EP1172323A1 - Articulated jib crane - Google Patents

Abstract

The crane consists of a pylon (21) with a jib foot (31) pivoted to its tip by one end (35) and having the jib (41) articulated to its other end (36). The jib has its tip (43) on one side of its pivot point (45) and a counter-jib (42) on the other, and the jib is retained by an assembly with one or more posts (16), a tie member (25) and at least one two-way power cylinder connecting the foot and jib. The foot and counterjib are designed to allow the jib tip to be aligned with the foot.

Description

The present invention relates to a lifting device with distributor boom working in articulated mode or in liftable for lifting and handling loads comprising a pylon, a boom foot articulated in rotation at its first end at the top of the pylon, a dart articulated in rotation at the second end of the foot arrow, said dart comprising on either side of its articulation axis at the foot of the arrow respectively a point and a counter-dart, a restraint system arrow comprising at least one punch and a tie rod boom, and at least one double-acting articulation cylinder connecting the arrow foot to the dart, determining the angle between arrowhead and dart.

To allow handling of loads on construction sites, we usually use cranes with adjustable horizontal distributing jib on which slides a carriage serving as a guide for means of suspension.

In certain circumstances, for example when construction sites are congested or when national legislation prohibits overflight of plots adjacent to the site, they are prefer either lifting jib cranes and swiveling, i.e. articulated distributing jib cranes adjustable. The lifting jib cranes have the advantage over horizontal boom cranes of comparable pylon heights, able to carry loads at greater heights.

However, these two types of cranes have certain disadvantages compared to horizontal boom cranes. On the one hand, their minimum ranges being relatively handling of loads in the immediate vicinity of the base of the cranes cannot be insured. On the other hand, it is very difficult to control a regularity of the speed of load distribution which avoids all untimely swaying.

Patent FR 2605619 describes a crane of defined type input, which combines the effects of a jib crane distributor articulated with those of a jib crane liftable dispenser, giving it a certain versatility. In addition, the mast of this crane has the advantage of being unfoldable and foldable and this automatically.

However, due to the design of the joints of the distributing boom, this crane always has a significant minimum range. In addition, the gain in height under hook obtained when the arrow tip is raised remains relatively small, cannot exceed an amplitude angular equivalent to 30 ° to the horizontal.

On the other hand, when this crane is folded up and placed on a rolling chassis, specially designed for its transport, the road unit thus formed is just admitted to pass under a template of 4 meters, allowing it to access on the road network. However, this set cannot travel on certain secondary axes with restricted gauge.

The object of the present invention is to produce a multipurpose orientable distributing jib hoist, can also be used as a jib crane liftable vending machine only like a jib crane articulated vending machine or even as a dart crane tilting, the transformation from one function to another in front be as simple as possible.

The present invention also aims to achieve of a lifting device with an adjustable distributing jib versatile which when working as a jib crane articulated distributor, has a very minimal reach low, but the highest possible maximum range.

The present invention also aims to achieve of a lifting device with an adjustable distributing jib versatile capable of distributing a load with speed regular, especially with horizontal speed constant when working like a jib crane articulated distributor.

The present invention also aims to achieve of a lifting device with an adjustable distributing jib versatile, which when working as a jib crane lifting distributor allows the highest hook height high possible.

The present invention finally aims to achieve of a lifting device with an adjustable distributing jib versatile which, when the boom is hinged on a pylon articulated, can be folded in the most compact way possible so that it can be placed in a marine-type container for transport.

To this end, the subject of the present invention is a machine lifting with adjustable distributing jib working in articulated or lifting mode for lifting and handling of loads as defined from the outset where the part of the boom foot near said second end and the counter-dart have conjugate shapes allowing the dart tip to come into position aligned with the boom foot.

The arrow rod can be connected to the tip of dart passing through at least one lifting strut attached to the dart.

The lifting strut can be arranged substantially at the junction between the counter-dart and the tip of the dart.

The counter-dart and the part of the arrow foot near its second end may have profiles prismatic and can come into contact with each other when jib foot and dart are aligned.

The part of the arrowhead close to its second end may have the shape of a two fork branches and that the counter-dart can be accommodated in the space between the two branches.

