FR2994169A1 - Hoisting machine i.e. self-propelled mini-crane, for use in e.g. factories to hoist load, has deformation unit arranged to pivot rod around axle while varying angle between values attained in folded and deployed positions - Google Patents

Abstract

The machine (1) has a path widening unit comprising deformable side shears (8) and a deformation unit to deform the shears between folded and deployed positions. The shears have a rod (10) extended from a side (15)/an upper portion (17) of a frame (2) and another rod (12) rotatively articulated on a support element (6) of a bearing unit and on the former rod around an axis (X3). The rods form an angle (alpha). The deformation unit is arranged to pivot the latter rod relative to the former rod around the axle while varying the angle between minimal and maximum values attained in the positions.

Description

The present invention relates to a lifting machine with variable track, including a mini-crane. The invention is particularly applicable in areas with strong spatial constraints, inside or outside, for example in warehouses or factories, or on urban sites, requiring work with arrow on the side. There are traditionally two solutions for lifting a load on the side. A first solution is to use a large tonnage and bulky device to withstand without a load on the side, but the size and mass of these devices do not allow to use in environments with high spatial constraints . A second solution is to use a machine equipped with stabilizers locking it to the ground, but preventing any displacement load suspended on the side. Some lifting machines offer solutions to increase the stability of the machine while allowing its movement. These solutions are based on principles of widening the track of the hoist, that is to say the distance between the wheels of the same axle, for example by means of telescopic beams arranged under the chassis, between the wheels of the machine. However, traditional lane widening systems have a fairly limited amplitude, the lane extension ratio rarely exceeding 1.2, allowing for example to go from lm lane to lane of 1.2 m. . In other words, the path is rarely increased beyond 20% of its minimum value. The benefit in terms of stability is consequently limited, and does not allow to consider the movement of the hoist while a load is suspended at the end of the boom, whatever the position of the latter for example from a first workstation to a second workstation of the same site. Furthermore, the lifting gear must have the smallest transverse space possible to facilitate their transport, or to increase their mobility in a theater of operations. However, traditional channel widening systems often have a large transverse bulk. Finally, the lifting gear is intended to evolve in environments that may have significant spatial constraints. However, the known channel widening systems often offer the possibility of widening the lane according to a number of predetermined lane values. In other words, the traditional systems are limited to two or three positions corresponding to only two or three possible channel values, which does not always make it possible to adapt to an environment which would impose as value of a possible path a value between these predetermined values. Also the present invention aims to overcome all or part of these disadvantages by providing a lifting machine with variable track, minigrue type, offering the ability to move while carrying a load whatever the position of the arrow, with a variable track large amplitude and adjustable in an infinity of possible values, while being of great transverse compactness for a minimum of space and greater maneuverability. For this purpose, the subject of the present invention is a hoist, in particular of the mini-crane type, comprising a chassis, rolling means arranged on each side of the chassis for moving the hoist on a surface, and channel widening means for varying the track of the hoist, characterized in that the channel widening means comprises a kinematic assembly of deformable side scissors in a plane substantially perpendicular to the axis 20 longitudinal axis X of the hoist, and deformation means scissors between a folded position in which the path of the hoist is minimal and an extended position in which the path of the hoist is maximum, the scissors comprising at least one pair of connecting rods arranged on one side of the chassis and above the rolling means to release the space under the chassis and between the rolling means, each pair of connecting rods both consisting of a first connecting rod, extending laterally from one side or an upper portion of the frame, and a second connecting rod, articulated in rotation on a support member of the rolling means about an axis X2 and on the first connecting rod about an axis X3, the first connecting rod and the second connecting rod forming an angle α between them, and the deformation means being arranged to pivot the second connecting rod relative to the first connecting rod about the axis X3 in varying the angle a between a minimum value reached in the folded position and a maximum value reached in the deployed position. Thus, the hoist according to the invention has an advantageous kinematics in deformable lateral scissors that make it possible to overcome any conventional axle systems bulky space under the chassis and between the rolling means and the chassis . Therefore, the hoist according to the invention offers great compactness in the folded position, which gives it great maneuverability and ease of transport. The kinematic assembly in deformable lateral scissors also allows to have a large amplitude of the channel. Thus, the stability of the machine can be substantially increased (the rolling means apart forming both support points and counterweights); the hoist according to the invention, because of this great stability, can move while lifting a load, and whatever the position of the arrow. Finally, the kinematic assembly of deformable side scissors offers the possibility of an infinity of possible channel values between the maximum path reached in the deployed position and the minimum path reached in the folded position. This allows the hoist to have the greatest possible route value, given the spatial constraints imposed by the environment in which it evolves. Advantageously, the axis X3 is arranged above the segment connecting the axes X1, X2 to release the space under the deformable lateral scissors. According to one embodiment, the angle α is acute, and preferably less than or equal to 45 °, in the folded position, and obtuse in the deployed position. According to one possibility, the only link between the second link and the chassis, except where appropriate the means of deformation, is formed by the first connecting rod. In other words, apart from the deformation means, the only kinematic link between the second connecting rod and the chassis is provided by the first connecting rod. According to one embodiment, the deformation means comprise, for each pair of connecting rods, a jack articulated with respect to the frame around an axis X4, a lever articulated with respect to the jack about an axis X5 and on the first connecting rod around an axis X6, and a transmission member arranged to transmit the rotational movements of the lever about the axis X6 to the second link in order to vary the angle a. Thus, the combination of a lever with the kinematic assembly made of deformable scissors makes it possible to dispense with the use of an oversized jack having to withstand significant stresses, the jack having to support in practice the deformable lateral scissors and the rolling means, which can be suspended from the scissors when they are spaced apart and close together, and whose mass may advantageously be important to counterbalance in the deployed position. In particular, the use of a lever cooperating with the side scissors makes it possible to use a cylinder with a short stroke (for example of the order of 100 mm) while retaining the benefit of a substantial widening of the track. According to one possibility, the couple of connecting rods, the lever and the transmission member delimit between them a parallelogram X3, X2, X7, X6 offset by a distance corresponding to the spacing X1, X6 with respect to the frame and deformable in a plane substantially perpendicular to the longitudinal axis X of the hoist. Thus, because of the deported nature of the deformable parallelogram thus formed, the widening of the track can be consequent, and moreover, the rolling means remain stable in position during their spacing or their approximation, their axis of rotation remaining substantially horizontal. According to another characteristic of the hoist according to the invention, the lever is articulated on the support member of the rolling means about an axis X7, the transmission member merging with the support member. rolling means. According to one possibility, the lever is connected to the first connecting rod by an axis X6 pivot connection arranged on an intermediate portion of the lever between a distal end and a proximal end of the lever, the distal end of the lever being connected to the jack by an X5 axis pivot connection. Thus, the center distance X5, X6 forms a lever arm which can be adapted to use a cylinder of small amplitude, not oversized, and advantageously working under load in compression with an advantageous inclination, as close as possible to the vertical axis. Z of the hoist. This contributes to a substantial widening of the track and makes it possible to use large mass rolling means to counterbalance and provide more stability to the hoist according to the invention. According to one embodiment, the axis X2 connecting the second connecting rod to the support member of the rolling means is arranged vertically above the center of gravity of the assembly formed by the support member and the means bearing supported by the support member.

