TEXT OF THE DESCRIPTION The present invention relates to the field of mechanical engineering, and in particular to the field of vehicle lifts. More particularly, it relates to a scissors- type lift which has a reduced height in the fully closed position, and which for this reason is defined as"low- level".

In the field of mechanical engineering, various types of lifts are known, which can lift vehicles to a required height such as to be able to work easily using the lifts, for execution of operations of ordinary and extraordinary maintenance. Included amongst all the types of vehicle lifts, there are those of the"scissors"type.

Substantially, in these lifts, there is generally an oleodynamic cylinder, which imparts its thrust to a scissors-type articulation, with arms which are connected to a lifting runway or platform, thus giving rise to upward thrust which can support a load. Lifts of this type are mostly used"recessed", i. e. the lift is embedded in the ground by means of appropriate foundations, such that there is no obstruction on the ground, and in order to obtain more space which can be used in a working environment.

The disadvantage of this lift is that it requires relatively deep foundations. The reason for this is that in order to be able to open the scissors-type articulation, the oleodynamic cylinder must have good inclination, so that it can impart its upward thrust. Correspondingly, a lift is obtained which, in the zero position, i. e. when it is fully closed, has a height which is generally no lower than 250 mm. Accordingly, in order to embed this type of

lift, it is obviously necessary to have a foundation in the floor with a depth of no less than 250 mm.

However, in many working environments, conditions are such that it is not possible to produce such a deep foundation, since there is a floor which is less thick than the height of the foundation required in order to embed the scissors-type lift.

The object of the present invention is to eliminate this disadvantage by means of a"low-level"scissors-type lift, which has a height no greater than 120 mm. This is possible by means of use of a lever-type kinematic mechanism as illustrated hereinafter.

The low-level scissors-type lift according to the present invention has the characteristics specified in the independent claim 1. Further specific characteristics of the invention are indicated in the dependent claims.

There now follows a detailed description of the invention, provided purely by way of non-limiting example, to be read with reference to the attached illustrative drawings, in which the various figures show the following: Figure 1 shows the innovative kinematic mechanism according to the present invention; Figure 2 shows a single-scissors-type lift according to the present invention, in an intermediate lifting position; and Figure 3 shows a double-scissors-type lift, in a condition substantially of complete extension, or of maximum lifting.

It is apparent that the same reference numbers in the various figures are used to indicate the same parts, or components which are functionally equivalent.

In addition, for the sake of greater clarity, and to avoid limiting unduly the scope of the invention, the lift is shown substantially"bare", i. e. without any runway or arm in order to support the vehicle, and without any other accessory, for example safety devices according to the known art, which are not directly relevant to the invention.

With reference initially to figure 1, the kinematic mechanism 12 consists of a semi-fixed lever 14 (the reason for the latter being"semi-fixed"will become apparent hereinafter), and of a mobile, or"impetus"lever 16. The semi-fixed lever 14 and the mobile lever 16 are hinged or pivoted relative to one another at the point C, such as to permit rotation between them. At its end B opposite the point C, the semi-fixed lever 14 is pivoted relative to an arm 22 of the scissors-type articulation; substantially the point B is a fixed anchorage point, which acts as a stop for the entire kinematic mechanism. Onto a fulcrum or point X at the end of the mobile lever 16, there is secured an oleodynamic cylinder 18, the direction of thrust of which in the starting position (figure 1) is towards the anchorage point B (force F).

At their fulcrum point C, the lever 14 and the lever 16 are shaped such as to have a respective bevelled or inclined surface 14'and 16'.

As can be seen clearly in figure 1, as well as in the other figures, the lift 10 according to the invention comprises means 20 which can prevent downward rotation of the semi-fixed lever 14 at the start of lifting, and thus define the position of starting or rest of the kinematic mechanism. Advantageously, these means are in the form of a plate 20 which is secured (i. e. welded) to the arm 22 of the lift 10. In another arm 24 of the lift 10, which is

pivoted relative to the arm 22, there is provided a slot 26 in which the fulcrum X moves.

The kinematic mechanism functions as follows.

In order to obtain a lift 10 with a low profile (with a maximum height of 120 mm), the unit 18 which generates the thrust, and in this case an oleodynamic cylinder 18, must be positioned such that its dimensions do not exceed the height of the profiled section itself. Thus, initially, the oleodynamic cylinder 18 assumes a position with an angle of 0 relative to the horizontal line of the profiled section. However, the rod of the oleodynamic cylinder 18 acts along a direction of thrust which is indicated by the force F, and is slightly spaced from the fulcrum point C: the force F can thus create torque relative to C, which in turn is sufficient to rotate the lever 16.

However, in order to be able to open the scissors, which are the support structure of the lift, it is necessary to deflect the thrust force F of the cylinder from the horizontal position to the vertical position, and this process is carried out by the lever-type kinematic mechanism according to the present invention.

In figure 2, the lower part of the oleodynamic cylinder 18 is secured to the wide arm 22 of the scissors, and its upper part is secured to the narrow arm 24 and to the lever 16. The semi-fixed lever 14 remains in its initial position until the oleodynamic cylinder 18 acts directly, and has thus completed its path in the slot 26 on the inner arm of the scissors; at this point the semi-fixed lever 14 is drawn by the mobile lever (again see figure 2), until the maximum height is reached (see figure 3).

It is apparent that many modifications, adaptations and substitutions of parts can be made to the emodiments described in detail and illustrated in the attached illustrative drawings, using alternatives which are functionally equivalent, without departing from the protective context of the following claims.