The boom foot can consist of two beams parallel and that the counter-dart can be accommodated in the spacing between the two beams.

The boom foot and the dart can be connected by two identical articulation cylinders, mounted symmetrically with respect to the vertical plane of symmetry of the spacecraft lifting.

The articulation cylinder (s) can connect directly from the jib foot to the counter-dart.

The articulation cylinder (s) can connect straight arrowhead and dart tip.

Each articulation cylinder can connect the boom foot and the dart via two connecting rods.

Said connecting rods can be articulated to each other and to the cylinder by the same axis of rotation.

• la figure 1 représente en perspective un premier mode d'exécution de l'engin de levage avec une flèche distributrice en position de travail en mode articulé et, en arrière plan, en mode relevable;
• la figure 2 représente, par une vue en élévation, le premier mode d'exécution de l'engin de levage ayant une flèche distributrice en position repliée le long du pylône;
• la figure 3 représente, par des vues superposées en élévation, différentes étapes du repliage du pylône du premier mode d'exécution de l'engin de levage;
• les figures 4a à 4d représentent, par des vues en élévation, les différentes étapes de transformation du mode articulé au mode relevable de la flèche distributrice du premier mode d'exécution de l'engin de levage;
• la figure 5 représente, par une vue en élévation, le premier mode d'exécution de l'engin de levage en position repliée;
• les figures 6a à 6c représentent, par des vues en élévation, différents moyens pour transporter le premier mode d'exécution de l'engin de levage.
• la figure 7 représente, par des vues superposées en élévation, différentes phases de fonctionnement du premier mode d'exécution de l'engin de levage avec une flèche distributrice en position de travail en mode relevable;
• la figure 8 représente, par une vue en perspective, le détail d'un dispositif pour le blocage de la flèche distributrice en position de travail en mode relevable du deuxième mode d'exécution de l'engin de levage;
• la figure 9 représente en perspective un deuxième mode d'exécution de l'engin de levage avec une flèche distributrice en position de travail en mode articulé et, en arrière plan, en mode relevable;
• la figure 10 représente, par une vue en perspective, l'articulation par vérin entre pied de flèche et fléchette d'une variante du deuxième mode d'exécution de l'engin de levage en position de travail en mode articulé.
• la figure 11 représente, par une vue en élévation, l'articulation par vérin entre pied de flèche et fléchette de la variante de la figure 10, avec la flèche distributrice en position repliée.
• les figures 12a, 12b et 12c représentent, par des vues schématiques en élévation, un troisième mode d'exécution de l'engin de levage, avec sa flèche distributrice respectivement en mode articulé, relevable et inclinable.
• les figures 13a et 13b représentent par des vues en perspective l'articulation, respectivement avec un vérin et deux vérins, entre pied de flèche et fléchette du troisième mode d'exécution de l'engin de levage en position de travail en mode articulé.
• les figures 14a, 14b, 14c, 14d, 14e, 14f et 14g représentent schématiquement des variantes de l'articulation par vérin(s) entre pied de flèche et fléchette du troisième mode d'exécution, en position de travail en mode articulé.

In order to facilitate understanding of the invention, its characteristics and advantages, several embodiments are presented below, with reference to the drawing in which:

• Figure 1 shows in perspective a first embodiment of the lifting device with a distributor boom in the working position in articulated mode and, in the background, in lifting mode;
• 2 shows, in an elevational view, the first embodiment of the lifting device having a distributing boom in the folded position along the pylon;
• FIG. 3 represents, by superimposed views in elevation, different stages of the folding of the pylon of the first embodiment of the lifting machine;
• FIGS. 4a to 4d show, in elevation views, the different stages of transformation from the articulated mode to the lifting mode of the distributing boom of the first embodiment of the lifting machine;
• Figure 5 shows, in an elevational view, the first embodiment of the lifting device in the folded position;
• Figures 6a to 6c show, in elevation views, different means for transporting the first embodiment of the lifting device.
• FIG. 7 represents, by superimposed views in elevation, different phases of operation of the first embodiment of the lifting machine with a distributing boom in the working position in lifting mode;
• FIG. 8 shows, in a perspective view, the detail of a device for blocking the dispensing boom in the working position in the lifting mode of the second embodiment of the lifting machine;
• FIG. 9 shows in perspective a second embodiment of the lifting machine with a distributor boom in the working position in articulated mode and, in the background, in lifting mode;
• FIG. 10 represents, in a perspective view, the articulation by a jack between the jib foot and the jib of a variant of the second embodiment of the lifting machine in the working position in articulated mode.
• Figure 11 shows, in an elevational view, the articulation by cylinder between the foot of the arrow and dart of the variant of Figure 10, with the distributor arrow in the folded position.
• Figures 12a, 12b and 12c show, in schematic elevation views, a third embodiment of the lifting device, with its distributing boom respectively in articulated, lifting and tilting mode.
• Figures 13a and 13b show in perspective views the joint, respectively with a cylinder and two cylinders, between the boom foot and jib of the third embodiment of the lifting device in the working position in articulated mode.
• Figures 14a, 14b, 14c, 14d, 14e, 14f and 14g schematically show variants of the articulation by jack (s) between the jib foot and dart of the third embodiment, in the working position in articulated mode.

To simplify writing and facilitate understanding of the invention, reference numbers identical have been given in several figures to pieces identical or equivalent of several execution variants

The first embodiment of the boom hoist swiveling distributor working in articulated mode or in lifting mode for lifting and handling loads such that shown in Figure 1 has a folding pylon consisting of two sections hinged to each other, namely a pylon base 21 and an upper pylon 22. The base pylon is pivotally mounted around a horizontal axis on the front part of a rotating chassis or turret 12. The pylon upper door, pivoting around a hinge horizontal 26, on the one hand a distributing arrow 31, 41 articulated and liftable and, on the other hand, two punches symmetrical 16 connected at their ends by an axis carrying two pulleys 17. The turret 12 is pivotally mounted around a vertical axis on a supporting frame 11.

The pylon is kept in the working position thanks to a set of elements consisting of a ballast 13 fixed on the part rear of turret 12, straightening struts 23 connecting the pylon to the turret, two tie rods 25, all connected to a control device not shown on the drawing, which could for example be a winch placed on the turret 12, the two tie rods passing respectively over the two pulleys 17 of the punches 16.

The articulated and lifting distributor boom is consisting of two master pieces, namely a foot arrow 31 and a dart 41, hinged to each other.

The lower end 35 of the jib foot 31 is connected, via the horizontal joint 26, at the top of the upper pylon 22. The other end 36 of the foot boom is connected, via a joint horizontal 45, with dart 41. The articulation 45 divides the dart 41 in two asymmetrical parts, namely a counter-dart 42, carrying at its end two pulleys 44, and a dart point 43, carrying at its end 46 two pulleys guiding load suspension means constituted a lifting cable 53, a muffle and a hook lifting 54.

As shown in the foreground of Figure 1, when the end 46 of the dart point 43 is in position A, the distributor arrow is in position working in articulated mode. The tie rods 25 pass successively in the grooves of the pulleys 17 of the two punches 16, then in those of the two pulleys 44 of the counter-dart 42, and are fixed on the dart 41. The tie rods 25 form with the jib foot 31, the two punches 16 and the counter-dart 42 a quadrilateral deformable. This geometric configuration allows the end 46 of the tip of the dart 43 to move along an approximately flat and horizontal trajectory, represented by dashed line 51.

In the background of FIG. 1, when the end 46 of the dart point 43 is in position B, the arrow vending machine is in working position in mode lift. The dart 41 is aligned with the foot of arrow 31. It can be seen that the tie rods 25 are fixed on the dart 41, near the end 46 of the tip of dart 43. In this configuration, these tie rods 25 do not pass more than on the pulleys 17 of the two punches 16, and now form a triangle with the two punches 16 and the aligned boom foot 31 - dart 41 assembly.

The background and perspective part of the figure 1 showing the distributor boom in the working position in lifting mode, shows that the arrow foot 31 is in fact consisting of two parallel beams 31a and 31b mounted laterally on both sides, on the one hand, of the pylon upper 22, and, on the other hand, the dart 41.

