FR3130263A1 - Aerial platform for working at elevation - Google Patents

Abstract

Elevating platform (1) comprising: - a basket (2) comprising a cockpit (3) and a floor (4) surmounted by a location (5) for receiving an operator, - a self-propelled chassis (6), - an arm (91) for driving the basket (2) movable between two extreme low and high positions, - a device (8) for determining the angular position of the arm (91), and- said nacelle (1) having a operating mode in work configuration and an operating mode in transport configuration, selectively activatable, and the control unit (10) being configured to control the activation of the operating mode in transport configuration when the arm (91) is in position extreme low. The operating modes are each defined by a maximum speed of movement of the chassis (6). The nacelle (1) comprises a device (11) for damping the oscillating movements of the floor (4) of the basket (2) arranged between the location (5) for receiving an operator of the basket (2) and the upper end of the arm (91), this damping device (11) being activatable/deactivatable according to the data provided by the device (8) for determining the angular position of the arm (91). Figure for abstract: Fig. 1B

Description

Aerial platform for working at elevation

The present invention relates to a lifting platform for the work in elevation of person.

It relates in particular to a lifting platform for the work in elevation of person comprising:
- a basket comprising a cockpit and a floor surmounted at least partially by a reception area for an operator,
- a self-propelled chassis,
- a drive arm in movement of the basket, one of the ends of which, called the lower end, is pivotally connected to the frame for an angular movement of the arm between an extreme low position close to the ground and an extreme high position away from the ground and of which the opposite end, called the upper end, is coupled directly or by an articulated connection, to the basket,
- a device for determining a parameter representative of the angular position of the arm, and
- a control unit configured to acquire data from the device for determining a parameter representative of the angular position of the arm,
- said nacelle having at least two selectively activatable operating modes, an operating mode, said in transport configuration, in which the arm is in the extreme low position and an operating mode, said in working configuration, activated when the arm occupies a position other than the extreme low position, and the control unit being configured to control the activation of one or other of the operating modes of the nacelle at least as a function of the data provided by the device for determining a parameter representative of the angular position of the arm.

Aerial platforms are well known to those versed in this art as illustrated for example by patent application WO2019/158869. The manufacturers of such platforms are constantly looking for an improvement in the comfort of the operator located in the basket without compromising the safety of said operator or the quality of the work carried out.

An object of the invention is therefore to provide a lifting platform whose design allows increased comfort for the driver of the platform without impairing the quality of the work that can be carried out from the platform.

To this end, the subject of the invention is a lifting nacelle for working in elevation of a person, said nacelle comprising:
- a basket comprising a cockpit and a floor surmounted at least partially by a reception area for an operator,
- a self-propelled chassis,
- a drive arm in movement of the basket, one of the ends of which, called the lower end, is pivotally connected to the frame for an angular movement of the arm between an extreme low position close to the ground and an extreme high position away from the ground and of which the opposite end, called the upper end, is coupled directly or by an articulated connection, to the basket,
- a device for determining a parameter representative of the angular position of the arm, and
- a control unit configured to acquire data from the device for determining a parameter representative of the angular position of the arm,
- said nacelle having at least two selectively activatable operating modes, an operating mode, said in transport configuration, in which the arm is in the extreme low position and an operating mode, said in working configuration, activated when the arm occupies a position other than the extreme low position, and the control unit being configured to control activation of one or other of the operating modes of the nacelle at least as a function of the data supplied by the device for determining a parameter representative of the angular position of the arm, characterized in that the operating modes in working configuration and in transport configuration are each defined at least by a maximum speed of movement of the self-propelled chassis, in that the maximum speed of movement of the self-propelled chassis in the operating mode in the work configuration is lower than the maximum speed of movement of the self-propelled chassis in the operating mode in the transport configuration, in that the nacelle comprises at least one device for damping oscillation movements up and down lowering of the floor of the basket, in that this damping device is an activatable/deactivatable device placed between the reception location of an operator of the basket and the upper end of the arm and in that the control unit is configured to control the activation or deactivation of the damping device at least as a function of the data supplied by the device for determining a parameter representative of the angular position of the arm.

