FR2659073A1 - Device and method for lifting, supporting and handling loads - Google Patents

Abstract

This device is noteworthy in that it consists of at least two mobile and stable units (U) each formed of a base element (1) resting on the ground and several telescopic elements (2) (3) capable of being moved vertically and in a decomposed manner, by an operating member (4) built into the said base element; the last telescopic element (3) of each unit carrying, at its upper end, a bearing and fastening sole plate (3c) for one or more structures (P) for connecting the units together and bearing the load.

Description

 Device and method for lifting, supporting and handling loads.

 The object according to 1. invention relates to the technical sector of lifting devices in general.

 According to the invention, we wanted to make a simple, robust and space-saving device, easy to implement for lifting heavy loads, possibly moving them or even to support various constructions, this has varying heights.

To this end, and according to a first characteristic, the device is constituted by at least two mobile and stable units each formed by a basic element bearing on the ground and telescopic elements capable of being moved vertically and in a manner broken down by a member. control integrated into 1 said basic element; the last telescopic element of each unit being arranged to receive a support structure and fixing of load-bearing spacer beams
According to another characteristic, each unit has two telescopic elements With multiple positions relative to each other, said positions being ensured after action of the control member by pinout by means of pairs of pins passing through openings made in a regularly spaced manner in the height of the elements, in horizontal alignment two by two and along two opposite faces of said elements.

According to another characteristic, the last telescopic element has a plurality of pairs of cylindrical orifices produced in a regularly spaced manner in its height in alignment two by two and on two opposite faces to be crossed by pairs of pins of cylindrical section intended to serve support and thrust plane of the control member.

 According to another characteristic, the displacement decomposes in height of the telescopic elements of each unit is produced by a jack 9 built-in non-return valve fixed in the base element and whose thrust head of its piston is in support either under the sole of support and fixing of the structure, either under the pins of the last telescopic element 1, the elevation of the supporting structure being carried out in an equal and simultaneous or unequal manner and successively for each unit.

According to another characteristic, the method of lifting the telescopic elements breaks down as follows
- raising of the last telescopic element by the integrated jack to the desired height
- first pinout of the last telescopic element relative to the element in which it slides;
- retraction of the cylinder rod to the retracted position
- second pinout of the last telescopic element above the retracted piston head
- ~ actuation of the jack whose piston head rests under the pins of the second set causes the last element and the intermediate element connected by the first pinout to said last element.

 These characteristics and others will become apparent from the description which follows.

To set the subject of the invention without however limiting it, in the accompanying drawings
FIG. 7 is a front view illustrating a lifting device according to the invention in the deployed position,
- Figure 2 is a sectional view on a larger scale illustrating a lifting unit in the rest position.

 - Figure 3 is a partial perspective view showing the different components of a lifting unit.

FIG. 4 is a sectional view taken along line 4-4 of FIG. 3,
- Figure 5 is a sectional view taken along line 5-S of Figure 4.

 - Figure 6 is a partial sectional view on a large scale showing the pinout of the telescopic elements.

 - Figures 7, 8 and 9 are sectional views illustrating the different phases of deployment of the telescopic elements.

 In order to make the object of the invention more concrete, it is now described in nonlimiting embodiments illustrated in the figures of the drawings.

 Throughout the following description, the constitution of c is defined for each unit (U), it being understood that a device according to the invention comprises at least two units joined together by a support structure (P) as shown in FIG. 1, Depending on the application given to this device and the load to be lifted, it is possible to use more than two units connected together by load-bearing structures.

 Each unit comprises a basic element (0) and at least two telescopic elements (2) (3).

 The element (0) has a T shape with, for the support on the ground, a profile (1a) of the type with an H section, for example, in which a vertical sleeve (1b) is embedded in the middle. '' one or more openwork sections or not forming a regular polygon (square in particular). Side jambs (1c) secured to the ends of the profiles (la) and possibly ds gussets (1d) consolidate the basic element. Note that the legs (1c) can constitute a staircase (1e) for access to the upper end of the base element.

 The support on the ground can be fixed (base, sole ...) or as illustrated, rolling. For this purpose, rollers (1f) in any number are mounted for free rotation in the lower part of the profile (1a).

 As illustrated in Figure 1, the profile (1a) may be parallel to the spacer beam (P) right part of the figure, or perpendicular to said beam-spacer, left part of the figure.

 Inside the sheath (1b) is fixed vertically the control member of the telescopic elements. In the example illustrated, this member is a hydraulic cylinder (4) with incorporated non-return valve and whose barrel (4a) extends approximately to the upper end of the sleeve; its piston rod (4b) being terminated by a pusher head (4c).

 Between the sheath (1b) and the jack t4) are slidably mounted preferably by lubrication, the telescopic elements (2) (3) of the same profile in section as the sheath. Said elements have manier9 regularly spaced in their height pairs of openings (2a) (3a) made in horizontal alignment on two opposite faces to be crossed by pairs of pins (5) intended to secure the elements (2) and < 3) in their relative displacements, as we will see later.