Such a construction with two beams is advantageous. In Indeed, the counter-dart 42 can be housed within the slot or spacing 34 between these two beams 31a and 31b and a perfect alignment of the dart 41 with the foot of arrow 31 is then obtained, which, as described below, allows a significant gain in height under hook compared to to the versatile arrows of the prior art which have a angled shape.

In addition, such a two-beam construction reinforces the structure of the hoist by providing better resistance to torsion.

The general movement of the whole in articulated, governed mode by the particular geometry of the quadrilateral (44, 45, 26, 17), is known from the prior art. It is however important to highlight the role played by two of the elements of the hoist, namely the control system of the movement and the split between the two beams of the foot of arrow.

In an articulated mode configuration in which the end 46 of the dart point 43 is located by example in position A, we can block the device controlling the tie rods 25 so as to maintain constant the distance between pulleys 17 and 44 during all phases to change the angle of the boom joint vending.

The control device (1) of the articulation 45 is consisting of a system with connecting rods and double-acting cylinder (s), which will be described in detail later.

In order to bring the end 46 of the dart point 43 towards position D corresponding to the minimum range of the lifting machine, we simply operate by movement relative of the rod relative to the cylinder of the jack (s). The lifting hook 54 progressively approaches the pylon.

Thanks to this simple mode of controlling the foot angle of arrow / dart, it becomes easy to control the regularity of the speed of translation of the end 46 of the tip of dart and thus avoid any untimely swaying of the charge during handling.

During the horizontal movement shortening the range, the end 46 of the dart point 43 passes through the intermediate position C, approximately corresponding to the position of minimum reach which was obtained with the machines lifting of the prior art. Now, because of the presence of the slot or spacing 34 between the two beams 31a and 31b of the arrowhead 31 which allows the tip to dart 43 to lodge there, the movement can continue until the end 46 of the dart point 43 is brought to position D, right against the boom foot. This position D corresponds to the minimum reach of the hoist.

Starting from this position D corresponding to the range minimum and to return to position A, it suffices to operate the reverse movement of the cylinder rod (s) of articulation, while maintaining the blocking of the device control of the tie rods 25 so that the end 46 of the point of the dart 43 is gradually moving away from the top of the upper pylon 22.

Continuing the movement beyond position A, always keeping the control device locked of the tie rods 25, the articulated mode is transformed in lifting mode of the distributing boom.

As symbolized by the white arrows 56, 57 in Figure 4a, the boom foot 31 lowers and the end 46 of the tip of the dart straightens. In Figure 4b, the tie rods 25 are almost aligned with the dart 41. In FIG. 4c, the boom foot continues to descend, the tie rods 25 are then separated from the pulleys 44 of the counter-dart 42.

Finally, in FIG. 4d, the position of the attachment point 48 tie rods 25 on the tip of the dart 43 becomes related. The dart 41 is perfectly aligned with the boom foot 31. A locking device 61, described below, now this alignment can be expected optionally, in addition to the jack system (1). The arrow vending machine is then in working position in mode lift. The end 46 of the dart point 43 is located at position E, the distributor arrow is already tilted a few degrees from the horizontal.

Figure 8 shows in detail the elements constituting the blocking device 61 integral, on the one hand, with each of the two beams 31a and 31b of the jib foot 31 and, on the other part, of the counter-dart 42 of the dart 41 and cooperating together to keep dart 41 aligned and the arrowhead 31. To make it easier to understand, the tie rods and the articulation cylinder system have been deleted in this figure.

Under each of the two beams 31a and 31b are mounted in protrusions and placed respectively opposite a piece 62a and a room 62b. In each of these two rooms is a sliding locking cylinder 63a and 63b respectively in a horizontal transverse direction respectively at within housings 64a and 64b. Lock cylinders are kept partly outside their housing under the action of the springs 65a and 65b respectively. Under the counter-dart 42 is located, projecting, a piece of U inverted 66, whose two side faces are bevelled. Two holes 67a and 67b, intended to serve respectively as housing at the external part of each of the cylinders locking 63a and 63b, were practiced respectively on the two lateral faces of the part 66.