Said nacelle therefore has two operating modes depending at least on the angular position of the arm within the angular range defined by the extreme high and low positions of the arm, namely an operating mode in transport configuration automatically activated when the arm is in the extreme low position, and in which the maximum speed of movement of the frame is greater than the maximum speed of the frame in operating mode in working configuration and an operating mode in working configuration automatically activated when the arm occupies a position other than the extreme low position and in which the maximum speed of movement of the chassis is lower than the maximum speed of the chassis in operating mode in transport configuration. This design makes it possible to avoid a movement on the ground at high speed of the frame in the operating mode in working configuration in which the arm occupies a position other than the extreme low position. In work configuration, the arm is potentially in a raised position. These two operating modes can be selectively activated, i.e. when one of the operating modes is active, the other operating mode is inactive and vice versa. The damping device can be activated or deactivated depending on the operating mode activated. Generally, the damping device is activated, that is to say in the active state, in the operating mode in transport configuration and can be deactivated when switching from the operating mode in transport configuration to the operating mode in work configuration. . The damping device can thus be in the inactive state in the operating mode in working configuration. Thanks to the fact that the damping device is activated in the mode of operation in transport configuration, it is possible for the operator who has taken his place in the basket to have driving comfort during the driving phases which essentially take place in the mode of operation in transport configuration. This damping device makes it possible to dampen, directly or indirectly, up-and-down oscillating movements of the basket observed in particular when the chassis is rolling at high speed on uneven ground. The deactivation of the damping device when switching from the operating mode in transport configuration to the operating mode in work configuration, allows the operator, in the operating mode in work configuration, not to be disturbed by a possibility of movement from the floor of the basket which could alter the precision of the operator's gestures.

According to one embodiment of the invention, the damping device is in the active state in the mode of operation in transport configuration of the nacelle and the control unit is configured to control the deactivation of the damping device at the activated state of the working mode operating mode of the platform. In other words, the damping device is in the active state in the operating mode in transport configuration of the nacelle and the control unit is configured to control the deactivation of the damping device, when the arm is angularly separated from the extreme low position. The control unit is therefore configured to control the transition from the active state to the inactive state of the damping device, depending on the angular position occupied by the arm between the extreme low and high positions. The passage of the nacelle from the operating mode in transport configuration to the operating mode in work configuration is accompanied by a deactivation of the damping device and the passage of the nacelle from the operating mode in work configuration to the operating mode in configuration transport is accompanied by an activation of the damping device.

According to one embodiment of the invention, the or at least one of the damping devices comprises at least one hydraulic jack, the or at least one of the jacks comprising a body and a piston, the body and the piston being movable relative to each other, said piston separating said body into two chambers.

According to one embodiment of the invention, the two chambers are interconnected by a fluid circuit equipped with a shutter member mounted to move between an open position corresponding to the active state of the damping device and a closed position. , corresponding to the inactive state of the damping device, in which any transfer of fluid between said chambers is prevented, each chamber housing at least one elastically deformable member for biasing the piston towards the other chamber . In practice, the body and the piston of the cylinder can be arranged on the motion transmission chain between the upper end of the arm and the location for receiving an operator from the basket and can be interposed between two separate parts of the nacelle mounted movable relative to one another, the movement of fluid between said chambers of the cylinder allowing this relative movement of said parts to be damped together.

According to one embodiment of the invention, the basket comprises a bottom and side walls surrounding said bottom, the floor extends above said bottom and the or at least one of the damping devices which is a device activatable/deactivatable disposed between the basket operator receiving location and the upper end of the arm extends between the floor and the bottom of the basket, the floor and the bottom being mounted movable in the direction of approximation or a separation from each other in the active state of the damping device. This arrangement makes it possible to dampen the oscillating movements of the floor as close as possible to the floor, in particular when the chassis is moving on uneven ground at high speed, so that the comfort of the operator in the platform is increased.

According to one embodiment of the invention, the body of the jack of the damping device is coupled to the bottom of the basket and the piston of said jack is coupled to the floor or vice versa and the piston and the body are mounted so as to move relative to each other. to the other in the driven state in relative movement of the floor and the bottom in the direction of a rapprochement or a separation from one another in the active state of the damping device. In the inactive state of the damping device, any relative movement of the floor and the bottom in the direction of a rapprochement or a separation from each other is prevented. In other words, the floor and the bottom are mounted fixed in the inactive state of the damping device. Thus, the work of the operator is not disturbed by any oscillation of the floor in the inactive state of the damping device.

According to one embodiment of the invention, the or at least one of the damping devices which is an activatable/deactivatable device arranged between the reception location of an operator of the basket and the upper end of the arm s 'extends between two basket parts, and said basket parts are mounted movable relative to each other in the active state of the damping device.

According to one embodiment of the invention, one of the basket parts is coupled to the upper end of the arm by the articulated connection coupling the upper end of the arm to the basket, this articulated connection comprising at least one pivoting connection of said vertical axis, said axis extending orthogonally to the floor and the body of the jack of the damping device is coupled to one of the parts of the basket and the piston of the said jack is coupled to the other of the parts of the basket and the piston and the body are, in the active state of the damping device, mounted movable relative to each other in the driven state in relative movement of said basket parts.

