with each other to prevent access to the internal space of the containing shell, are not locked to each other and the closing shell can be moved to the open position.
In an embodiment, the device comprises a locking unit. The locking unit is connected to the container. The locking unit is movable between an unlocked position, where the closing shell may be moved from the closed positon to the open position, and a locked position, where the closing shell is in the closed position and forced to remain in the closed position.
In an embodiment, the device comprises an actuator. It should be noted that the term "actuator" is used to mean any component which, by moving, actuates another component. In an embodiment, the actuator is configured to receive drive signals. In an embodiment, the actuator is connected to the locking unit to move it between the locked position and the unlocked position.
In an embodiment, the device comprises a control unit. The control unit is configured to receive access data. The control unit is configured to generate the drive signals. The control unit is configured to generate the drive signals as a function of the access data.
In an embodiment, the device comprises a grippable handle. The grippable handle is connected to the container. The grippable handle is configured to be connected to an external restraining object.
In a preferred embodiment, the fact that the grippable handle is configured to be connected to an external restraining object means that the handle alone, without the aid of any other components, may be hooked to an external object. This definition thus excludes all those handles which, in order to be connected to an external object, require using additional connecting parts such as cords or straps. Also, in a preferred embodiment, this functional limitation implies that the handle must be able to be unfastened from the container and refastened to the container in such a way as to be effectively fastened permanently: that is to say, in such a way that it can be unfastened only by sending the access data to the control unit.
In an embodiment, the control unit is configured to receive an enabling signal. In an embodiment, the control unit is configured to enable generating the drive signals, preferably in response to the access data. In an embodiment, the control unit is configured to enable generating the drive signals as a function of the enabling signal.
That way, the device can be enabled by a signal different from the access signals and managing the use of the device is more precise.
In an embodiment, the device comprises a memory. The memory is configured to store the enabling signal.
In an embodiment, the device comprises a chronometer. The chronometer is configured to measure an enabling interval, preferably in real time. The enabling interval represents a time interval, preferably uninterrupted, in which the control unit is enabled to generate the drive signals in response to the access data. In other words, the enabling interval represents the time that elapses from the moment the device is enabled, that is, from the moment the control unit is enabled to generate the drive signals in response to the access data, that is, enabled to open and close the device (drive signals) in response to external input of a user (access data).
In other words, the enabling signal is a signal received by the control unit and on the basis of which the control unit is enabled to generate the drive signals in response to the access data. In short, in the absence of the enabling signal, the device cannot be used because it is impossible to alternate the closed position with the open position and vice versa. In effect, in the absence of the enabling signal, the device remains open and is incapable of fulfilling its function.
The presence of the enabling signal, in combination with the access data, allows controlling the use of the device, which can thus be given on loan for a predetermined time, after which the control unit is no longer enabled to generate the drive signals as a function of the access data.
In a preferred embodiment, therefore, the enabling signal and the access data are information items received by the control unit but are distinct and used for different purposes.
In an embodiment, the enabling signal includes an enabling time. The enabling time represents a maximum time interval, preferably within which the user is enabled to use the device (that is to say, a length of time in which the control unit is enabled to generate the drive signals in response to the access data). In an embodiment, the control unit is configured to generate a disabling signal. The control unit is configured to generate the disabling signal as a function of a comparison between the enabling interval and the enabling time. In other words, when the enabling interval exceeds the enabling time - that is to say, the user has exceeded the maximum time for using the device - the control unit generates the disabling signal. The control unit is configured to generate the disabling signal and, as a function of the disabling signal, to prevent the generation of the drive signals in response to the access data. In other words, once the disabling signal has been generated, the control signal is no longer enabled to (generate drive signals to) open and close the device in response to external input (in response to the access data) of a user.
The grippable handle comprises a first end. The first end is connected to the container at a first fastening. The grippable handle comprises a second end. In an embodiment, the second end is movable between a fastened position, where it is connected to the container at a second fastening, and an unfastened position, where it is removed from the second fastening.
In an embodiment, the grippable handle comprises a cable. In an embodiment, the grippable handle comprises an articulated joint. The articulated joint is configured to allow the cable (grippable handle) to bend to make it easier to hook it to the restraining object.
These features of the grippable handle make it particularly handy and greatly simplify the operations for hooking it to a restraining object.
In an embodiment, the locking unit is in the locked position when the second end of the grippable handle is in the fastened position. In an embodiment, the locking unit is in the unlocked position when the second end of the grippable handle is in the unfastened position.
In other words, in an embodiment, the locking unit is configured to move into the locked position only if the second end of the grippable handle is in the fastened position. Conversely, the locking unit is configured to remain in the unlocked position if the second end of the grippable handle is in the unfastened position.
In an embodiment, the locking unit comprises a closing profile.
In an embodiment, the second end of the grippable handle, when it is in the fastened position, is configured to engage the closing profile of the locking unit. In an embodiment, the locking unit, when it is in the locked position, is configured to lock the closing profile to the second end of the grippable handle.
That way, with a single locking unit, the device is able to lock the closing shell in the closed position and to lock the grippable handle with the second end in the fastened position so that no one can carry the device away from the restraining object it is hooked to.
In an embodiment, the device comprises a fastening seal. The fastening seal is interposed between the second end of the hooking element and the second fastening of the container. That way, the fastening seal prevents fluid from infiltrating in the internal space of the containing shell through a gap between the second end of the grippable handle and the second fastening of the container.
In an embodiment, the device comprises a main seal. The main seal, when the closing shell is in the closed position, is interposed between the containing shell and the closing shell of the container. That way, the main seal prevents fluid from infiltrating in the internal space of the containing shell through a gap between the containing shell of the container and the closing shell of the container.
In an embodiment, the device comprises a closing element. The closing element is configured to keep the closing shell (temporarily) in the closed position, although not locked in the closed position. Thus, the closing element is movable between a blocked position, where the closing shell is in the closed position and the locking unit is in the unlocked position, and an unblocked position, where the closing shell is in the open position and the locking unit is in the unlocked position. The presence of the closing element is highly advantageous for this invention because it allows temporarily closing the closing shell while the device is being fixed to the corresponding restraining object, even if the second end of the grippable handle is not yet in the hooked position, thus preventing any objects that have already been placed inside the containing shell from falling out.
In an embodiment, the device comprises a primary accumulator. In an embodiment, the device comprises an auxiliary accumulator. The primary accumulator is configured to power the control unit. The auxiliary accumulator is configured to power an object inside the safekeeping container. In an embodiment, the primary accumulator and the auxiliary accumulator are a single accumulator performing the functions of both the primary accumulator and the auxiliary accumulator.
In an embodiment, the device comprises one or more charging ports. The one or more charging ports are connected to the auxiliary accumulator (or to the single accumulator). The one or more charging ports are connectable to an external object to be electrically recharged, located inside the containing shell of the container.
In an embodiment, the control unit comprises an enabling receiver. The enabling receiver is configured to receive the enabling signal through a wireless connection. In other words, the control unit is configured to receive the enabling signal from a remote terminal through the wireless connection.
In an embodiment, the control unit comprises an access receiver. The access receiver is configured to receive the access data through a wireless connection. In an embodiment, purely by way of example, the access receiver is configured to receive the access data from a specifically configured RFID transmitter possessed by the user.
In an embodiment, the device comprises an electric connector, configured to be connected to an external power charger which recharges its respective accumulators (primary or auxiliary or single accumulator).
According to an aspect of it, this disclosure provides a system for the safekeeping of an object.
In an embodiment, the system comprises a transportable device for the safekeeping of an object according to any of the features described above.
In an embodiment, the system comprises a local terminal. The local terminal is connectable to the device.
The local terminal is configured to send the enabling signal to the device.
In an embodiment, the system comprises a remote terminal. The remote terminal includes a memory. In an embodiment, the local terminal is configured to send tracking signals to the remote terminal. The tracking signals include one or more of the following information items:

an identification code of the transportable device;
time trace, representing an instant in which the local terminal sends the enabling signal to the transportable device (or representing the instant in which the transportable device receives the enabling signal);
an enabling time, representing a time interval in which the container of the transportable device can be moved from the closed position to the open position.

In an embodiment, the remote terminal is configured to store the tracking signals in its memory.
In an embodiment, the transportable device is configured to receive a disabling signal from the remote terminal. In an embodiment, the remote terminal is configured to send the disabling signal. The disabling signal is generated as a function of the enabling time and/or of the time trace. The disabling signal is configured to prevent the generation of the drive signals in response to the access data as a function of the disabling signal.
In an embodiment, the system comprises an access device. The access device is configured to send the access data to an access receiver of the control unit of the transportable device to generate the drive signals.
In an embodiment, the system comprises a charging rack. The charging rack includes one or more charging slots. The charging rack includes a main connector, configured to be connected to an external power supply and to recharge the accumulators of each device. For each charging slot, the charging rack includes a dedicated connector configured to be connected to a respective device for recharging the respective accumulators (primary or auxiliary) or the respective single accumulator.
According to an aspect of it, this disclosure provides a method for the safekeeping of an object in a transportable device.
The method comprises a step of changing the position of a transportable container, including a containing shell having an internal space, and closing shell which is movable relative to the containing shell between an open position, where the internal space of the containing shell is accessible from the outside, and a closed position, where access to the internal space of the containing shell is prevented.
The method comprises a step of moving the locking unit, connected to the container, between an unlocked position, where the closing shell can move between the closed position and the open position, and a locked position, where the closing shell remains in the closed position, by means of an actuator.
The method comprises a step of receiving access data in a control unit. The method comprises a step of generating a drive signal in the control unit, preferably as a function of the access signals.
The method comprises a step of sending the drive signals from the control unit to the actuator. The method comprises a step of hooking the transportable container to a restraining object.
In an embodiment, the method comprises a step of enabling. in which the control unit receives enabling signals. The control unit generates the enabling signals as a function of which it enables the step of generating the drive signals as a function of the access data.
In an embodiment, the method comprises a step of storing. in which the control unit stores the enabling signal in its memory.
In an embodiment, the method comprises a step of timing. In the step of timing, a chronometer in the control unit measures an enabling interval, preferably in real time. The enabling interval represents a time interval, preferably uninterrupted, in which the control unit generates the drive signals in response to the access data. In an embodiment in which the enabling signal includes an enabling time representing a maximum time interval in which the user is enabled to use the device, the method comprises a step of disabling. In the step of disabling, the control unit generates a disabling signal as a function of a comparison between the enabling interval and the enabling time. The control unit generates the disabling signal and, as a function of the disabling signal, prevents the drive signals from being generated in response to the access data.
In an embodiment, in the step of hooking, a first end of the grippable handle is connected to the container at a first fastening of the container.
In an embodiment, the step of hooking comprises a step of inserting, in which a second end of the grippable handle is moved between a fastened position, where it is connected to the container at a second fastening, and a unfastened position, where it is removed from the second fastening.
In an embodiment, the method comprises a step of rotating the grippable handle about an articulated joint.
In an embodiment, when the locking unit is in the locked position, the second end of the grippable handle is in the fastened position. In an embodiment, when the locking unit is in the unlocked position, the second end of the grippable handle is in the unfastened position.
In an embodiment, the locking unit comprises a closing profile.
In an embodiment, the second end of the grippable handle, when it is in the fastened position, engages the closing profile of the locking unit. In an embodiment, the locking unit, when it is in the locked position, locks the closing profile to the second end of the grippable handle.
In an embodiment, the method comprises a step of fastening sealing. In the step of fastening sealing, a fastening seal, interposed between the second end of the fastening element and the second fastening of the container, creates a fluid seal between the second end of the grippable handle and the second fastening of the container to prevent fluid from infiltrating into the internal space of the containing shell.
In an embodiment, the method comprises a step of main fastening. In the step of main sealing, a main seal, interposed between the containing shell and the closing shell of the container, creates a fluid seal between the containing shell and the closing shell of the container to prevent fluid from infiltrating into the internal space of the containing shell.
In an embodiment in which the device comprises a closing element, the method comprises a step of temporary closing in which the closing element keeps the closing shell (temporarily) in the closed position, though not locked in the closed position. In the step of temporary closing, the closing element is movable between a blocked position, where the closing shell is in the closed position and the locking unit is in the unlocked position, and an unblocked position, where the closing shell is in the open position and the locking unit is in the unlocked position.
In an embodiment, the method comprises a step of primary accumulation, in which a primary accumulator provides energy for the locking system. In an embodiment, the method comprises a step of auxiliary accumulation in which an auxiliary accumulator powers an object stored securely in the container.
In an embodiment, the method comprises a step of recharging in which one or more charging ports are connected to the auxiliary accumulator and power an external object to be electrically recharged, located inside the containing shell of the container.
In an embodiment, the method comprises a first step of receiving in which an enabling receiver of the control unit receives the enabling signal through a wireless connection. In an embodiment, the method comprises a second step of receiving in which an access receiver of the control unit receives the access data through a wireless connection.
This and other features will become more apparent from the following description of a preferred embodiment, illustrated by way of non-limiting example in the accompanying drawings, in which:

Figures 1A and 1B are, respectively, a first perspective view and a second perspective view schematically illustrating a device for the safekeeping of objects;
Figures 2A and 2B are, respectively, a first cross section and a second cross section schematically illustrating the device of Figure 1A;
Figures 3A and 3B are, respectively, a first side view and a second side view schematically illustrating the device of Figure 1A;
Figure 4 is a schematic cross section of a further embodiment of the device for the safekeeping of objects;
Figure 5 schematically illustrates a detail of the device of Figure 2A;
Figure 6 schematically illustrates a system for the safekeeping of objects.

With reference to the accompanying drawings, the numeral 1 denotes a transportable device for the safekeeping of objects. The device 1 includes a container 10.
The container 10 includes a top face 10A. The container 10 includes an underside face 10B. The container 10 includes one or more side walls 10C. In an embodiment, the container includes four side walls 10C.
The container 10 comprises a containing shell 101. The container 10 comprises a closing shell 102. The containing shell 101 has an internal space 101' in which the objects for safekeeping are housed.
In an embodiment, the containing shell 101 comprises an internal separator 101 ", configured to divide the internal space 101' into smaller sub-spaces. The closing shell 102 is configured to be coupled to the containing shell 101 and to close it to prevent access to the internal space 101'.
In an embodiment, the closing shell 102 is movable from an open position PA, where it is at least partly spaced from the containing shell 101, to allow access to the internal space 101' of the containing shell 101, to a closed position PC, where it is in contact with the containing shell 101 to prevent access to the internal space 101'.
In an embodiment, the container 10 includes a hinge 103. In an embodiment, the hinge 103 is positioned on a connecting face 10C' of the container 10. The hinge 103 includes a housing and a pin. The pin is inserted in the respective housing to rotate therein. In an embodiment, the pin is connected to the containing shell 101 and the housing is connected to the closing shell 102. In other embodiments, the pin is connected to the closing shell 102 and the housing is connected to the containing shell 101.
In an embodiment, the closing shell 102 is configured to rotate about the hinge 103 relative to the containing shell 101 between the open position PA and the closed position PC.
In an embodiment, the container 10 includes a gripping element 104A. In some embodiments, the gripping element 104A is positioned on the closing shell 102 and, in other embodiments, it is positioned on the containing shell 101. In an embodiment, the container 10 includes a gripping profile 104B. Depending on the embodiment adopted, the gripping profile 104B may be formed on the containing shell 101 or on the closing shell 102.
In an embodiment, the closing shell 102 is configured to be detached completely from the containing shell 101 by removing the gripping element 104A from the respective gripping profile 104B. More specifically, the closing shell 102 is configured to rotate about the gripping element 104B until the gripping element is disengaged from the respective gripping profile 104B, allowing the closing shell 102 to be completely detached from the containing shell 101.
In an embodiment, the device 1 comprises a grippable handle 11. The grippable handle 11 is configured to allow a user to easily carry the device 1.
The grippable handle 11 is configured to allow the device 1 to be secured to an external restraining object to prevent the device 1 from being stolen.
In an embodiment, the grippable handle comprises a cable 11'. In an embodiment, the cable 11' comprises a metal core. In an embodiment, the cable 11' comprises a covering, wrapped around the metal core to make it more comfortable for the user to hold, while maintaining the same standard of security. In an embodiment, the cable 11 extends from a first end 11A to a second end 11B.
In an embodiment, the closing shell 102 comprises a first fastening 102' and a second fastening 102". In some embodiments, the first fastening 102' and/or the second fastening 102" are through holes in the closing shell 102.
In an embodiment, the first end 11A of the cable 11 is inserted in the first fastening 102'. In an embodiment, the first end 11A of the cable 11 is removable from the first fastening.
In an embodiment, the second end 11B of the cable 11 is inserted in the second fastening 102". In an embodiment, the second end 11B of the cable 11 is removable from the second fastening 102". In an embodiment, the second end 11B of the cable 11 is movable between a fastened position P1, where it is inserted in the second fastening 102", and an unfastened position P2, where it is removed from the second fastening 102".
In an embodiment, the device 1 comprises a locking unit 12. The locking unit 12 is connected to the container 10. The locking unit 12 is configured to lock the closing shell 102 in its closed position PC and/or to release the closing shell 102 from its closed position PC.
In an embodiment, the locking unit 12 is movable between an unlocked position PS, where the closing shell 102 can be moved between the closed position PC and the open position PA, and a locked position PB, where the closing shell 102, in the closed position PC, is forced to remain in the closed position PC.
In an embodiment, the locking unit comprises a locking member 121. In an embodiment, the locking member 121 is configured to create mechanical resistance to the movement of the closing shell 102 from the open position PA to the closed position PC. In an embodiment, the locking member 121 is configured to move until it engages a corresponding coupling member which is connected to the closing shell 102. For example, but not necessarily, the locking member 121 might engage a portion of the closing shell 102.
In an embodiment, the locking member 121 is connected to (integral with) the containing shell 101.
In a preferred embodiment, the locking member 121 is configured to move and engage the second end 11B of the cable 11. That way, the second end 11B of the cable 11, which will be connected to the locking member 121, will also connect the locking member 121 (hence the containing shell) to the closing shell 102.
In an embodiment, when the locking unit 12 is in the locked position PB, the locking member 121 is engaged in the second end 11B of the cable 11. In an embodiment, when the locking unit 12 is in the unlocked position PS, the locking member 121 is disengaged from the second end 11B of the cable 11, which is thus free to move between the fastened position P1 and the unfastened position P2.
In an embodiment, the device 1 comprises an actuator 13. The actuator 13 is configured to move the locking unit 12 from the locked position PB to the unlocked position PS. In an embodiment, the actuator 13 is configured to move the locking member 121 between a position where it is engaged (coupled or integral) with the second end 11B of the cable 11 and a position where it is disengaged (uncoupled) from the second end 11B of the cable 11.
The actuator 13 is configured to receive drive signals 131 as a function of which it moves the locking unit between the locked position and the unlocked position.
The device 1 comprises a control unit 14. The control unit 14 is configured to control the actuator 13. The control unit 14 is configured to receive access data 141. The access data represent information which is possessed only by the user of the device 1 and which is used to authenticate the identity of the person wishing to unlock the locking unit 12.
In an embodiment, the control unit 14 is configured to generate the drive signals 131, preferably as a function of the access data 141.
In an embodiment, the device 1 comprises a user interface 14'. The user interface 14' is configured to receive the access data 141 and to transmit them to the control unit 14. In an embodiment, the user interface may comprise one or more of the following features:

a keyboard 14'A for entering access data representing an alphanumeric code;
an access receiver 14'B configured to receive the access data 141 from an external transmitter through a wireless connection;
a keyhole configured to receive a key.

The control unit comprises a memory. In an embodiment, the control unit is configured to store authentication data in the memory.
In an embodiment, the control unit 14 is configured to verify that the access data 141 match the authentication data so as to enable or inhibit the movement of the locking unit 12 from the locked position PB to the unlocked position PS.
In an embodiment, the control unit 14 is configured to receive an enabling signal 142.
In an embodiment, the control unit is configured to store the enabling signal 142 in the memory.
In an embodiment, the control unit 14 is configured to enable generating the drive signals 131 as a function of the enabling signal 142. In other words, in an embodiment, the control unit is configured to perform one or more of the following operations:

receive the access data 141 through the user interface 14';
verify the receiving of the enabling signal 142;
verify that the access data 141 match the authentication data, as a function of the receiving of the enabling signal 142;
inhibit verification of match between the access data 141 and the authentication data, as a function of the receiving of the enabling signal 142.

Thus, the control unit 14 is configured to drive the actuator to move only if it has received the enabling signal 142. In the absence of the enabling signal 142, the closing shell 102 can move freely from the open position PA to the closed position without being able to be locked in the closed position PC.
In an embodiment, the control unit is configured to receive a disabling signal 143.
In an embodiment, the control unit is configured to store the disabling signal 143 in the memory.
In an embodiment, the control unit 14 is configured to inhibit generating the drive signals 131 as a function of the disabling signal 143. In other words, in an embodiment, the control unit is configured to verify the receiving of the disabling signal 143 and, as a function of the receiving of the disabling signal 143, to verify that the access data 141 match the authentication data.
Thus, in an embodiment, the control unit 14 may have in its memory an enabling parameter whose value is variable as a function of the enabling signal 142 and/or of the disabling signal 143. More specifically, the control unit 14 is configured to set the enabling parameter at a first value, responsive to receiving the enabling signal 142. The control unit 14 is configured to set the enabling parameter at a second value, responsive to receiving the disabling signal 143. Thus, the control unit 14 is configured to enable or inhibit verification of the match between the access data 141 and the authentication data (that is generation of the drive signals 131 as a function of the access data) as a function of the enabling parameter.
In an embodiment, the control unit 14 includes a chronometer 144. The chronometer 144 is configured to measure an enabling interval. The enabling interval represents the time that elapses after receiving the enabling signal 142 in the control unit. In short, the enabling interval indicates how long the device 1 has been enabled to be used by a certain user.
In an embodiment, the enabling signal 142 comprises an enabling time. The enabling time represents a maximum enabling interval within which the user is enabled to use the device 1. In other words, the enabling time is the maximum time in which a user can be enabled to use the device 1.
In an embodiment, the control unit therefore has in its memory a time parameter, representing a maximum enabling interval within which the user is enabled to use the device 1. The control unit 14 is configured to set the time parameter at a value equal to the enabling time received through the enabling signal 142.
In an embodiment, the control unit 14 is configured to receive the enabling interval from the chronometer 144. The control unit 14 is configured to compare the enabling interval with the enabling time to verify whether the time interval is greater or less than the enabling time. The control unit 14 is configured to generate the disabling signal 143 as a function of the enabling interval and of the enabling time (that is, as a function of the comparison between the enabling interval and the enabling time).
In an embodiment, the device 1 comprises a closing element 15. In an embodiment, the closing element 15 is connected to the closing shell 102 but, in other embodiments, it may be connected to the containing shell 101. The closing element 15 is configured to close the container, preferably temporarily, without having to put the locking unit 12 in the locked position PB. The closing element 15 is configured to fasten the containing shell 101 to the closing shell 102 to prevent the containing shell 101 and the closing shell 102 from moving relative to each other while the device 1 is being fixed to the restraining object. This prevents objects from falling out of the internal space 101' without having to operate on the locking unit 12.
In an embodiment, the closing element 15 is movable between a blocked position P3, where the closing shell 102 is in the closed position PC and the locking unit 12 is in the unlocked position PS, and an unblocked position P4, where the closing shell 102 is in the open position PA and the locking unit 12 is in the unlocked position PS.
In a purely exemplary embodiment, the closing element 15 comprises a hinge 151. The closing element 15 comprises a hook 152. The closing element 15 comprises a thrust wall 153. In an embodiment, the thrust wall 153 includes a slot 153'.
In an embodiment, the thrust wall 153 and the hook 152 are linked to form a rigid body that rotates about the hinge 151.
In an embodiment, the hook 152 is configured to engage a respective housing in the containing shell 101. In an embodiment, with the hook 152 engaged in the respective housing, the thrust wall 153 is configured to rotate about the hinge 151 until it is coplanar with the top face 10A of the container 10.
The rotation of the thrust wall 153 in a closing direction causes a corresponding rotation of the hook 152 which, when engaged in the respective housing, applies a compressive force on the closing shell 102, thus keeping the closing shell in the closed position PC. Clearly, rotating the thrust wall 153 in a direction opposite to the closing direction relaxes the compressive force and causes the closing shell to move to the open position PA.
In an embodiment, when the closing element 15 is in the blocked position P3, the thrust wall 153 is coplanar with the top face 10A and the hook 152 is engaged in the respective housing.
In an embodiment, the second end 11B of the cable 11 is configured to be inserted in the slot 153' of the thrust wall 153 and then in the second fastening 102" of the closing shell 102.
That way, when the locking unit 12 is in the locked position PB, the second end 11B of the cable 11 is locked in the fastened position, the closing shell 102 is locked in the closed position PC and the closing element 15 is locked in the blocked position P3.