In the final alignment phase of the dart 41 and the arrowhead 31, the end of the outer part of the two locking cylinders 63a and 63b comes into contact with the Exhibit 66. The bevelled shape of the side faces of this part acting as a guide, the locking cylinders are gradually introduced by sliding within their respective housings 64a and 64b and the springs 65a and 65b are gradually compressed. The alignment phase is continuing, the ends of the locking cylinders go be located respectively with holes 67a and 67b.

The precise alignment of the cylinders 63a, 63b with the holes 67a, 67b is obtained by means of two stops 68a, placed respectively on either side of room 66. At this particular position, under the action of springs 65a and 65b, the locking cylinders 63a and 63b engage respectively in the two holes 67a and 67b, ensuring thus locking the dart in aligned position with the arrow foot. The distributing boom can then operate in lift mode.

The performance of the hoist in liftable mode are illustrated in Figure 7.

The inclination of the distributing arrow obtained during the alignment of the distributor arrow and corresponding to the position E is 7 ° above the horizontal. A range of more than 24 meters corresponds to the maximum range that one can get with this lifting gear. Hook height is more than 24 meters from the top of the pylon.

At position F, a maximum tilt of the arrow almost 80 ° is obtained. The minimum range is then 6 meters and the hook height is almost 42 meters.

To return to articulated working mode, two electromagnetic devices 69a, secured respectively of the two parts 62a and 62b, are actuated in order to allow total withdrawal of the two locking cylinders 63a and 63b holes 67a and 67b. The control device (1) of articulation with jack makes it possible to break the alignment of the dart with arrow foot.

To fully fold the hoist, first of all to place the distributing arrow in position of work in articulated mode and then bring the end 46 of the arrowhead 43 at position D corresponding to the span minimal. The arrowhead 43 is then housed between the two beams of the jib foot 31.

The next step is to release the tie rods 25. The arrowhead 31, framing the dart point 43, then tilts forward of the hoist and comes lean along the upper pylon 22, as is illustrated in FIG. 2. In fact, the articulation 26, supporting the boom foot 31, is placed at the front of the upper pylon. A joint 27, supporting the two punches 16, is placed at the rear of the upper pylon.

The folding of the pylon is illustrated in FIG. 3 at using a succession of superimposed views. To clarify the drawing, most of the distribution arrow in a folded and folded position on the upper pylon as described above has been removed in this figure.

As shown in Figures 2 and 3, the end of each of the punches 16, opposite to that carrying the pulleys 17, is mounted in articulation to a straightening sling 20, thus avoiding the tilting of the punches towards the rear of the machine, the sling being connected to a strut straightening 23. The top of the pylon is extended by two pieces 28 forming a stop for the two punches, thus avoiding their tilting towards the front of the lifting machine. Each beams of the jib foot 31 carries an easel 32 intended for straightening the boom. On each of these easels is a stop 33 based respectively on each of the punches, thus avoiding the tilting of the foot of arrow 31 towards the rear of the lifting device.

By actuating a double-acting cylinder 18 which rests on the pylon foot 21 and acts on a system of connecting rods 19, the pylon folds around a horizontal articulation 24 and tilts thanks to the presence of straightening struts 23. The straightening slings 20, each linked in hinge at the end of a punch 16, rotate these punches around the joint 27.

At the end of the folding process, all the elements of the hoist are horizontal, the pylon upper 22 resting on the pylon foot 21 and supporting the dart 41 framed by the two beams of the foot of arrow 31, the punches 16 and the straightening slings 20 being placed alongside these elements. This configuration is shown in Figure 5.

An additional advantage offered by the boom distributor whose boom foot is made up of two beams is obtained with a hoist having a pylon foldable. This is the space saving obtained when the machine lift is fully folded, allowing wide variety of transportation.

The fact that the dart 41 can be accommodated between the beams 31a and 31b of the jib foot 31 makes it possible to obtain a significant space saving in height. By the compactness of the hoist in the folded position, many transport possibilities are offered, none requiring the specific construction of a rolling chassis. The Figures 6a to 6c illustrate some of these possibilities.

