Patent Description:
The present invention finds its preferred, although not exclusive, application in firefighting vehicles. Reference will be made to this application by way of example below.

Rescue vehicles such as firefighting vehicles are usually provided with an extendable ladder assembly. Such ladder assembly is configured to vary its longitudinal extension in order to reach high or distant rescue points.

A preferred use of such ladder assembly for firefighting vehicles is to provide firefighting mixture to buildings on fire or to allow a cage hosting rescuers to reach apartments in buildings. Accordingly, the preferred, but not exclusive use, of such extendable ladder assembly is to provide a suitable vertical elongation to reach needed portions of a rescue point.

As said, since the main use of ladder assembly is to provide firefighting mixtures, they are equipped with water pipes.

In such known arrangement, the ladder assembly comprises a plurality of segments that are placed one within the other and extends telescopically to vary the ladder length. In such configuration, the water pipes, that are made rigid, are themselves realized telescopically, i.e. in segments that are each carried by a respective segment of the ladder assembly.

However, according to an example of known ladder assembly arrangement shown in <CIT>, the use of the aforementioned rigid tubes is impossible if it is requested to provide a further degree of freedom to the terminal portion of the ladder. Indeed, rigid water tubes would make impossible to move such terminal portion.

Existing ladder systems for special/rescue vehicles are disclosed in publications <CIT>, <CIT>, <CIT> or <CIT>.

In view of the above, the need is felt to improve existing ladder system to allow the use of rigid water tubes in an extendable ladder assembly layout with a movable terminal portion.

An aim of the present invention is to satisfy the above mentioned needs in a cost-effective and optimized manner.

The aforementioned aim is reached by a ladder assembly and a rescue vehicle as claimed in the appended set of claims.

The attached figures discloses a rescue vehicle <NUM>, in particular a firefighting vehicle, comprising a body <NUM> movably on ground G via a plurality of wheels <NUM> or any other equivalent traction means.

The vehicle <NUM> is provided with a ladder assembly <NUM> that is coupled by a support structure <NUM> to the body <NUM> of the vehicle. In particular, the support structure <NUM> may comprise a base <NUM>' rigidly carried by vehicle body, an intermediate portion <NUM>" carried in a turntable way by base <NUM>' and a connection <NUM>‴ portion rigidly carried by ladder assembly <NUM> and coupled via a movable connection 4a to the intermediate portion <NUM>".

As visible in <FIG> and as schematized in <FIG>, the ladder assembly <NUM> comprises a plurality of segments 5a, 5b, 5c, 5d, 5e that are telescopically coupled one with respect to the other, as described, for sake of example, in patent publication <CIT>. In the described embodiment, without any limitative meaning, reference will be made to a five-segments ladder, however such number may vary according to the needs and typology of the rescue vehicle.

Therefore, the vehicle extends along a longitudinal axis A and the ladder assembly <NUM> extends along a longitudinal axis B that may vary its position (see <FIG> and <FIG>, <FIG>) in function of the movements of the support structure with respect to longitudinal axis A. In particular, when in rest position, longitudinal axis A, B are parallel one with respect to the other and to the ground G, while in operation the longitudinal axis B tends to be inclined of an angle with respect to the ground G, i.e. being incident to longitudinal axis A.

The aforementioned segments 5a, 5b, 5c, 5d, 5e are at least partially arranged one within the other so that the first can be totally extracted from the second, the second from the third and consequently till the fifth segment that is coupled to the connection portion <NUM>‴.

Such movement may be achieved by dedicated actuators, such as hydraulic actuators or ropes actuators as in the aforementioned patent publication.

In particular, the first segment 5a comprises a terminal portion 5a' and a main portion 5a" wherein the main portion 5a" cooperates with the second segment 5b and the terminal portion 5a' is connected to a rescue cab <NUM> in known manner, e.g. fixed or movable.

In particular, the terminal portion 5a' is hinged via a hinge connection <NUM> to the main portion 5a". Accordingly, the terminal portion 5a' may vary the inclination of a longitudinal axis C thereof with respect to the longitudinal axis B of the ladder (see <FIG>), e.g. varying the value of an inclination angle α between <NUM> and <NUM>°.