According to one embodiment of the invention, the nacelle being of the type in which the upper end of the drive arm for moving the basket is coupled to the basket by an articulated connection comprising at least one parallelogram structure deformable to the basket, the structure with a deformable parallelogram is connected to the upper end of the arm by a pivot connection with a so-called horizontal pivot axis perpendicular to the longitudinal axis of the arm, and the or at least one of the damping devices which is an activatable device/ deactivatable disposed between the receiving location of an operator of the basket and the upper end of the arm extends between the upper end of the arm and the deformable parallelogram structure.

According to one embodiment of the invention, the or at least one of the damping devices comprising at least one hydraulic cylinder with a body and a piston separating said body into two chambers, the body of the cylinder is coupled to the arm and the piston of said actuator is coupled to the deformable parallelogram structure or vice versa, the deformable parallelogram structure is mounted so as to move around the pivot axis of the pivot connection coupling the arm and the deformable parallelogram structure in the driven state in axial displacement of the piston inside the body and the damping device comprises a hydraulic accumulator in fluid communication with one of the cylinder chambers by a closable connection open in the active state of the damping device. This design is characterized by its simplicity. This design makes it possible to use the jack already present and used as a jack for correcting the horizontality of the floor of the basket as a damping device by associating it with a hydraulic accumulator, this damping device being activated when the closable fluid connection between the accumulator and cylinder is open. This results in a simplified nacelle design.

According to one embodiment of the invention, the device for determining a parameter representative of the angular position of the arm comprises at least one inductive sensor for detecting the extreme low position of the arm. This inductive sensor can allow the detection of the arm in abutment on the frame in the extreme low position. The elevation of the arm and the resulting absence of contact of the arm with the stopper can be detected by the inductive sensor. This detection information can be transmitted to the control unit. As a variant or in addition, the device can comprise an angular sensor for measuring the angular position of the arm relative to one of the extreme positions. These necessary conditions can be supplemented by other conditions, in particular when the arm is a telescopic arm. The extreme low position is defined in this case also by a retracted position of the arm.

According to one embodiment of the invention, said nacelle comprises a member for forced activation of the damping device, this forced activation member being a manual actuation activation member for forcibly controlling the passage of the inactive state in the active state of the damping device in the stressed state of said activation member.

According to one embodiment of the invention, when said deformable parallelogram structure is present, the basket is coupled to the deformable parallelogram structure by a pivoting connection with a so-called vertical axis, said axis extending orthogonally to the floor .

According to one embodiment of the invention, when the upper end of the arm is coupled to the basket by an articulated connection comprising at least one deformable parallelogram structure, the basket is coupled to the deformable parallelogram structure by a pivoting connection d said vertical axis, said axis extending orthogonally to the floor.

The invention will be better understood on reading the following description of exemplary embodiments, with reference to the appended drawings in which:

shows a perspective view of a nacelle according to the invention in operating mode in transport configuration,

shows a perspective view of a nacelle according to the invention in operating mode in working configuration,

represents a partial view of the nacelle in the active state of the damping device,

represents a partial view of the nacelle in the inactive state of the damping device,

represents a partial view of the nacelle in the inactive state of the damping device,

represents a partial view of the nacelle in the active state of the damping device,

represents a partial view of the nacelle in the inactive state of the damping device,

represents a partial view of the nacelle in the active state of the damping device.

As mentioned above, the nacelle 1 is a nacelle for the work in elevation of person. This nacelle 1 comprises a self-propelled rolling frame 6.

This rolling frame 6 is, for example, equipped with a heat engine connected to the wheels of the machine by a transmission to drive the wheels of the machine in rotation. The wheels could equivalently have been replaced by tracks.

This nacelle 1 also includes a basket 2 that can be coupled to the self-propelled chassis 6. This basket 2 comprises a cockpit 3 formed here by a control panel equipped in particular with an articulated control lever called a joystick. This control lever makes it possible in a known manner to control the elevation of the basket 2 which will be described below and the movement of the self-propelled chassis 6. The cockpit 3 is therefore equipped with controls for the movement of the frame 6 and for the elevation of the basket 2. This basket 2 comprises a floor 4 surmounted at least partially by a location 5 for receiving an operator inside which the operator takes place while being able to stand on the floor 4. This reception location 5 is delimited by guardrails or railings which form the side walls 15 of the basket 2. An access door can be formed in these walls 15 lateral. The basket 2 further comprises a bottom 14 extending under the floor 4 or merged with the floor 4 depending on the design of the basket 2.