According to Figure 6a, the folded hoist is placed on a carriage 71 and its carrying frame 11 is attached to the rear of a tractor 72. According to FIG. 6b, the lifting is laid on an articulated trailer 73 to a tractor 72.

According to FIG. 6c, the lifting machine is placed in a container 74 known as a "marine container" and of which the standard dimensions are 12040 millimeters for the length and 2450 millimeters for height. Previously and thanks to the presence of a vertical articulation 47, the counter-dart 42 has been folded in on itself, thus providing space saving this time in length. The container can then be transported in a conventional manner, for example on a flatbed trailer 75.

The hoist has been described above with a chassis carrier 11 resting on the ground. It is understood that can also be mounted, regardless of the type of pylon which compose it, on a rolling carrying chassis, possibly propelled.

Some of the benefits of using an arrow vending machine whose arrow foot has a slot allowing the accommodation of all or part of the dart have just been illustrated with a lifting machine the pylon is foldable. However, the same versatility and similar performances of the distributing boom are also obtained when replacing this folding pylon by a conventional tower or by a telescopic pylon.

In a second embodiment of the lifting machine, particularly advantageous when the pylon is a tower 29 as shown in Figure 9, the foot of arrow 31 consists of a single fork-shaped beam having a longitudinal slot 34 open at the end of the boom foot carrying the joint 45. The length of this slot is sufficient for the counter-dart 42 to be lodge there so as to allow alignment between the dart 41 and the boom foot 31. A locking device, similar to that (61) of the first embodiment can be optional and ensures alignment of the dart with the arrow foot.

Figure 10 shows the control device 1 of the articulation between foot of arrow and dart of a variant of the second embodiment. The two branches 31a, 31b of the fork have a transverse axis 2 around from which a cylinder 3 can pivot. The cylinder 3 is articulated axis 2 through one end 4 of cylinder cylinder 5. The rod of cylinder 6 is articulated at its free end by a pin transverse 7 to a system of two pairs of connecting rods 8a, 8b, 9a, 9b. Each connecting rod is articulated in rotation around axis 7 by one of its ends. The other end of connecting rods 8a, 8b is articulated at 10a on the counter-dart. The second end of each connecting rod 9a, 9b is articulated in 14a, 14b respectively to the branches 31a, 31b of the fork. When the rod 6 of the cylinder 3 enters the cylinder 5, the connecting rods come against each other and the dart just aligned with the arrow foot. Conversely, when the rod 6 comes out of the cylinder 5, the dart point folds down against the arrow foot.

Those skilled in the art will readily understand that the joint presented in Figure 10 can also be used in the first embodiment of the machine lifting, of which the jib foot consists of two beams. In this case, the length of the connecting rods and the rod cylinder is calculated so that when the cylinder rod is extended as far as possible from the cylinder, the dart is housed between the two beams of the boom foot, as is illustrated in figure 11.

Figures 12a, 12b and 12c schematically represent a third embodiment of the lifting machine. The pylon is a classic tower 29. At the top of the pylon is a first end 35 of a jib foot 31. The second end 37 of the boom foot has the shape of a prism. At the tip of the prism is articulated a rotating dart around a horizontal axis 45. This axis of articulation subdivides the dart respectively into a point of dart similar to the darts of the first two embodiments and in a counter-dart 49 which, seen in lateral elevation, also has a prismatic profile, whose apex angle is chosen so that the dart, by rotation around the joint 45 can come align with the boom foot as shown by FIG. 12b, the counter-dart 49 being placed against the end 37 in the form of a prism of the arrow foot.

Two variants of this joint and the device articulation command 1 are illustrated in FIGS. 13a and 13b. As shown in Figures 13a and 13b, the second end 37 of the boom foot is a beam having the profile of a prism. At the top of the prism is articulated in 45 a dart. In figure 13a, the counter-dart is consisting of two symmetrical branches 49a, 49b separated by a slit. The articulation device with 1 cylinder and a pair rods is housed in this slot.