Making reference to the schematic representation of <FIG>, the ladder assembly <NUM> is provided with a hydraulic equipment <NUM> configured to allow to provide firefighting fluid to rescue cab <NUM> from a source of firefighting fluid of the vehicle <NUM>.

The hydraulic equipment <NUM> is advantageously carried within ladder assembly <NUM>, i.e. within ladder assembly segments. In detail, the hydraulic equipment <NUM> comprises a plurality of rigid segments 10a, 10b, 10c, 10d, 10e that are telescopically housed one within the other. In particular, the rigid segments 10a, 10b, 10c, 10d, 10e are in equal number of the segments 5a, 5b, 5c, 5d, 5e of the ladder assembly <NUM>.

In particular, the first segment 10a is provided with an outlet <NUM>' that is configured to be hydraulically connected to a hydraulic device (not shown) that may be used by a rescuer on the cab <NUM> and the fifth segment 10e is provided with an inlet <NUM>" that is configured to be hydraulically connected to the firefighting fluid source on the vehicle.

In detail, the first segment 10a of the hydraulic equipment <NUM> has a diameter greater than the diameter of the second segment 10b and so on so that the fifth segment 10e is the smallest and is inserted within all the other segments.

Each segment 10a, 10b, 10c, 10d, 10e of the hydraulic equipment <NUM> is fixedly carried by the respective segment 5a, 5b, 5c, 5d, 5e of the ladder assembly <NUM> so that the movement of each segment 5a, 5b, 5c, 5d, 5e carries the respective 10a, 10b, 10c, 10d, 10e of the hydraulic equipment <NUM>.

In particular, the first segment 10a is divided into two separate portions 10a', 10a", a first portion 10a' is fixedly carried by the terminal portion 5a' of the first segment 5a of the ladder and a second portion 10a" is fixedly carried by the main portion 5a". The first and second portions 10a', 10a" are connected together via a flexible element <NUM>.

The flexible element <NUM> may be realized as a hose or an accordion-shape element or as any suitable flexible piping typology and is connected to its extremities to the portions 10a', 10a", as detailed in the following.

In particular, the flexible element <NUM> is configured to allow the relative movement via hinge <NUM> of portions 5a', 5a" of an angle α of maximum about, e.g., <NUM>°, <NUM>°.

In particular the flexible element <NUM> is placed vertically above or below the hinge <NUM>, in the disclosed embodiment vertically below the hinge <NUM>.

The flexible element <NUM> is connected to the portions 10a', 10a" via a length compensator <NUM>'. Length compensator <NUM>' allows a relative motion of at least an extremity of the flexible element <NUM> with respect to the first and/or second portions 10a', 10a".

In the disclosed embodiment, only one extremity of the flexible element <NUM> is connected in a movable manner to the first and/or second portions 10a', 10a", in particular to the main portion 10a".

Accordingly, flexible portion <NUM> comprises a first extremity <NUM> that is rigidly coupled, e.g. bolted or welded to the first portion 10a' of the first segment 10a of the hydraulic equipment <NUM> and a second extremity <NUM> that is movably about external surface of the second portion 10a". In particular, the second extremity <NUM> is fixed to an annular element <NUM> that is arranged between second portion 10a" and slides in tight manner with respect to the external surface of the second portion 10a".

The annular element <NUM> is operatively coupled via elastic means <NUM>, e.g. a plurality of helicoidally springs, to a flange element <NUM> that is fixedly carried by the second portion 10a".

The allowed movement along longitudinal axis B of flange element <NUM> depends on the rigidity of the elastic means <NUM> that may be set in function of the stiffness of the flexible element <NUM> and of the maximum allowed pressure of the firefighting fluid flowing in the flexible element <NUM>.

The operation of the embodiment of the invention as described above is the following.

When the ladder assembly <NUM> is in its retracted configuration (<FIG>) the segments 5a, 5b, 5c, 5d, 5e are placed one with respect to the other and the segments 10a, 10b, 10c, 10d, 10e are consequently compacted one within the other.