In other words, the axis X2 connecting the second connecting rod to the rolling means is arranged in the vertical plane including the center of gravity of the rolling means and perpendicular to the transverse axis Y of the hoist, above this center of gravity. Thus, the rolling means remain in a stable position when they are moved apart or close together, even when the rolling means are raised and suspended from the deformable lateral scissors and when their only connection with another element consists of the pivot connection or links. X2 axis connecting them to the second or second connecting rods.

According to one embodiment, the first connecting rod and / or the second connecting rod are each formed by two substantially parallel rods articulated around the same axes of rotation. In other words, the first connecting rod, the second connecting rod and / or, if appropriate, the lever can be doubled for greater rigidity, thus to better resist bending. This allows for example to increase the mass of the rolling means so that they counterbalance in the deployed position and they thus contribute to increasing the stability of the hoist. According to a possible characteristic, the track widening means and the rolling means are substantially symmetrical with respect to a median plane perpendicular to the transverse Y axis of the hoist. Thus, the stability of the hoist is increased. According to one embodiment, in the folded position, the rolling means are folded in contact with the frame thanks to the space released under each pair of rods. Thus, the hoist according to the invention offers a great compactness in the folded position, which is advantageous both in terms of maneuverability when the hoist moves itself from one place to another , and transport since the hoist is less bulky when it is to be transported, for example on a truck. According to one possibility, the lane extension ratio, corresponding to the ratio of the lorry track in the deployed position on the track of the hoist in the folded position, is at least 1.8 for example of the order of 1.9, and preferably greater than or equal to 2.