In FIG. 13b, the counter-dart is constituted a single beam 49 of prismatic profile. A double system cylinders 3a, 3b and connecting rods 8a, 8b, 9a, 9b is placed symmetrically on either side of the counter-dart.

By comparing Figures 10, 13a and 13b, the man in the trade will easily understand that the three devices are functionally identical, although different in their structure, since the articulation of the Figure 10 includes a single cylinder acting on two pairs of symmetrical connecting rods, Figure 13a shows a single cylinder acting on a single pair of connecting rods moving at the inside of the slot between the two branches of the counter-dart and Figure 13b shows two identical systems and symmetrical connecting rods and jacks.

Figures 12a, 12b and 12c illustrate the three modes of work of the lifting device according to the invention. On each of these figures, the displacement of the end 46 of the tip of the dart is shown in dashed lines.

In FIG. 12 a, which represents a mode of work in articulated boom, end 46 essentially moves along a horizontal line 51 which rises only nearby from the maximum reach position. In Figure 12b, beyond from this maximum reach position, the arrow aligned rises in liftable mode along line 52 as is also illustrated in Figure 7. In Figure 12c is schematically represented the working mode in dart tilting: from the minimum reach position, the dart point is first moved in articulated mode, from so that its end 46 describes a trajectory horizontal to a position G. From this position G, the angle of the boom foot relative to the horizontal is kept constant by means of a compensation of the length of the tie rod 25, and, using the control device 1 of the cylinder joint (s), the dart is raised to describe an arc of circle 55 centered on axis 45, as illustrated in Figure 12c. The interest of this working mode is also illustrated by FIG. 12c, on which are shown schematically tall buildings in the background: This working mode allows you to move a load at relatively low altitude, practically at the horizontal, parallel to the facade of the building, then finally raise it, after rotation of the tower of the machine lifting, deposit the load on the top of the building, and this at a high range.

The articulation between arrowhead and dart can be carried out using many variants of the system of articulation with rods and jacks without leaving the framework of the invention. Figure 14a is a schematic representation in side view of this joint which can represent both the joint in Figure 10 and the joint of figure 13a or the articulation of figure 13b with regard to relates to the arrangement of the actuator 3 and the connecting rods 8 and 9. We note in particular in this figure 14a that one end 10 of the connecting rod 8 is articulated on the counter-dart.

The joint shown schematically in the figure 14b differs from the articulation shown in FIG. 14a in that the connecting rod 8 is articulated slightly more forward, the other side of the hinge pin 45, on the tip of dart.

FIG. 14c shows a variant in which the connecting rod 8 is articulated at 10 at the hinge pin 45. The free end of the cylinder rod is articulated at 15 on a middle part of the connecting rod 9 and not at the level of the articulation 7 between the connecting rod 9 and the connecting rod 8.

FIG. 14d shows an alternative embodiment of the Figure 14c, where the connecting rod 8 is articulated on the tip of dart.

Figure 14e shows another alternative embodiment in which the rod 8 is articulated much more forward 10 on the dart point; the whole system of connecting rods + cylinder is located below the hinge pin 45. The head of the cylinder rod is articulated at 15 in a median zone of the connecting rod 9, the jib foot has a recess (not shown in the figure) to accommodate the connecting rod and cylinder when the dart folds back against the arrow foot.

In FIG. 14f, the connecting rod 8 is also articulated in 10 clearly forward on the dart point. In this variant, it is the middle part of the connecting rod 9 which is articulated at the foot of the arrow, while the ends of the connecting rod 9 are articulated respectively at 7 and 14 at the connecting rod 8 and the cylinder head.

Figure 14g shows a joint in which the cylinder rod is articulated directly on axis 45 between point arrow and counter-dart, while the connecting rods 8 and 9 have a common joint 7 not at the end of the cylinder rod, but on the cylinder, near the point of out of the cylinder rod.

Note in the joints shown in the figures 14a, 14b and 14g, the presence of four axes of horizontal rotation / articulation while the articulations shown in Figures 14c, 14d, 14e and 14f show five axes of articulation.