When the ladder assembly <NUM> starts to be extracted (see <FIG>), after being inclined with respect to the ground to reach the needed inclination, then the first segment 5a is controlled to be extracted with respect to the second segment 5b thereby increasing the length of the ladder assembly along axis B. The first segment 10a follows the movement of the first segment 5a extracting from the respective second segment 10b.

When the correct position is reached, then a further degree of movement may be used by controlling the movement of terminal portion 10a' by varying its inclination, i.e. angle α with respect to main portion 10a". In particular, since the hinge point <NUM> is positioned vertically distanced with respect the flexible element <NUM> in order to allow the motion of the terminal portion 10a' with respect to the main portion 10a", the flexible element may bent in order to compensate the variation of length along the longitudinal axis B.

with the length compensator system <NUM>', the flexible element <NUM> is allowed to retract or expand with respect to one (or two) of its fixation points according to the variation of pressure therein according to the flow of firefighting fluid passing in the flexible portion <NUM>. In such case, the force F exerted by the pressure variation in flexible portion <NUM> acts against or in favor of elastic means <NUM> thereby moving extremity <NUM> carried by element <NUM>.

In view of the foregoing, the advantages of the ladder assembly and of the rescue vehicle according to the invention are apparent.

Thanks to the proposed ladder assembly, it is possible to use rigid segments on a ladder in which the first segment has a terminal portion that is movable.

Indeed, the flexible element may compensate the length variation due to the movement of such terminal portion with respect to the main portion.

The proposed solution is economic and can be applied to any typology of existing ladders.

Moreover, the possible presence of a length compensator allows to compensate the stresses due to the variation of pressure in the flexible element thereby providing a robust disposition.

It is clear that modifications can be made to the described ladder assembly and rescue vehicle which do not extend beyond the scope of protection defined by the claims.

For example, the number of segments of ladder and of hydraulic equipment may vary.

Moreover, the relative disposition of the segments of hydraulic equipment with respect to the segments of ladder or of the flexible element with respect to the hinge may vary.

Claim 1:
Ladder assembly (<NUM>) for a rescue vehicle, said ladder assembly (<NUM>) comprising a plurality of segments (5a, 5b, 5c, 5d, 5d) carried one within the other in a telescopic manner, said ladder assembly (<NUM>) comprising actuator means configured to allow retraction or extraction of ladder assembly (<NUM>) between a minimum and a maximum length along said longitudinal axis (B), said ladder assembly (<NUM>) comprises a hydraulic equipment (<NUM>), said hydraulic equipment (<NUM>) comprising a plurality of rigid segments (10a, 10b, 10c, 10d, 10e) each associated to a respective segments (5a, 5b, 5c, 5d, 5e) of said ladder assembly (<NUM>), the first segment (5a) of said ladder assembly (<NUM>) comprising a terminal portion (5a') and a main portion (5a"), said terminal portion (5a') being carried in a movable manner by said main portion (5a"), said first segment (10a) of said hydraulic equipment (<NUM>) comprising a first portion (10a') and a second portion (10a") respectively carried by said terminal and main portions (5a', 5a"), said first portion (10a') being connected to said second portion (10a") via a flexible element (<NUM>),
wherein said flexible element (<NUM>) is configured to vary its length via a length compensator (<NUM>'), wherein a first extremity (<NUM>) of said flexible element (<NUM>) is fixedly carried to one of said terminal portion (5a') and said main portion (5a") and a second extremity (<NUM>) of said flexible element (<NUM>) is movably carried to the other of said terminal portion (5a') and said main portion (5a").
characterized in that said second extremity (<NUM>) is fixedly carried to a first element (<NUM>) that is slidably carried by said other of said terminal portion (5a') and said main portion (5a"), wherein length compensator (<NUM>') comprises elastic means (<NUM>) operatively interposed between said first element (<NUM>) and a portion (<NUM>) fixed with respect to said other of said terminal portion (5a') and said main portion (5a").