The nacelle 1 also comprises, for the coupling of the basket 2 to the self-propelled chassis 6, an arm 91 for driving the basket 2 in displacement. This arm 91, which can be a simple arm, a telescopic arm, or an articulated arm as in the example shown in , is a swivel arm. This arm 91 is coupled at one of its ends, called lower, to the frame 6 by a pivot axis pivot connection, called horizontal that is to say extending substantially horizontally to within + 15 degrees , in the positioned state of the self-propelled chassis 6 on a flat horizontal surface.

One or more so-called lifting cylinders of the arm 91 which, depending on the design of the arm, extend between the frame 6 and the arm 91 and possibly between sections of the arm, when the arm is, as shown, an articulated arm, are provided. The or at least one of the lifting cylinders is controllable from the cockpit 3 of the basket 2. This or these lifting cylinders allow, in a manner known per se, a movement of the arm 91 between an extreme low position close to the ground and an extreme high position away from the ground. The so-called upper opposite end of the arm 91 is itself coupled to the basket 2, either directly, that is to say by a rigid connection in the simplest version, or by an articulated connection 21. This articulated connection 21 can have a large number of shapes. In the example of the , this articulated link 21 comprises a deformable parallelogram structure 92 called a pendular structure. This deformable parallelogram structure 92 is well known to those skilled in the art. It will not be described in more detail below.

In the example shown for example in , this deformable parallelogram structure 92 is coupled to the upper end of the arm 91 by a pivot link 13 with a pivot axis, said to be horizontal, perpendicular to the longitudinal axis of the arm. The so-called horizontal pivot axis extends substantially parallel to the plane of support on the ground of the frame 6 in the positioned state of the frame 6 on a flat horizontal surface. The basket 2 is coupled to the structure 92 with a deformable parallelogram by a pivoting link 18 with a so-called vertical axis, said axis extending orthogonally to the floor 4. In a simpler version of the articulated link 21, as illustrated for example at there , the deformable parallelogram structure 92 is eliminated and the connection 18 with so-called vertical axis pivoting is maintained.

A jack-type actuator, that is to say formed by a jack, is arranged between the upper end of arm 91 and said structure 92 with a deformable parallelogram. This actuator, called slave, shown at 20 in the figures, is generally in fluid communication with an actuator, called master, also formed by a cylinder. This master actuator is arranged between the arm 91 and the frame 6. By "fluidic communication", it is meant that one of the chambers of the cylinder constituting the master actuator is connected by a first fluid circuit to one of the chambers of the constituent jack of the slave actuator 20 and that the other chamber of the constituent jack of the master actuator is connected by a second circuit to the other chamber of the jack of the slave actuator 20. This constituent jack of the actuator slave can also have its own control as shown in . Thus, this actuator can be both a slave actuator and an independent actuator with its own control or exclusively a slave actuator or exclusively an independent actuator without departing from the scope of the invention.

In the case where this cylinder is a slave cylinder, the displacement of the arm 91 under the action of the or one of the lifting cylinders generates in parallel a displacement of the master actuator and consequently of the slave actuator in communication fluidic with the master actuator. This assembly makes it possible to maintain the horizontality of the floor 4 of the basket 2 at least during a pivoting movement of the arm 91.

The nacelle 1 comprises a device 8 for determining a parameter representative of the angular position of the arm 91 with respect to the extreme low and high positions of the arm 91.

This device 8 for determining a parameter representative of the angular position of the arm 91 can have a large number of forms. This device 8 for determining a parameter representative of the angular position of the arm 91 can comprise at least one angular sensor arranged at the level of the pivoting connection of the arm 91 to the frame 6. This angular sensor allows the measurement of the angle formed by the arm with a plane passing through the longitudinal axis of the arm in the extreme low position of said arm. As a variant or in addition, the device 8 for determining a parameter representative of the angular position of the arm can be formed by a sensor, for example inductive, for detecting the extreme low position of the arm, the lifting of the arm from this extreme low position wherein the arm is in abutment on the frame being detected by said sensor. In the case of an articulated and/or telescopic arm, additional sensors are provided at each section of the articulated arm and/or at the extended or retracted position of the telescope to reliably identify the extreme low position of the arm . Thus the extreme low position corresponds to an extreme low position of the arm or arm sections when the arm is articulated and, in addition, to the retraction of the telescope when the arm is a telescopic arm.

The nacelle 1 further includes a steering unit 10 . This control unit 10 is configured to acquire data from the device 8 for determining a parameter representative of the angular position of the arm 91.