In an embodiment, the device 1 comprises a primary accumulator 16A and/or an auxiliary accumulator 16B.
In an embodiment, the device 1 comprises a single accumulator which combines the functions of both accumulators (primary and auxiliary).
In an embodiment, the primary accumulator is connected to the control unit 14 to power it.
In an embodiment, the auxiliary accumulator 16B is configured to power (that is, to recharge) objects placed in safekeeping.
In an embodiment, the device 1 comprises one or more charging ports 17. The charging ports 17 may be, for example, USB ports, lighting jacks, sound jacks, power sockets.
The one or more charging ports 17 are connected to the auxiliary accumulator 16B. The one or more charging ports 17 are connected to the objects placed in safekeeping to transmit to them the power received from the auxiliary accumulator 16B.
In an embodiment, the primary accumulator 16A and/or the auxiliary accumulator 16B are mounted in the internal space 101' of the containing shell 101, in a zone which is in contact with a side wall 10C opposite to the connecting wall 10C' which the hinge 103 is mounted on.
Thus, when the closing shell 102 rotates relative to the containing shell 101, the weight of the accumulators 16A and 16B balances the weight of the closing shell 102 which is separated from the containing shell 101.
In an embodiment, the device 1 (the control unit 14) comprises an enabling receiver (which might also be the access receiver 14'B) which is configured to receive the enabling signal 142 and/or the disabling signal 143.
In an embodiment, the device 1 comprises a main seal 18A. The main seal 18A is configured to create a fluid seal between the closing shell 102 and the containing shell 101.
In an embodiment, the main seal may be made of deformable plastic material or other materials known in the field of hydraulic seals.
In an embodiment, the main seal 18A, when the closing shell 102 is in the closed position PC, is interposed between the closing shell 102 and the containing shell 101.
In an embodiment, the device 1 comprises a fastening seal 18B. The fastening seal 18B is configured to create a fluid seal between the second end 11B of the cable 11 and the second fastening 102" of the closing shell 102.
In an embodiment, the fastening seal 18B may be made of deformable plastic material or other materials known in the field of hydraulic seals.
In an embodiment, when the second end 11B of the cable 11 is in the fastened position P1, the fastening seal 18B is interposed between the second end 11B of the cable 11 and the second fastening 102" of the closing shell 102.
In an embodiment, the device 1 comprises one or more solar panels configured to convert sunlight into electrical energy. In an embodiment, the one or more solar panels are disposed on one of the faces 10A, 10B or 10C of the container 10.
In an embodiment, the one or more solar panels are connected to the primary accumulator 16A and/or to the auxiliary accumulator 16B to recharge them.
In an embodiment, the device 1 comprises a charging socket 19. The charging socket 19 is configured to be connected to a plug to receive electrical power from an external source. The charging socket is connected to the primary accumulator 16A and/or to the auxiliary accumulator 16B to transmit the power received from the external source. In an embodiment, the charging socket 19 is located on the underside face 10B of the container 10.
According to an aspect of it, this disclosure provides a system 100 for the safekeeping of objects.
The system 100 comprises one or more devices 1 according to any one of the features set out in this disclosure.
In an embodiment, the system 100 comprises a local terminal 1001. The local terminal 1001 may be a personal computer of a person responsible for controlling the devices 1.
The local terminal 1001 is connected (or connectable) to one or more of the devices 1. In an embodiment, the local terminal 1001 includes a configuration cable connectable to a device 1.
The device 1 comprises a configuration port. The local terminal 1001 is connected to the configuration port of a device 1 through the configuration cable.
In an embodiment, the local terminal 1001 is configured to send the enabling signal 142 to the device 1, preferably through the configuration cable but, alternatively, also through a wireless connection (using the enabling receiver). In an embodiment, the local terminal 1001 is configured to send the disabling signal 143 to the device 1, preferably through the configuration cable but, alternatively, also through a wireless connection (using the enabling receiver).
In an embodiment, the system 100 comprises a remote terminal 1002. The remote terminal 1002 comprises a database 1003. The database 1003 may be located at the same position as the remote terminal 1003 or it may be a "cloud" database which can be accessed through the Internet.
In an embodiment, the local terminal 1001 is connected to the remote terminal 1002 through a wireless connection.
In an embodiment, the local terminal 1001 is configured to send a tracking signal 1012 when the enabling signal 142 is sent to a specific device 1. In this embodiment, the tracking signal 1012 may contain a unique identifier of the device 1 (for example, a product serial number) and/or an enabling time indicating the maximum time within which the specific device 1 can be used by a specific user and/or an enabling instant, representing the instant in which the enabling signal was sent to the device 1 and/or user data, including specific information relating to the user of the specific device.
The remote terminal 1002 is configured to store the tracking signal 1012 in the database 1003.
In an embodiment, the remote terminal 1002 is connected to the devices 1 through a wireless connection.
In an embodiment, the devices 1 are configured to receive the enabling signal 142 and/or the disabling signal 143 from the remote terminal 1002.
In an embodiment, the system 100 comprises an access device 1004 for each device 1. The access device 1004 is configured to send the access data 141 to the respective device 1 (to the respective user interface 14' of the control unit 14 of the device 1).
In an embodiment, the local terminal 1001 and/or the remote terminal 1002 are configured to send configuration data 1014 to each access device 1004. The access device 1004 is configured to generate the access data as a function of the configuration data 1014.
In an embodiment, the local terminal 1001 and/or the remote terminal 1002 are configured to send authentication data to each device 1. In an embodiment, the control unit is configured to verify the match between the authentication data received from the device 1 and the access data 141 generated by the access device 1004, as a function of the configuration data 1014.
In an embodiment, the access device 1004 may be a rubber wristband including an RFID transmitter, or a remote control which transmits the access data by means of radio waves.
In an embodiment, the access device 1004 is not supplied with the device 1 and, instead, a code is provided which must be entered in the user interface 14' of the device 1 to unlock the locking unit 12.