Note that the openings C2a) (3a) can be circular or oval, as can the pins (5),
The telescopic element (3) also has a plurality of pairs of circular orifices (3b) regularly distributed in its height along two opposite faces and with a spacing (el) smaller than the spacing (e2) of the openings (3a) so that pairs of cylindrical pins (6) engaged in these orifices serve as support for the head (4c) of the jack (4)
Finally, the upper end of the element (3) forms a sole (3c) to receive by bolting or otherwise the supporting structure (P) connecting two units. This structure can for example be a reinforced I-profile and can optionally be fitted to serve as a guide rail for a hoist type hoist or similar,
The operation of the device thus constituted by at least two units and a supporting structure will now be described, with reference to Figures 2, 7, 8 and 9 of the drawings.

 The unit shown in Figure 2 is in the low position or rest position, that is to say that the piston rod (4b) is retracted and the telescopic elements (2) and (3) are supported by their underside on the profile (la).

The first phase consists in deploying the element
C3) by controlling the jack (4), the head (4c) of which rests under the sole (3c) of said element. The elevation of this element (3) can be carried out at will between a minimum and a maximum determined by the openings (2a, 3a).

 In a second phase, when the desired height is reached, the pins (5) are introduced into said openings (2a) C3a3 opposite the telescopic elements (2) (3), in order to secure these elements together (Figure 7).

The third phase consists in retracting the piston rod of the jack (4) until its head (4c) is placed between the pins (5) and the orifices (3b) of the element (3) located immediately above above Cfigure 8). We then engage (phase 4) the pins (6) in the holes (3b) to form support zones for the head (4c) of the jack (Figure 8) which is then actuated (fifth phase) to simultaneously raise the elements (2) and (3) interconnected by pins (5) as shown in FIG. 9,
By the telescopic development of elements (2) and (3), we obtain a significant lifting height (of the order of about 6 meters) with a single control member integrated in the sheath.

As an indication, we can lift loads of around 160 tonnes
The high or deployed position of the device is maintained by the jacks (4), but additional security can be provided in the form of complementary pinouts (not shown) between the sleeve (1b) and the element (2). can order all. cylinders simultaneously or successively to obtain equal or unequal lifting.

 In addition to the advantages set out above, we should also highlight the many possible applications of the device: supporting structures, lifting heavy loads, handling suspended loads

Claims (1)

 CLAIMS -1- Device for lifting, supporting and handling loads, characterized in that it consists of at least two mobile and stable units (U), each formed of a basic element (1) bearing on the ground and several telescopic elements (2) (3) capable of being moved vertically and in a decomposed manner by a control member (4) integrated in said base element; the last telescopic element (3) of each unit carrying at its upper end a sole (3c) for support and fixing for one or more structures (P) connecting between the units and load carriers. -2- Device according to claim 1 characterized in that each unit has two telescopic elements (2) (3) with multiple positions relative to each other; said positions being ensured after action of the control member (4); by broaching by means of pairs of pins (5) passing through openings (2a) (3a) produced in a regularly spaced manner in the height of the elements, in horizontal alignment two by two and along two opposite faces of said elements. -3- Device according to claim 2 characterized in that the openings ((3a) of the telescopic elements (2) (3) are preferably ovalized and receive pins (5) of the same section or circular section. -4- Device according to claim ï characterized in that the last telescopic element (3) has a plurality of pairs of cylindrical orifices (3b) produced in a regularly spaced manner in its height in alignment two by two and on two opposite sides for be crossed by pairs of pins (6) of cylindrical section intended to survive from the support and thrust plane for the control member C5) -5- Device according to claims 1, 2, and 4 together, characterized in that the displacement decomposes in height of the telescopic elements (2) (3) of each unit is carried out by a jack (4), with an incoporated non-return valve, fixed in the basic element (1) and of which the thrust head ( 4c) of its piston (4b) is supported either on the sole (3c) for supporting and fixing the structure (P), or under the pins (6) of the last telescopic element (3); the elevation of the supporting structure being carried out equally and simultaneously or unevenly and successively for each unit. -6- Device according to claims 2 and 4 together characterized in that the pairs of orifices C3b) have a horizontal spacing (el) less than the horizontal spacing Ce2) of the pairs of openings (2a) (3a) to cooperate with the head (4c) of the jack (4). -7- Device according to claim 1, characterized in that the basic element (1) has a T-shape with a profile (1a) of stable support on the ground, a vertical sleeve (1b) housing the member control (4) and the telescopic elements (2) and (3) and reinforcement means (1c) forming a staircase. -8- Device according to claims 1 and 7 together, characterized in that the profile (1a) for supporting the ground receives free rotation in its lower part of the rolling means (the) in number which conch. -9- Device according to claim 1 characterized in that the telescopic elements (2) (3) are held in the deployed position by the cylinder (4) and by additional pinouts between the base element (1) and the first element telescopic (2).  -0O- Method of lifting loads by the device according to claim 1 characterized by the following phases - raising the last telescopic element (3) by the jack (4) integrated to the desired height - first pinout (S) of the last telescopic element (3) relative to the element (2) in which it slides - retraction of the cylinder rod (4b) to the retracted position - second pinout (6) of the last telescopic element (3) above the piston head (4c) retracts; ; - actuation of the jack (4), the piston head (4c) of which rests under the pins (6) of the second set drives the last element (3) as well as the intermediate element (2) connected by the first pinout (5) audit last element (3).