This control unit 10 is in the form of an electronic and computer system which includes, for example, a microprocessor and a working memory. According to a particular aspect, the control unit is in the form of an electronic and computer system which comprises for example a microprocessor and a working memory. According to a particular aspect, the control unit can take the form of a programmable automaton. That is, the described functions and steps can be implemented as a computer program or via hardware components (eg programmable gate arrays). In particular, the functions and steps performed by the control unit or its modules can be performed by instruction sets or computer modules implemented in a processor or controller or be performed by dedicated electronic components or components of the logic circuit type. programmable (or FPGA which is the acronym for field-programmable gate array, which literally corresponds to in-situ programmable gate network) or of the integrated circuit type specific to an application (or ASIC which is the acronym of English application-specific integrated circuit, which literally corresponds to integrated circuit specific to an application). It is also possible to combine computer parts and electronic parts. When it is specified that the unit or means or modules of said unit are configured to carry out a given operation, this means that the unit comprises computer instructions and the corresponding means of execution which make it possible to carry out said operation and/ or that the unit includes corresponding electronic components.

It is also possible to combine computer parts and electronic parts. When it is specified that the unit or means or modules of said unit are configured to carry out a given operation, this means that the unit comprises computer instructions and the corresponding means of execution which make it possible to carry out said operation and/ or that the unit includes corresponding electronic components.

This control unit 10 may include a memory for storing a threshold value corresponding to the value of the angle formed by the arm in its extreme low position. As a variant or in addition, this control unit 10 can also receive as input a signal from the inductive sensor described above corresponding to the fact that the arm 91 is no longer in abutment and has been moved in the direction of a lifting, this signal being representative of the passage of the arm from the extreme low position to a position other than the extreme low position when the arm is not articulated.

The nacelle 1 still has two modes of operation called, one, mode of operation in working configuration, the other, mode of operation in transport configuration. These operating modes can be selectively activated according to the data provided by the device 8 for determining a parameter representative of the angular position of the arm 91.

The control unit 10 is configured to control the activation of the mode of operation in transport configuration when the arm 91 is in the extreme low position as defined above.

The control unit 10 is configured to control the activation of the working configuration operating mode when the arm 91 passes from the extreme low position to another position. The activation of one or other of the operating modes therefore takes place automatically.

The operating modes in work configuration and in transport configuration are each defined at least by a maximum speed of movement on the ground of the self-propelled chassis 6.

In practice, generally, in the operating mode in work configuration, the maximum speed of movement on the ground of the chassis 6 of the nacelle 1 is of the order of 0.6 km / h, while in the operating mode in configuration transport, the maximum speed of movement on the ground of the chassis 6 of the nacelle can be equal to at least 5 km/h .

It is therefore noted that the maximum speed of movement of the self-propelled chassis 6 in the operating mode in the work configuration is lower than the maximum speed of movement of the self-propelled chassis 6 in the operating mode in the transport configuration to avoid any risk of accident when the arm is in the high position, that is to say in the operating mode in work configuration. In fact, in the event of high speed in this mode of operation, there would be a risk of the operator being expelled from the basket 2.

To complete the assembly, the nacelle 1 comprises at least one device 11 for damping the up-and-down oscillating movements of the basket 2, these oscillating movements being able to occur in particular when the chassis 6 is rolling moves on the ground over uneven terrain. There is a risk of the operator being expelled from the basket 2 if these movements are of too great an amplitude. In addition, these oscillations put a great deal of strain on the operator, who must dampen these movements with his knees by maintaining constant flexion. This results in muscle fatigue of the operator.

This damping device 11 is an activatable/deactivatable device which is arranged between the location 5 for receiving the operator in the basket 2 and the upper end of the arm 91. This damping device 11 can affect a large number of shapes.

In the examples shown, the damping device 11 comprises at least one hydraulic jack 12, as in the example shown in , or several hydraulic cylinders in parallel as shown in Figures 6 and 7.

The or each hydraulic jack 12 comprises a body 121 and a piston 122 able to slide axially inside the body and separating said body into two chambers 123. In the examples of FIGS. 5 to 7, the chambers 123 are interconnected by a fluidic circuit 124 equipped with a shutter member 125. This shutter member 125 is here formed by a solenoid valve. This shutter member 125 is mounted to move between an open position corresponding to the active state of the damping device 11 and a closed position corresponding to the inactive or deactivated state of the damping device 11 in which the transfer of fluid enters said chambers 123 is prevented. Each chamber contains an elastically deformable member 128, such as a spring, for restoring the piston in the direction of the other chamber.

In the example shown in Figures 6 and 7, the damping device 11 comprises two cylinders 12 mounted in parallel and each arranged between the floor 4 and the bottom 14 of the basket 2. In this embodiment, the floor 4 and the bottom 14 are mounted so as to move towards or away from each other in the activated state of the damping device 11.

