Patent Description:
Aside from the pure driving, the driver of a truck is likely to also perform various activities in his truck, like taking his lunches, resting, doing paperwork or sleeping. The driver may also be accompanied by passengers, who will also carry out their own activities either while the truck is driven or when the truck is parked. It is therefore handy to be able to temporarily arrange various pieces of equipment in the truck cabin, corresponding to the requirements of the moment.

The dashboard of the truck usually offers a storage space with some opened shelves and some closed compartments as well. This storage space is often not sufficient in terms of storage capacity, or not very well suited to the needs of the driver or of the passengers. In particular, the geometry of this storage space cannot usually be modified, or only to a very limited extent. There are various movable table assemblies which are for instance known from <CIT>, <CIT>, <CIT>, <CIT>, <CIT> and <CIT>.

Consequently, there is a need to propose a device on which various pieces of equipment can be disposed. The device should be adjustable and should be orientable to provide various geometrical configurations. The device should also be easy to dismantle and has to be safe to operate. The installation of the device should not negatively affect the comfort of the cabin. In particular, noise and vibration levels should not be increased once the device is fitted.

To this end, the present invention proposes a table assembly according to claim <NUM>.

The two degrees of freedom of pivotal movement provide a good flexibility and numerous possibilities to configurate the table assembly. The table assembly can be adjusted to receive equipment in various situations. Furthermore, both the swing arm and the turntable will remain in position under the mechanical constraints associated with normal driving of the vehicle. Therefore, the proposed table assembly provides a very versatile equipment that can be used by driver and passengers, in driving or non-driving conditions.

The following features can be optionally implemented, separately or in combination one with the others:.

Preferably, the first predetermined torque threshold is higher than the second predetermined torque threshold.

For example, the first predetermined torque threshold is comprised between <NUM>,<NUM> N. m and <NUM>,<NUM> N.

For example, the second predetermined torque threshold is comprised between <NUM>,<NUM> N. m and <NUM>,<NUM> N.

Preferably, the swing arm comprises a first pivot extending about a first axis. When the table assembly is assembled, the first pivot is supported by the support plate.

Preferably, the swing arm comprises a second pivot extending about a second axis. When the table assembly is assembled, the turntable is supported by the second pivot.

Preferably, the swing arm can be moved continuously between the stowed position and the extended position.

Preferably, the swing arm can be moved among a set of discrete stable positions.

Preferably, the turntable can be moved continuously relatively to the swing arm.

Preferably, the turntable can be moved relatively to the swing arm among a set of discrete stable positions.

Preferably, the first pivot extends from a first end of the swing arm.

Preferably, the second pivot extends from a second end of the swing arm.

Preferably, the swing arm is made of cast aluminum alloy.

Preferably, the length of the swing arm is about <NUM> centimeters.

Preferably, the width of the swing arm is about <NUM> millimeters.

Preferably, the length of the turntable is about <NUM> centimeters.

Preferably, the width of the turntable is about <NUM> centimeters.

Preferably, an axis of the first pivot of the swing arm makes with a vertical axis an angle comprised between <NUM>° et <NUM>°.

For example, an axis of the first pivot of the swing arm is vertical.

Preferably, an axis of the second pivot of the swing arm makes with the vertical axis an angle comprised between <NUM>° et <NUM>°.

For example, an axis of the second pivot of the swing arm is vertical.

Preferably, the axis of the first pivot is parallel to the axis of the second pivot.

Preferably, the first pivot and the second pivot extend from the swing arm in opposite directions.

Preferably, an angular amplitude of the swing arm between the stowed position and the extended position is comprised between <NUM>° and <NUM>°.

Preferably, an angular amplitude of the turntable relatively to the swing arm is comprised between -<NUM>° and <NUM>°.

Preferably, a translation motion of the swing arm relatively to the support plate is blocked when the table assembly is in use position.

Preferably, a translation motion of the turntable relatively to the second pivot of the swing arm is blocked when the table assembly is in use position.