It will also be noted that on all the joints shown in Figures 13a, 13b, 14a to 14g, the axis articulation 45 is arranged so that the point of dart can come back against the arrow foot, subject, with regard to the joints shown in Figures 14e and 14g, of a recess corresponding in the arrow foot or in the dart. Those skilled in the art will readily understand that all of the joints shown in Figures 14a to 14g for the third embodiment are adaptable mutatis mutandis to the first two embodiments.

It will also be noted that in FIGS. 12a-14g, the third embodiment of the dart carries an easel lift 50 located approximately at the base of the arrow foot / dart joint. It goes without saying that first and second embodiments of the lifting device can also be fitted with such an easel 50.

The work in lifting mode of each of the arrows distributors of the three previous execution modes described in the lifting device operates identically. A times the dart 41 and the arrow foot 31 aligned and this locked position, pulling on the tie rods 25, for example using a winch placed on the turret 12 and not shown in the drawing, we gradually note the distributor arrow. The different amplitudes likely to be obtained, represented in FIG. 7 for the first mode of execution, are obtained in a similar way for other modes of execution.

Such performances are comparable to those usually obtained with jib cranes operating only in lift mode.

Claims (12)

Articulated lifting and handling equipment with articulated and lifting distributing jib, comprising a pylon (21, 22, 29), a jib foot (31, 31a, 31b) articulated in rotation at its first end (35) at the top of the pylon, a dart (41) articulated in rotation at the second end (36, 37) of the jib foot, said dart comprising on either side of its articulation axis (45) at the jib foot respectively a point of dart (43) and a counter-dart (42, 49, 49a, 49b), an arrow retaining assembly comprising at least one punch (16) and a jib tie rod (25), and at least one articulation cylinder (3, 3a, 3b) with double effect connecting the arrow foot to the dart, determining the angle between arrow foot and dart, characterized in that said second end of the arrow foot and the counter-dart have conjugate shapes allowing the dart tip to come into aligned position with c the arrow foot. Machine according to claim 1, characterized in that the arrow rod (25) is connected to the dart tip (43) by passing through at least one lifting bridge (50) integral with the dart. Machine according to claim 2, characterized in that the lifting bridge (50) is arranged substantially at the junction between the counter-dart (42, 49, 49a, 49b) and the dart point (43). Machine according to one of Claims 1 to 3, characterized in that the counter-dart (49, 49a, 49b) and the second end (37) of the jib foot have prismatic profiles and come into contact with one another. other when the boom foot and dart are aligned. Machine according to one of claims 1 to 3, characterized in that the second end (36) of the jib foot has the shape of a fork with two branches (31a, 31b) and that the counter-dart (42) comes lodge in the space (34) between the two branches. Machine according to one of claims 1 to 3, characterized in that the jib foot consists of two parallel beams (31a, 31b) and that the counter-dart (42) is received in the spacing (34) between the two beams. Machine according to one of the preceding claims, characterized in that the jib foot (31) and the dart (41) are connected by two identical articulation jacks (3a, 3b), mounted symmetrically with respect to the vertical plane of symmetry of the arrow. Machine according to one of the preceding claims, characterized in that the articulation cylinder or cylinders (3, 3a, 3b) directly connect the jib foot to the counter-dart. Machine according to one of claims 1 to 7, characterized in that the articulation cylinder or cylinders directly connect the boom foot and the dart point. Machine according to one of Claims 1 to 7, characterized in that each articulation jack (3, 3a, 3b) connects the jib foot (31) and the dart (41) by means of two connecting rods (8 , 8a, 8b, 9, 9a, 9b). Machine according to claim 10, characterized in that said connecting rods are articulated to one another and to the jack by the same axis of rotation (7). Distributor jib lifting device according to one of claims 5 to 7, characterized in that it comprises a blocking device comprising, on the one hand, two parts (62a, 62b), integral with the jib foot (31) and arranged opposite each side of the slot (34), each of said parts being equipped with a sliding locking cylinder (63a, 63b), and, on the other hand, a counterpart (66 ), integral with the counter-jib (42) and having bevelled side faces each comprising a bore (67a, 67b), the assembly being arranged so that the cylinders (63a, 63b) can cooperate respectively with each of the holes during the alignment of the dart with the boom foot.

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