The body 121 of each jack 12 of the damping device 11 is coupled to the bottom 14 of the basket 2 and the piston 122 of the jack 12 is coupled to the floor 4. The piston 122 of each jack 12 is axially movable inside the body 121 in the driven state in relative movement of the floor 4 and the bottom 14 in the direction of a rapprochement or a separation from each other in the active state of the damping device 11. This axial movement of the piston 122 is damped by the passage of the fluid from one chamber to another of the cylinder. In the deactivated or inactive state of the damping device 11, corresponding to the closed state of the shutter member 125, any passage of fluid from one chamber to another is prevented and the floor 4 is then fixed by relative to the bottom 14 of the basket 2.

Figures 4 and 5 illustrate another possibility of positioning the damping device 11. In these figures, the damping device 11 extends between two parts 161 and 162 of the basket, said parts of the basket being mounted so as to move one with respect to the other in the active state of the damping device 11. Again, the cylinder body of the damping device 11 is coupled to one of the parts and the piston of the cylinder to the other part.

Thus, one of the parts, namely here the basket part 162 is coupled to the upper end of the arm 91 by the articulated connection 21, said articulated connection 21 comprising at least one pivoting connection 18 of said vertical axis, said axis extending orthogonally to floor 4 of basket 2 and body 121 of cylinder 12 of damping device 11 is coupled to said part 162 of basket 2. Piston 122 of said cylinder 12 is coupled to the other of the parts of basket, namely the basket part 161 which extends between the basket part 162 described previously and the basket 2. The piston 122 and the body 121 of the cylinder 12 are, in the active state of the damping device 11, mounted movable relative to each other in the driven state in relative movement of said basket parts 161,162.

This relative movement of the basket parts 161 and 162 corresponds to a relative movement of the basket parts 161 and 162 in a direction parallel to the axis of the pivoting connection 18 of one of the basket parts to the arm 91.

Independently of the embodiment of the damping device, as illustrated in FIGS. 4 to 7, the control unit 10 is configured to control the passage of the shutter member 125 from the open position to the closed position or conversely depending on the active or inactive state of the desired damping device 11 .

The control unit 10 is configured to control the activation or deactivation of the damping device 11 at least according to the data provided by the device 8 for determining a parameter representative of the angular position of the arm.

In particular, the damping device 11 is in the active state in the mode of operation in transport configuration of the nacelle and the control unit is configured to control the deactivation of the damping device 11, i.e. i.e. the passage of the damping device 11 from the active state to the inactive state when the arm 91 is moved away from the extreme low position due to an elevation by pivoting movement in the direction of the extreme high position and/ or an exit from the telescope in the case of a telescopic arm.

Thus, the passage of the nacelle from the mode of operation in transport configuration to the mode of operation in work configuration is accompanied by a deactivation of the damping device 11 and the passage of the nacelle from the mode of operation in work configuration to the mode of operation in transport configuration is accompanied by an activation of the damping device 11. The damping device 11 can be positioned at various locations on the nacelle 1.

In the example shown in Figures 2 and 3, the damping device 11 extends between the upper end of the arm 91 and the deformable parallelogram structure 92 of the link 21 articulated from the upper end of the arm 91 to the basket . Indeed, in this example, the nacelle 1 is of the type whose upper end of the arm 91 for driving the basket 2 in displacement is coupled to the basket by an articulated connection 21 comprising a structure 92 with a deformable parallelogram. The deformable parallelogram structure 92 is connected to the upper end of the arm 91 by a pivot connection 13 with a so-called horizontal pivot axis perpendicular to the longitudinal axis of the arm 91, and the or at least one of the damping devices 11 which is an activatable/deactivatable device arranged between the location 5 for receiving an operator from the basket 2 and the upper end of the arm 91 extends between the upper end of the arm 91 and the structure 92 with a deformable parallelogram.

Again, the damping device 11 comprises a hydraulic jack 12 with a body 121 and a piston 122 separating said body 121 into two chambers 123. The body 121 of the jack 12 is coupled to the arm 91 and the piston 122 of the jack 12 is coupled to the deformable parallelogram structure 92. The reverse is also possible. The deformable parallelogram structure 92 is movably mounted around the pivot axis of the pivot connection 13 coupling the arm 91 and the deformable parallelogram structure 92 in the driven state in axial displacement of the piston 122 inside the body 121 and the damping device 11 comprises a hydraulic accumulator 127 produced here in the form of a membrane accumulator in fluid communication with one of the chambers 123 of the cylinder 12 by a closable connection open in the active state of the damping device 11 .

The fluid connection closure member, shown at 126, is again a solenoid valve controlled in movement by the control unit for switching the fluid connection from the open state to the closed state. Thus, when the link is open, damping is possible. The chamber 123 arranged on the bottom side of the cylinder can allow, through its fluidic connection with the hydraulic accumulator, in the open state of the connection, an evacuation of the contents of said chamber towards the hydraulic accumulator, this energy then being recoverable.