In other words, the pathway can be increased by at least 80%, and preferably by 100% or more. For example, the channel I may be of the order of 1.2m to 1.3m in the folded position, and of the order of 2.4m in the deployed position. According to one embodiment, the rolling means correspond to tracks mounted on a track support supporting the axis X2 and, where appropriate, the axis X7. Thus, the tracks offer, in addition to the ability to travel over particularly rugged areas to further increase the workability of the hoist according to the invention, a substantially larger mass to counterbalance and further stabilize the machine 10 lifting when handling a load, especially when traveling with this load. According to one embodiment, the lifting apparatus comprises means for lifting the chassis, movable between a rest position in which the lifting means are at a distance from the surface on which the rolling means rest, to allow the moving the lifting apparatus on this surface, and an output position in which the lifting means press against this surface to lift the frame so as to maintain the rolling means at a distance from this surface and thus allow the enlargement or the narrowing of the track of the hoist. Advantageously, the lifting means comprise at least two hydraulic legs mounted movable in substantially vertical translation under the frame. According to one possibility, the axis X3 is arranged above a horizontal plane including the axis, among the axes X1, X2, situated vertically the highest. According to another possible characteristic, a hydraulic power unit is embedded in the chassis of the hoist. It can be envisaged that the displacement means comprise a single jack for two pairs of rods arranged on either side of the frame. Advantageously, this jack can be arranged substantially horizontally. Moreover, this jack can be articulated at one end to the second connecting rod of one of the couples of connecting rods and at another end to the second connecting rod of the other pair of connecting rods, so that this jack enables a synchronous deformation. side scissors formed by the two pairs of rods. Other features and advantages will become clear from the following description of an embodiment of a hoist according to the invention, given by way of non-limiting example, with reference to the appended drawings in which: FIGS. 1 and 2 are side views of a hoist according to one embodiment of the invention, FIGS. 3 and 4 are rear views of a hoist according to one embodiment of the invention. the invention in two operating positions. Figures 1 and 2 show a hoist 1 according to one embodiment of the invention, self-propelled mini-crane type. It is specified that the description is made with respect to a Cartesian frame of reference related to the lifting gear 1, the X axis being oriented in the longitudinal direction of the lifting gear 1, the Y axis being oriented in the transverse direction of the lifting gear 1, and the Z axis being oriented in the vertical direction of the lifting gear 1. The orientations, directions, longitudinal, transverse, vertical, forward, backward, lateral movements are thus defined with respect to this reference frame. The lifting gear 1 comprises a frame 2, and rolling means arranged on each side of the frame 2.