In an embodiment, the system 100 comprises a rack 1005. The rack 1005 is configured to house one or more transportable devices 1. The rack 1005 comprises a plurality of charging slots. Each charging slot comprises a power plug, configured to be connected to the charging socket 19 of the respective device 1.
In an embodiment, the rack 1005 comprises an electrical connecting cable, configured to transmit electrical power to the rack 1005. In an embodiment, the rack 1005 comprises an electronic connecting cable connected to the local terminal 1001. The electronic connecting cable is configured to transmit to the rack 1005 an enabling signal 142 (and, when necessary this is applicable also to the disabling signal 143) and a specific identifier of the device 1 to which the enabling signal is directed. In an embodiment, the rack 1005 is configured to send the enabling signal 142 received from the local terminal 1001 to the specific device 1 for which the signal was generated.
According to an aspect of it, this disclosure also intends providing a method for the safekeeping of objects in a transportable device 1 according to one or more of the features described above.
The method comprises a step of coupling, in which a containing shell 101 and a closing shell 102 of the device 1 are coupled to each other to close and prevent access to an internal space 101' of the containing shell 101.
The method comprises a step of moving the closing shell 102 between an open position PA, where it is at least partly spaced from the containing shell 101, to allow access to the internal space 101' of the containing shell 101, and a closed position PC, where it is in contact with the containing shell 101 to prevent access to the internal space 101'.
In an embodiment, the step of moving the closing shell 102 comprises a step of rotating the closing shell 102 relative to the containing shell 101 about a hinge 103.
In an embodiment, in which the container 10 includes a gripping element 104A, positioned on the closing shell 102 (or on the containing shell 101) and in which the container 10 includes a respective gripping profile 104B formed on the containing shell 101 (or on the closing shell 102), the method comprises a step of totally detaching the closing shell 102 from the containing shell 101, by removing the gripping element 104A from the respective gripping profile 104B. More specifically, the closing shell 102 rotates about the gripping element 104B until the gripping element is disengaged from the respective gripping profile 104B, allowing the closing shell 102 to be completely detached from the containing shell 101.
In an embodiment, the method comprises a step of transporting in which the device 1 is moved from one site to another by means of a grippable handle 11.
In an embodiment, the method comprises a step of hooking in which the grippable handle 11 is hooked to an external restraining object to prevent the device 1 from being stolen.
In an embodiment, the grippable handle 11 extends from a first end 11A to a second end 11B and the closing shell 102 comprises a first fastening 102' and a second fastening 102".
In an embodiment, the method comprises a step of inserting, in which the first end 11A of the grippable handle 11 is inserted into the first fastening 102' and/or the second end 11B of the cable 11 is inserted into the second fastening 102".
In an embodiment, the method comprises a step of removing, in which the first end 11A of the grippable handle 11 is removed from the first fastening 102' and/or the second end 11B of the cable 11 is removed from the second fastening 102".
In an embodiment, the method comprises a step of moving the second end 11B of the cable 11 between a fastened position P1, where it is inserted in the second fastening 102", and an unfastened position P2, where it is removed from the second fastening 102".
The method comprises a step of locking, in which a locking unit 12 locks the closing shell 102 in its closed position PC and/or releases the closing shell 102 from its closed position PC.
In an embodiment, the method comprises a step of moving the locking unit 12 between an unlocked position PS, where the closing shell 102 can be moved between the closed position PC and the open position PA, and a locked position PB, where the closing shell 102, in the closed position PC, is forced to remain in the closed position PC.
In the step of locking, a locking member 121 of the locking unit creates mechanical resistance to the movement of the closing shell 102 from the open position PA to the closed position PC. In the step of locking, the locking member 121 is moved until it engages a corresponding coupling member which is connected to the closing shell 102. For example, but not necessarily, the locking member 121 is inserted into (engages) a portion of the closing shell 102.
In a preferred embodiment, the locking member 121 is moved and engages the second end 11B of the cable 11. That way, the second end 11B of the cable 11, which will be connected to the locking member 121, will also connect the locking member 121 (hence the containing shell) to the closing shell 102.
Thus, when the locking unit 12 is in the locked position PB, the locking member 121 is engaged in the second end 11B of the cable 11. In an embodiment, when the locking unit 12 is in the unlocked position PS, the locking member 121 is disengaged from the second end 11B of the cable 11, which is thus free to move between the fastened position P1 and the unfastened position P2.
In an embodiment, the method comprises a step of actuating, in which an actuator 13 moves the locking unit 12 from the locked position PB to the unlocked position PS.
In the step of actuating, the actuator 13 moves the locking member 121 between a position where it is engaged (coupled or integral) with the second end 11B of the cable 11 and a position where it is disengaged (uncoupled) from the second end 11B of the cable 11.
In the step of actuating, the actuator 13 receives drive signals 131 as a function of which it moves the locking unit between the locked position and the unlocked position.
The method comprises a step of controlling, in which a control unit 14 controls the actuator 13. The control unit 14 receives access data 141, representing information which is possessed only by the user of the device 1 and which is used to authenticate the identity of the person wishing to unlock the locking unit 12.
In an embodiment, the control unit 14 generates the drive signals 131, preferably as a function of the access data 141.
In an embodiment, in the step of controlling, a user interface 14 receives the access data 141 and transmits them to the control unit 14. In an embodiment, the user interface receives the access data with an access receiver 14'B though a wireless connection.
The control unit stores authentication data in a memory.
In an embodiment, the control unit 14 verifies that the access data 141 match the authentication data so as to enable or inhibit the movement of the locking unit 12 from the locked position PB to the unlocked position PS.
In an embodiment, the control unit 14 receives an enabling signal 142.
In an embodiment, the control unit stores the enabling signal 142 in the memory.
In an embodiment, the control unit 14 enables generating the drive signals 131 as a function of the enabling signal 142. In other words, in an embodiment, the control unit carries out one or more of the following steps:

receiving the access data 141 through the user interface 14';
verifying the receiving of the enabling signal 142;
verifying the match between the access data 141 and the authentication data, as a function of the receiving of the enabling signal 142;
inhibiting verification of the match between the access data 141 and the authentication data, as a function of the receiving of the enabling signal 142.

Thus, the control unit 14 drives the actuator to move only if it has received the enabling signal 142. In the absence of the enabling signal 142, the closing shell 102 can move freely from the open position PA to the closed position without being in any way able to be locked in the closed position PC.
In an embodiment, the control unit receives a disabling signal 143.
The control unit stores the disabling signal 143 in the memory.
In an embodiment, the control unit 14 inhibits generating the drive signals 131 as a function of the disabling signal 143. In other words, in an embodiment, the control unit verifies the receiving of the disabling signal 143 and, only in the absence of the disabling signal 143, verifies that the access data 141 match the authentication data.
Thus, in an embodiment, the control unit 14 has in its memory an enabling parameter which varies as a function of the enabling signal 142 and/or of the disabling signal 143. More specifically, the control unit 14 sets the enabling parameter at a first value, responsive to receiving the enabling signal 142. The control unit 14 sets the enabling parameter at a second value, responsive to receiving the disabling signal 143. Thus, the control unit 14 enables or inhibits verification of the match between the access data 141 and the authentication data (that is generation of the drive signals 131 as a function of the access data) as a function of the enabling parameter.
In an embodiment, the control unit 14 includes a chronometer 144. The chronometer 144 measures an enabling interval representing the time that elapses after receiving the enabling signal 142 in the control unit 14.
In an embodiment, the enabling signal 142 comprises an enabling time. The enabling time represents a maximum enabling interval within which the user is enabled to use the device 1.
In an embodiment, the control unit therefore has in its memory a time parameter, representing a maximum enabling interval within which the user is enabled to use the device 1. The control unit 14 sets the time parameter at a value equal to the enabling time received through the enabling signal 142.
In an embodiment, the method comprises a step of disabling.
In the step of disabling, in an embodiment, the control unit 14 receives the enabling interval from the chronometer 144. The control unit 14 compares the enabling interval with the enabling time to verify whether the time interval is greater or less than the enabling time. The control unit 14 generates the disabling signal 143 as a function of the enabling interval and of the enabling time (that is, as a function of the comparison between the enabling interval and the enabling time).
In an embodiment, the method comprises a step of temporarily closing, in which a closing element 15, connected to the closing shell 102 or connected to the containing shell 101 closes the container, preferably temporarily, without having to put the locking unit 12 in the locked position PB. The closing element 15 fastens the containing shell 101 to the closing shell 102 to prevent the containing shell 101 and the closing shell 102 from moving relative to each other while the device 1 is being fixed to the restraining object. This prevents objects from falling out of the internal space 101' without having to operate on the locking unit 12.
In an embodiment, the method comprises a step of moving the closing element 15 between a blocked position P3, where the closing shell 102 is in the closed position PC and the locking unit 12 is in the unlocked position PS, and an unblocked position P4, where the closing shell 102 is in the open position PA and the locking unit 12 is in the unlocked position PS.
In an embodiment, a hook 152 of the closing element 15 is inserted into (coupled to) a respective housing of the containing shell 101.
In an embodiment, the method includes a step of compressing, in which the closing shell 102 is compressed onto the containing shell 101 by means of the closing element 15.
In an embodiment, the second end 11B of the grippable handle 11 is inserted into a slot 153' of the closing element 15 and then into the second fastening 102" of the closing shell 102.
That way, when the locking unit 12 is in the locked position PB, the second end 11B of the cable 11 is locked in the fastened position, the closing shell 102 is locked in the closed position PC and the closing element 15 is locked in the blocked position P3.
In an embodiment, the method comprises a step of powering, in which an accumulator powers loads associated with the device 1 (the control unit or objects to be placed in safekeeping) with electrical energy. The step of powering comprises a step of primary powering and/or a step of auxiliary powering.
In the step of primary powering, a primary accumulator 16A powers the control unit 14.
In the step of auxiliary powering, an auxiliary accumulator 16B powers (that is, recharges), if necessary, objects placed in safekeeping.
In an embodiment, the method comprises a step of recharging, in which the objects placed in safekeeping are recharged through one or more charging ports 17.
In an embodiment, the method comprises a step of sealing, in which the containing shell applies a fluid seal to prevent infiltration of fluid into the internal space of the containing shell 101. In an embodiment, the step of sealing comprises a step of main sealing in which a main seal 18A creates a fluid seal between the closing shell 102 and the containing shell 101.
In an embodiment, the step of sealing comprises a step of sealed fastening, in which a fastening seal 18B creates a fluid seal between the second end 11B of the cable 11 and the second fastening 102" of the closing shell 102.
In an embodiment, the method comprises a step of generating energy, in which one or more solar panels convert sunlight into electrical energy.
In an embodiment, the method comprises a step of recharging the device 1, in which a charging socket 19, connected to a plug to receive electrical power from an external source and connected to the primary accumulator 16A (and/or to the auxiliary accumulator 16B) transmits the power received from the external source to the accumulators of the device 1.
In an embodiment, the method comprises a step of configuring. In the step of configuring, a local terminal 1001, connected (or connectable) to a device 1, sends the enabling signal 142 to the device 1, preferably through the configuration cable but, alternatively, also through a wireless connection (using the enabling receiver).
In an embodiment, the local terminal 1001 sends the disabling signal 143 to the device 1, preferably through the configuration cable but, alternatively, also through a wireless connection (using the enabling receiver).
In an embodiment, in the step of configuring, a remote terminal 1002, connected (or connectable) to the device 1 through a wireless connection, sends the enabling signal 142 and/or the disabling signal 143 to the device 1.
In an embodiment, the method comprises a step of tracking. In the step of tracking, the local terminal 1001 sends a tracking signal 1012 at the same time as or when the enabling signal 142 is sent to a specific device 1.
The remote terminal 1002 stores the tracking signal 1012 in a database 1003.
In an embodiment, the devices 1 receive the enabling signal 142 and/or the disabling signal 143 from the remote terminal 1002.
In an embodiment, the method comprises a step of accessing, in which an access device 1004 for each device 1 sends the access data 141 to the respective device 1 (to the respective user interface 14' of the control unit 14 of the device 1).
In an embodiment, in the step of configuring, the local terminal 1001 and/or the remote terminal 1002 send configuration data 1014 to each access device 1004. The access device 1004 generates the access data as a function of the configuration data 1014.
In an embodiment, in the step of configuring, the local terminal 1001 and/or the remote terminal 1002 send authentication data to each device 1. In an embodiment, the control unit verifies the match between the authentication data received from the device 1 and the access data 141 generated by the access device 1004, as a function of the configuration data 1014.
In an embodiment, the method comprises a step of housing the devices 1, in which a rack 1005 houses (keeps) one or more transportable devices 1 in respective charging slots. In the step of housing, a power plug at each charging slot is connected to the charging socket 19 of the respective device 1 in order to recharge it.
In an embodiment, in the step of configuring, the remote terminal 1002 and/or the local terminal 1001 send to the rack 1005 the enabling signal 142 (and, when necessary, also the disabling signal 143) and a specific identifier of the device 1 to which the enabling signal (or the disabling signal) is directed. The rack 1005 sends the enabling signal 142 received from the local terminal 1001 to the specific device 1 for which the signal was generated.