In this embodiment, where said deformable parallelogram structure 92 is present, the basket 2 is coupled to the deformable parallelogram structure 92 by a pivoting connection 18 of so-called vertical axis, said axis extending orthogonally to the floor 4.

Note that in the example shown, the actuator 12 has a body 121 and a piston 122 common with the slave actuator described above. The piston 122 of the cylinder 12 can move axially inside the body 121 under the effect of a movement of the master actuator itself driven in movement under the action of the lifting cylinder. This results in simplicity of construction.

Finally, the nacelle may comprise a member 17 for forced activation of the damping device 11 . This activation member 17 is a manually actuated activation member for forcibly controlling the transition from the inactive state to the active state of the damping device 11 in the stressed state of said member 17 activation. This activation member 17 can be arranged at the level of the cockpit 3 and be formed by a button.

Regardless of the position of the damping device 11 on the nacelle 1, the operation is always similar. When the engine of the nacelle 1 is started, the mode of operation in transport configuration is activated and the damping device 11 is in the active state, that is to say that the shutter member 125 or 126 is in the open position. The control unit receives as input the data from the device 8 for determining a parameter representative of the angular position of the arm and processes them. When it results from the processing of the data that the arm 91 is no longer in the extreme low position, and is therefore in a position other than the extreme low position, the operating mode in work configuration is activated and the damping device 11 is deactivated, that is to say made inactive, by closing the shutter member 125 or 126. These conditions are maintained until the processing of the data provided by the device 8 for determining a parameter representative of the angular position at the arm control unit corresponds to the case where the arm 91 is again in the extreme position. low. The control unit 10 then controls again the activation of the mode of operation in transport configuration and the activation of the damping device 11. Of course, in each mode of operation of the nacelle 1, the maximum speed of movement of the self-propelled chassis 6 is adapted and controlled by the control unit 10.

Claims (13)