The rolling means may comprise, as shown in FIGS. 1 to 4, tracks 4, and be mounted on a support member 6, here corresponding to a crawler support. The lifting apparatus 1 also comprises means for widening the track intended to vary the track of the lifting apparatus 1, that is to say the distance between the rolling means, in this case the distance I between the tracks 4. As is illustrated in FIGS. 3 and 4, the channel widening means comprise a kinematic assembly made of lateral scissors 8 deformable in a plane substantially perpendicular to the longitudinal axis X of the vehicle 1 lifting. The lifting apparatus 1 here comprises four pairs of deformable lateral scissors 8, two on each side of the frame 2, as can be seen in FIGS. 1 and 2. Each pair of scissors 8 comprises at least one pair of connecting rods 10, 12 , arranged on one side of the frame 2, above the tracks 4 to 5 release the space under the frame 2 and between the tracks 4. Each pair of rods 10, 12 comprises a first rod 10, extending laterally from a side 15 or an upper portion 17 of the frame 2, for example articulated in rotation on the frame 2 by a pivot connection of axis X1, and a second connecting rod 12, articulated in rotation on the support member 6 10 of the tracks 4 by a pivot link X2 axis and articulated by a pivot link axis X3 on the first rod 10. Note that neither the first rod 10 nor the second rod 12 do not extend under the frame 2. The axis X3 can be advantageously arranged above the segment connecting the X axes 1, X2 to release the space under the deformable lateral scissors 8. The axis X3 can in particular be arranged above a horizontal plane including the axis, among the axes X1, X2, located vertically the highest. It will be noted that the only link between the second connecting rod 12 and the chassis 2 is formed by the first connecting rod 10, apart from the deformation means which will be described in more detail below. As can be seen in FIGS. 3 and 4, the first connecting rod 10 and the second connecting rod 12 form an angle α between them. The lifting gear 1 also comprises means for deforming the scissors 8 between a folded position, visible in FIG. 3, in which the track I of the lifting gear 1 is minimal, for example of the order of 1200. mm to 1300 mm, and an extended position, visible in Figure 4, in which the track l 'of the lifting gear 1 is maximum, for example of the order of 2400 mm. Thus, it will be noted that the lane extension ratio of the lifting gear 1 is at least 1.8, and may be of the order of 1.9 or greater than or equal to 2. In other words, the route can be increased by at least 80%, and preferably by 100% or more. The deformation means comprise, according to the example of FIGS. 1 to 4, for each pair of connecting rods 10, 12, a jack 14, fed for example by a hydraulic power unit embedded in the frame 2, a lever 16, and an element 18 of transmission of forces between the lever 16 and the second connecting rod 12, arranged to pivot the second connecting rod 12 relative to the first connecting rod 10 about the axis X3 by varying the angle a between a minimum value reached in the folded position and a maximum value reached in the deployed position. As can be seen in FIGS. 3 and 4, the angle α may be acute in the folded position, and preferably less than or equal to 45 °, and obtuse in the deployed position. The cylinder 14 can be hinged to the frame 2 by a pivot link axis X4. The lever 16 is here hinged on the cylinder 14 by a pivot axis connection X5 and on the first connecting rod by a pivot link axis X6. According to the embodiment shown in Figures 1 to 4, the lever 16 is also articulated on the support member 6 of the tracks 4 by a pivot link axis X7, so that the transmission member 18 here corresponds to practical to the support member 6 of the tracks 4.

The pair of rods 10, 12, the lever 16 and the transmission member 18 may be arranged relative to each other to form a parallelogram X3, X2, X7, X6, offset by a distance corresponding to the distance between the axes. X1, X6 relative to the chassis 2 and deformable in a plane substantially perpendicular to the longitudinal axis X of the lifting machine 1.

It will be noted that the X6 axis pivot connection may be arranged on an intermediate portion of the lever 16, that is to say on a portion of the lever 16 between a distal end 20 and a proximal end 22 of the lever 16. the distal end 20 being connected to the cylinder 14 by the X5 axis pivot connection, to form a lever arm corresponding to the center distance X5, X6.

Advantageously, the axis X2 about which is articulated the second connecting rod 12 relative to the support member 6 of one of the tracks 4 is arranged vertically above the center of gravity of the assembly formed by the support member 6 and the track 4 which it supports, so that, when they are suspended from the second connecting rod 12, the support member 6 and the track 4 which it supports remain in a position of stable equilibrium corresponding to their position of use when the caterpillars 4 are in contact with the ground. As can be seen in FIGS. 1 and 2, the first connecting rod 10 and / or the second connecting rod 12, but also possibly the lever 16 can be doubled, that is to say formed respectively of two connecting rods or two levers 35 substantially parallel and articulated around the same axes of rotation.

2 994 16 9 10 The lifting gear 1, in particular its lower part including the scissors 8, the jacks 14, the levers 16, the tracks 4 and their support member 6, or even the frame 2, is substantially symmetrical with respect to at a median plane perpendicular to the transverse Y axis of the hoist 1, that is to say a vertical plane including the longitudinal axis X of the hoist 1. As can be seen in FIG. 3, the support members 6 of the tracks 4 can be folded against the frame 2 in the folded position, in particular thanks to the space released under each pair of connecting rods 10, 12. It will be noted that, to allow widening or narrowing of the path of the lifting gear 1, the latter may include means for lifting the frame 2, such as hydraulic legs 24. The hydraulic crutches 24 are movable between a rest position in which they are at a distance from the surface on which the tracks 4 rest, so as not to hinder the movement of the lifting gear 1 on this surface, and an exit position in which hydraulic crutches 24 are deployed and press against this surface to lift the frame 2 and keep the tracks 4 away from this surface, to allow to separate or bring the caterpillars 4 then suspended scissors 8. Of course, the The invention is in no way limited to the embodiment described above, this embodiment having been given by way of example only. Modifications are possible, particularly from the point of view of the constitution of the various elements or by the substitution of technical equivalents, without departing from the scope of protection of the invention. Thus, instead of including a lever 16 and a transmission member 18, the deformation means could comprise a jack 14 hinged to the frame 2 and directly to the second rod 12. Thus, instead of being confused with the body 6, the transmission member 18 could correspond to a connecting rod connecting the lever 16 and the second connecting rod 12; the support member 6 could then only be attached to the second connecting rod 12 via the axis pivot connection X2.