Preferably, the support plate comprises a first locking device configured for holding the swing arm in place relatively to the support plate.

Preferably, the first locking device can be selectively activated and deactivated.

For example, the first locking device comprises a first rotating knob linked to the support plate.

Preferably, the first rotating knob is fixed to a threaded shaft, and the threaded shaft is engaged in a threaded bore of the support plate.

Preferably, the turntable comprises a second locking device configured for holding the turntable in place relatively to the swing arm.

Preferably, the second locking device can be selectively activated and deactivated.

In other words, a swiveling motion of the turntable relatively to the swing arm can be blocked by a second locking device.

Preferably, the second locking device comprises a second rotating knob linked to the turntable.

Preferably, the swing arm comprises a first pivot extending about a first axis and a second pivot extending about a second axis, the swing arm comprises a first portion extending transversely to the first axis and a second portion extending transversely to the second axis, and the first portion and the second portion are offset one from the other along the first axis.

For example, the swing arm comprises a curved portion linking the first portion and second portion.

For example, the curved portion comprises a first curvature directed towards the first pivot and comprises a second curvature directed in opposite direction.

Preferably, the first pivot of the swing arm is cylindrical, the support plate comprises a cylindrical bore, and the first pivot is inserted in the cylindrical bore of the support plate.

Preferably, the second pivot of the swing arm is cylindrical, and the turntable comprises a cylindrical bore, and the second pivot is inserted in the cylindrical bore of the turntable.

Preferably, the first pivot of the swing arm has a toothed crossed section.

For example, the first pivot is inserted in a sleeve fixed in a housing of the support plate.

Preferably, the second pivot has a toothed crossed section.

According to to the invention, the support plate comprises a protection pad, and the swing arm is in contact with the protection pad when the swing arm is in the stowed position.

Preferably, the protection pad comprises a first wing with which a lateral surface of the swing arm is in contact when the swing arm is in the stowed position.

Preferably, the first wing of the protection pad extends in a first plane parallel to the axis of the first pivot.

Preferably, the protection pad comprises a second wing with which a lateral surface of the swing arm is in contact when the swing arm is in the extended position.

The second wing extends in a second plane parallel to the axis of the first pivot.

Preferably, a cross-section of the swing arm has a U shape defining a base and two sides wings.

In an example of implementation, the base of the U-shaped cross-section is perpendicular to the axis of the first pivot. The sides wings of the U-shaped cross-section are parallel to the axis of the first pivot.

Preferably, the axis of the first pivot is located between the side wings.

When the table assembly is installed, the base of the U-shaped cross section is orientated away from the surface of the dashboard.

Preferably, a side wing rests against the first wing of the protection pad when the swing arm is in the stowed position.

Preferably, a side wing rests against the second wing of the protection pad when the swing arm is in the extended position.

Preferably, the protection pad comprises a base extending in a plane perpendicular to the axis of the first pivot, and a bottom surface of the swing arm is in contact with the base when the swing arm is in the stowed position.

Preferably, the protection pad is in polyacetal and polyoxymethylene (POM) material.

Preferably, the protection pad comprises an anti-friction additive.

According to the invention, the swing arm comprises a friction insert configured to slide over the protection pad when the swing arm is rotated from one position between the stowed position and the extended position to the other position.

For example, the friction insert is in polyacetal and polyoxymethylene (POM) material.

Preferably, the friction insert is fixed to swing arm by one or several fixing screws.

Preferably, the turntable comprises a protection mat configured to be in contact with the dashboard when the swing arm is in the stowed position.

The invention also relates to a retrofit kit comprising :.

in which the bracket is configured to receive the support plate of the table assembly.

Preferably, the support plate carries internal mechanical constraints when the support plate of the table assembly is fixed to the bracket.

The invention is also related to a truck comprising a table assembly as described earlier, or comprising a retrofit kit as described above.