Claims

A transportable device (1) for the safekeeping of objects, comprising:
- a transportable container (10), including a containing shell (101) which affords an internal space (101') and a closing shell (102) which is movable relative to the containing shell (101) between an open position (PA), where the internal space (101') of the containing shell (101) is accessible from the outside, and a closed position (PC), where access to the internal space (101') of the containing shell (101) is inhibited;

- a locking unit (12) connected to the container (10) and movable between an unlocked position (PS), where the closing shell (102) can be moved between the closed position (PC) and the open position (PA), and a locked position (PB), where the closing shell (102), in the closed position (PC), is forced to remain in the closed position (PC);

- an actuator (13), configured to receive drive signals (131) and connected to the locking unit (12) to move it between the locked position (PB) and the unlocked position (PS);

- a control unit (14) configured to receive access data (141) and to generate the drive signals (131);

- a grippable handle (11) connected to the container (10) and configured to be connected to an external restraining object,
characterized in that the control unit (14) is configured to receive an enabling signal (142) and, as a function of the enabling signal (142), to enable the generation of the drive signals (131) in response to the access data (141).
The device (1) according to claim 1, comprising:
- a memory, configured to store the enabling signal (142);

- a chronometer (144), configured to measure in real time an enabling interval representing an uninterrupted time interval in which the control unit (14) is enabled to generate the drive signals (131) in response to the access data (141),
wherein the enabling signal (142) includes an enabling time and wherein the control unit (14) is configured to generate disabling signals (143) as a result of comparing the enabling interval with the enabling time and, as a function of the disabling signal (143), to inhibit the generation of the drive signals (131) in response to the access data (141).
The device (1) according to claim 1 or 2, wherein the grippable handle (11) comprises a first end (11A) which is connected to the container (10) at a first fastening (102'), and a second end (11B) which is movable between a fastened position (P1), where it is connected to the container (10) at a second fastening (102"), and an unfastened position (P2), where it is detached from the second fastening (102").
The device (1) according to claim 3, wherein the locking unit (12) is in the locked position (PB) when the second end (11B) of the grippable handle (11) is in the fastened position (P1) and wherein the locking unit (12) is in the unlocked position (PS) when the second end (11B) of the grippable handle (11) is in the unfastened position (P2).
The device (1) according to claim 3 or 4, comprising a fastening seal (18A), interposed between the second end (11B) of the grippable handle (11) and the second fastening (102") of the container (10) to prevent the infiltration of fluid into the internal space (101') of the containing shell (101).
The device (1) according to any one of the preceding claims, comprising a main seal (18B), which, in the closed position (PC), is interposed between the containing shell (101) and the closing shell (102) of the container (10) when the closing shell 102) is in the closed position (PC), to prevent the infiltration of fluid into the internal space (101') of the containing shell (101).
The device (1) according to any one of the preceding claims, comprising a closing element (15) which is movable between a blocked position (P3), where the closing shell (102) is in the closed position (PC) and the locking unit (12) is in the unlocked position (PS), and an unblocked position (P4), where the closing shell (102) is in the open position (PA) and the locking unit (12) is in the unlocked position (PS).
The device (1) according to any one of the preceding claims, comprising a primary accumulator (16A), configured to power the control unit (14), and an auxiliary accumulator (16B), configured to power an object to be kept safe in the container (10).
The device (1) according to claim 8, comprising one or more charging ports (17) connected to the auxiliary accumulator (16B) and connectable to an external object to be electrically recharged.
The device according to any one of the preceding claims, wherein the control unit (14) comprises an access receiver (14'B) configured to receive the access data (141) through a wireless connection.
A system (100) for the safekeeping of an object, comprising:
- a transportable device (1) for the safekeeping of objects, according to any one of the preceding claims;

- a local terminal (1001) responsible for communicating data to the device (1),
characterized in that the local terminal (1001) is configured to send the enabling signal (142) to the device (1).
The system (100) according to claim 11, comprising a remote terminal (1002) and a database (1003) and wherein the local terminal (1001) is configured to send to the remote terminal (1002) tracking signals (1012) including one or more of the following information items:
- an identification code of the transportable device (1);

- time trace, representing an instant in which the local terminal (1001) sends the enabling signal (142) to the transportable device (1);

- an enabling time, representing a time interval in which the closing shell (102) of the transportable device (1) can be moved from the closed position (PC) to the open position (PA),
and wherein the remote terminal (1002) is configured to store the tracking signals (1012) in the database (1003).
The system (10) according to claim 12, wherein the transportable device (1) is configured to receive disabling signals (143) from the remote terminal (1002) as a function of the enabling time and of the time trace and, as a function of the disabling signal (143), to inhibit the generation of the drive signals (131) in response to the access data (141).
The system (10) according to any one of claims 11 to 13, comprising an access device (1004), configured to send the access data (141) to an access receiver (14'B) of the control unit (14) of the transportable device (1) to generate the drive signals (131).
A method for the safekeeping of an object in a transportable device (1) provided with a container (10) having a containing shell (101) and a closing shell (102), comprising the following steps:
- moving the containing shell (101) and the closing shell (102) relative to each other between an open position (PA), where the internal space (101') of the containing shell (101) is accessible from the outside, and a closed position (PC), where access to the internal space (101') of the containing shell (101) is inhibited;

- moving a locking unit (12) by means of an actuator (103) between an unlocked position (PS), where the closing shell (102) can move between the closed position (PC) and the open position (PA), and a locked position (PB), where the closing shell (102), in the closed position (PC), is constrained to remain in the closed position (PC);

- receiving access data (141) in a control unit (14) included in the device;

- generating drive signals (131) in the control unit (14) as a function of the access signals (141) and sending the drive signals (131) from the control unit (14) to the actuator (13);

- hooking the transportable device (1) to a restraining object by means of a grippable handle (11),
characterized in that the method comprises a step of enabling in which the control unit (14) receives an enabling signal (142), as a function of which it enables or disables the step of generating the drive signals (131) as a function of the access data (141).