Claims (10)

REVENDICATIONS1. Lifting apparatus (1), in particular of the mini-crane type, comprising a chassis (2), rolling means arranged on each side of the chassis (2) for moving the machine (1) on a surface, and lane widening means for varying the path of the lifting apparatus (1), characterized in that the lane widening means comprise a scissor-shaped lateral kinematic assembly (8) deformable in a plane substantially perpendicular to the longitudinal axis (X) of the lifting machine (1), and means of deformation of the scissors (8) between a folded position in which the path of the machine (1) of lifting is minimal and a deployed position in which the path of the machine (1) lifting is maximum, the scissors (8) comprising at least a pair of connecting rods (10, 12) arranged on one side of the frame (2) and above the means for releasing the space under the chassis (2) and between the rolling means, each pair of connecting rods (10, 12) being composed of a first connecting rod (10), extending laterally from one side (15) or an upper portion (17) of the frame (2), and a second connecting rod (12), articulated in rotation on a support member (6) for rolling means around an axis (X2) and on the first connecting rod (10) about an axis (X3), the first connecting rod (10) and the second connecting rod ( 12) forming between them an angle (a), and the deformation means being arranged to rotate the second connecting rod (12) with respect to the first connecting rod (10) about the axis (X3) by varying the angle (a) between a minimum value reached in the folded position and a maximum value reached in the deployed position. 2. Lifting gear (1) according to claim 1, characterized in that the axis (X3) is arranged above the segment connecting the axes (X1, X2) to release the space under the scissors (8) lateral deformable. 3. Lifting machine (1) according to claim 1 or 2, characterized in that the angle (a) is acute, and preferably less than or equal to 45 °, in the folded position, and obtuse in the deployed position. 4. Lifting gear (1) according to one of claims 1 to 3, characterized in that the single link between the second connecting rod (12) and the frame (2), except where appropriate the deformation means, is formed by the first connecting rod (10). 5. Machine (1) according to one of claims 1 to 4, characterized in that the deformation means comprise for each pair of rods (10, 12) a jack (14) hinged relative to the frame (2) around an axis (X4), a lever (16) articulated with respect to the jack (14) about an axis (X5) and on the first link (10) about an axis (X6), and a member (10) 18) for transmitting the rotational movements of the lever (16) about the axis (X6) to the second link (12) to vary the angle (a). 6. Lifting gear (1) according to claim 5, characterized in that the pair of connecting rods (10, 12), the lever (16) and the transmission member (18) delimit between them a parallelogram (X3, X2). X7, X6) offset by a distance corresponding to the spacing (X1, X6) relative to the frame (2) and deformable in a plane substantially perpendicular to the longitudinal axis (X) of the machine (1) lifting. 7. Device (1) for lifting according to claim 5 or 6, characterized in that the lever (16) is articulated on the member (6) for supporting the rolling means about an axis (X7), the transmission member (18) merging with the support member (6) of the rolling means. 8. Device (1) for lifting according to one of claims 5 to 7, characterized in that the lever (16) is connected to the first connecting rod (10) by a pin pivot connection (X6) arranged on a portion intermediate lever (16) between a distal end (20) and a proximal end (22) of the lever (16), the distal end (20) of the lever (16) being connected to the ram (14) by a pivotal connection axis (X5). 9. Engine (1) for lifting according to one of claims 1 to 7, characterized in that the axis (X2) connecting the second connecting rod (12) to the member (6) for supporting the rolling means is arranged vertically above the center of gravity of the assembly formed by the support member (6) and the rolling means supported by the support member (6). 10. Lifting machine (1) according to one of claims 1 to 9, characterized in that the first connecting rod (10) and / or the second connecting rod (12) are each formed by two substantially parallel rods articulated around the same axes of rotation.