Elevating nacelle (1) for work in elevation of person, said nacelle (1) comprising:
- a basket (2) comprising a cockpit (3) and a floor (4) surmounted at least partially by a location (5) for receiving an operator,
- a self-propelled chassis (6),
- an arm (91) for driving the basket (2) in displacement, one end of which, called the lower end, is pivotally connected to the frame (6) for an angular displacement of the arm between an extreme low position close to the ground and an extreme high position away from the ground and whose opposite end, called the upper end, is coupled directly or by an articulated connection (21), to the basket (2),
- a device (8) for determining a parameter representative of the angular position of the arm (91), and
- a control unit (10) configured to acquire data from the device (8) for determining a parameter representative of the angular position of the arm (91),
- said nacelle (1) having at least two selectively activatable operating modes, an operating mode, said in transport configuration, in which the arm (91) is in the extreme low position and an operating mode, said in work configuration, activated when the arm (91) occupies a position other than the extreme low position, and the control unit (10) being configured to control an activation of one or other of the operating modes of the nacelle (1) at the least as a function of the data provided by the device (8) for determining a parameter representative of the angular position of the arm (91), characterized in that the modes of operation in the work configuration and in the transport configuration are each defined at least by a maximum speed of movement of the self-propelled chassis (6), in that the maximum speed of movement of the self-propelled chassis (6) in the operating mode in working configuration is lower than the maximum speed of movement of the self-propelled chassis (6) in the mode of operation in transport configuration, in that the nacelle (1) comprises at least one device (11) for damping up-and-down oscillating movements of the floor (4) of the basket (2), in that that this damping device (11) is an activatable/deactivatable device arranged between the location (5) for receiving an operator from the basket (2) and the upper end of the arm (91) and in that the control unit (10) is configured to control the activation or deactivation of the damping device (11) at least according to the data provided by the device for determining a parameter representative of the angular position of the arm (91) . Lifting platform (1) according to Claim 1, characterized in that the damping device (11) is in the active state in the mode of operation in the transport configuration of the platform (1) and the unit (10) of control is configured to control the deactivation of the damping device (11) in the activated state of the operating mode in working configuration of the nacelle (1). Lifting platform (1) according to one of Claims 1 or 2, characterized in that the or at least one of the damping devices (11) comprises at least one hydraulic jack (12), the or at least the one of the cylinders comprising a body (121) and a piston (122), the body (121) and the piston (122) being movable relative to each other, said piston (122) separating said body (121) with two bedrooms (123) Lifting platform (1) according to Claim 3, characterized in that the two chambers (123) are interconnected by a fluidic circuit (124) equipped with a closure member (125) mounted to move between an open position corresponding to the active state of the damping device (11) and a closed position, corresponding to the inactive state of the damping device (11), in which any transfer of fluid between said chambers (123) is prevented, each chamber ( 123) housing at least one elastically deformable member (128) for biasing the piston (122) towards the other chamber (123) . Lifting platform (1) according to one of Claims 1 to 4, characterized in that the basket (2) comprises a bottom (14) and side walls (15) surrounding the said bottom (14), in that the floor ( 4) extends above said bottom (14) and in that the or at least one of the damping devices (11) which is an activatable/deactivatable device arranged between the location (5) for receiving operator of the basket (2) and the upper end of the arm (91) extends at least partially between the floor (4) and the bottom (14) of the basket (2), the floor (4) and the bottom (14) being mounted so as to move towards or away from each other in the active state of the damping device (11). Lifting platform (1) according to Claim 5 taken in combination with one of Claims 3 or 4, characterized in that the body (121) of the cylinder (12) of the damping device (11) is coupled to the bottom (14 ) of the basket (2) and the piston (122) of the said actuator (12) is coupled to the floor (4) or vice versa and in that the piston (122) and the body (121) are mounted so as to move relative to each other the other in the driven state in relative movement of the floor (4) and the bottom (14) in the direction of a rapprochement or a separation from each other in the active state of the device damping (11). Lifting platform (1) according to one of Claims 1 to 6, characterized in that the or at least one of the damping devices (11), which is an activatable/deactivatable device arranged between the location (5) of reception of an operator of the basket (2) and the upper end of the arm (91) extends between two parts (161, 162) of the basket (2), and in that the said parts (161, 162) of the basket (2) are mounted movable relative to each other in the active state of the damping device (11). Lifting platform (1) according to Claim 7 taken in combination with one of Claims 3 or 4, characterized in that one of the parts (161,162) of the basket is coupled to the upper end of the arm (91) by the articulated connection (21) coupling the upper end of the arm (91) to the basket (2), this articulated connection (21) comprising at least one pivoting connection (18) with a so-called vertical axis, the said axis extending orthogonally to the floor (4) and in that the body (121) of the cylinder (12) of the damping device (11) is coupled to one of the parts of the basket (2) and the piston (122) of the said cylinder (12) is coupled to the other of the basket parts and in that the piston (122) and the body (121) are, in the active state of the damping device (11), mounted movable relative to each other the other in the driven state in relative movement of said basket parts (161,162). Lifting platform (1) according to one of Claims 1 to 3, characterized in that the platform (1) being of the type in which the upper end of the arm (91) for driving the basket (2) in displacement is coupled to the basket (2) by an articulated connection (21) comprising at least one deformable parallelogram structure (92), the deformable parallelogram structure (92) is connected to the upper end of the arm (91) by a pivot connection (13) with a so-called horizontal pivot axis perpendicular to the longitudinal axis of the arm (91), and in that the or at least one of the damping devices (11) which is an activatable/deactivatable device arranged between the location ( 5) for receiving an operator from the basket (2) and the upper end of the arm (91) extends between the upper end of the arm (91) and the structure (92) with a deformable parallelogram. Lifting platform (1) according to Claim 9, characterized in that the or at least one of the damping devices (11) comprising at least one hydraulic cylinder (12) with a body (121) and a piston (122) separating said body (121) into two chambers (123), body (121) of jack (12) is coupled to arm (91) and piston (122) of said jack (12) is coupled to structure (92) at deformable parallelogram or vice versa, in that the deformable parallelogram structure (92) is movably mounted around the pivot axis of the pivot link (13) coupling the arm (91) and the deformable parallelogram structure (92) to the state driven in axial displacement of the piston (122) inside the body (121) and in that the damping device (11) comprises a hydraulic accumulator (127) in fluid communication with one of the chambers (123) of the cylinder (12) by a closable connection open in the active state of the damping device (11). Lifting platform (1) according to one of Claims 1 to 10, characterized in that the device (8) for determining a parameter representative of the angular position of the arm (91) comprises at least one inductive sensor for detecting the extreme low position of the arm (91). Lifting platform (1) according to one of Claims 1 to 11, characterized in that the said platform (1) comprises a member (17) for the forced activation of the damping device (11), this member (17) for forced activation being a manually actuated activation member for forcibly controlling the transition from the inactive state to the active state of the damping device (11) to the requested state of said activation member (17). Lifting platform (1) according to one of Claims 1 to 12, characterized in that, when the upper end of the arm (91) is coupled to the basket (2) by an articulated connection (21) comprising at least one structure ( 92) with a deformable parallelogram, the basket (2) is coupled to the structure (92) with a deformable parallelogram by a pivoting connection (18) of so-called vertical axis, said axis extending orthogonally to the floor (4).