In order to make the figures easier to read, the different represented elements are not necessarily drawn to scale. On these figures, identical elements are described by identical reference numbers. Some elements or parameters may be indexed, which means referred to by first or second element, or by first or second parameter. This index system is used only for differentiating elements that are similar, but not identical. This index system does not imply a priority of one element, or parameter, over another one, and the different terms may be exchanged.

When a device or a subsystem comprises a given element, it doesn't exclude the presence of other elements in this device or subsystem.

<FIG> shows a truck <NUM> comprising a table assembly <NUM> according to the invention, that will be described in detail here below. The truck <NUM> is for example a long-haul truck.

<FIG> illustrates in a non-limiting manner a table assembly <NUM> for a truck <NUM>, configured for being moved between a stowed position S and an extended position E, the table assembly <NUM> comprising :.

in which the swing arm <NUM> is configured to retain its angular position as long as a torque applied on the swing arm <NUM> is less than a first predetermined threshold Th1,
and in which the turntable <NUM> is configured to retain its angular position as long as a torque applied on the turntable <NUM> is less than a second predetermined threshold Th2.

The two degrees of freedom of pivotal movement provide a good flexibility and numerous possibilities to configurate the table assembly <NUM>. The table assembly <NUM> can be adjusted to receive equipment in various situations. Furthermore, both the swing arm <NUM> and the turntable <NUM> will remain in position under the mechanical constraints associated with normal driving of the vehicle. Therefore, the proposed table assembly <NUM> provides a very versatile installation that can be used by both driver and passengers, in driving or non-driving conditions. On <FIG>, arrow f1 indicates the travel of the table assembly <NUM> when it is moved from the stowed position S to the extended position E. The arrow f2 indicates the travel of the table assembly <NUM> when moved the other way round, meaning from the extended position E to the stowed position S. Similarly, arrow f3 indicates a clockwise rotation of the turntable <NUM>, when viewed from the top of the cabin, and arrow f4 indicates an anti-clockwise rotation of the turntable <NUM>. The table assembly <NUM> is intended to be moved by the effort of a user. For this, the user may exert a force on the swing arm <NUM>, or on the turntable <NUM>, or any protruding element linked to one of the previous elements. The rotation of the swing arm <NUM> is independent of the rotation of the turntable <NUM>. This means the swing arm <NUM> can be rotated relatively to the support plate <NUM> while the turntable <NUM> remains fixed relatively to the swing arm <NUM>. Similarly, the turntable <NUM> orientation relatively to the swing arm <NUM> can be modified while the angular position of the swing arm <NUM> relatively to the support plate <NUM> remains constant. Finally, the position of the swing arm <NUM> relatively to the support plate <NUM> and the position of the turntable <NUM> relatively to the swing arm <NUM> can be simultaneously modified.

The swing arm <NUM> can be rotated relatively to the support plate <NUM> only if the torque applied between the swing arm <NUM> and the support plate <NUM> exceeds a first predetermined threshold Th1. Thanks to this feature, the swing arm <NUM> will remain in a fixed position under the mechanical constraints associated with normal driving of the vehicle. These mechanical constraints come for example from the vibrations, small shocks, slopes and camber of the road on which the truck is driven. Different values of the first predetermined threshold Th1 can be obtained through design of internal clearances and materials selection. Similarly, the turntable <NUM> can be moved relatively to the swing arm <NUM> only if the torque applied between the turntable <NUM> and the swing arm <NUM> exceeds a second predetermined threshold Th2. The turntable <NUM> will thus also remain in position under mechanical constraints associated with normal driving of the vehicle.

The first predetermined torque threshold Th1 is higher than the second predetermined torque threshold Th2. For example, the first predetermined torque threshold Th1 is comprised between <NUM>,<NUM> N. m and <NUM>,<NUM> N. The second predetermined torque threshold Th2 is comprised between <NUM>,<NUM> N. m and <NUM>,<NUM> N. With these values of the first predetermined torque threshold Th1 and the second predetermined torque threshold Th2, the table assembly <NUM> position remains stable with the payload defined, and is still easy to move when a user wants to adjust its configuration.

In the embodiment illustrated here, for example on <FIG>, the swing arm <NUM> comprises a first pivot <NUM> extending about a first axis Z1. When the table assembly is assembled, the first pivot <NUM> is supported by the support plate <NUM>. <FIG> shows that the first pivot <NUM> is inserted in a housing <NUM> of the support plate <NUM>. The swing arm <NUM> also comprises a second pivot <NUM> extending about a second axis Z2. When the table assembly is assembled, the turntable <NUM> is supported by the second pivot <NUM>.

Preferably, the swing arm <NUM> can be moved continuously between the stowed position S and the extended position E. In other words, the swing arm <NUM> can steadily take any angular position comprised between the stowed position S and the extended position E.

According to the illustrated embodiment, the swing arm <NUM> can be moved among a set of discrete stable positions. In other words, the position of the swing arm <NUM> can be switched between various discrete positions, and intermediate positions between the discrete positions are only transient positions.

For this, and as illustrated on <FIG>, the first pivot <NUM> of the swing arm <NUM> has a toothed crossed section. The top <NUM> of the teeths is further away from the axis Z1 than the gap <NUM> between the teeths. On this example, the cross section of the pivot <NUM> is similar to an hexagon with rounded vertices.

The first pivot <NUM> may be inserted in a sleeve fixed in a housing of the support plate <NUM>. The sleeve has a complementary shape to the toothed cross section of the pivot <NUM>. The material and the dimensions of the sleeve are selected so the torque required to shift the pivot <NUM> by one tooth relatively to the sleeve is at least equal to the first predetermined threshold Th1.

In a similar way, in the illustrated embodiment the second pivot <NUM> has a toothed crossed section. This toothed crossed section ensures that the torque required to shift the second pivot <NUM> by one tooth is at least equal to the second predetermined threshold Th2. The turntable <NUM> can be moved relatively to the swing arm <NUM> among a set of discrete stable positions. Intermediate positions between these discrete positions are only transient positions that are occupied during the transition between one stable position and another stable position.

Preferably, the turntable <NUM> can be moved continuously relatively to the swing arm <NUM>.

<FIG> illustrates the swing arm <NUM> in isolation. The first pivot <NUM> extends from a first end of the swing arm <NUM>. The second pivot <NUM> extends from a second end of the swing arm <NUM>. The swing arm <NUM> has an elongated shape similar to a rod.

The swing arm <NUM> is metallic. The swing arm <NUM> is for example made of cast aluminum alloy. Adequate strength and stiffness can thus be provided. Furthermore, a variety of different shapes can easily be obtained.

As illustrated on <FIG>, the length L4 of the swing arm <NUM> is about <NUM> centimeters. The width W4 of the swing arm <NUM> is about <NUM> millimeters.

The first pivot <NUM> and the second pivot <NUM> extend from the swing arm <NUM> in opposite directions. In other words, the first pivot <NUM> and the second pivot <NUM> are pointing in opposition directions. The swing arm <NUM> is axially located, along the direction of extension of the first pivot <NUM> and the second pivot <NUM>, between the first pivot <NUM> and the second pivot <NUM>.

Preferably, an axis <NUM> of the first pivot <NUM> of the swing arm <NUM> makes with a vertical axis Z an angle A comprised between <NUM>° et <NUM>°. The axis Z1 of the first pivot <NUM> of the swing arm <NUM> is here vertical.

Similarly, an axis Z2 of the second pivot <NUM> of the swing arm <NUM> makes with the vertical Z axis an angle comprised between <NUM>° et <NUM>°. The axis Z2 of the second pivot <NUM> of the swing arm <NUM> is here vertical. As illustrated for example on <FIG>, the axis Z1 of the first pivot <NUM> is parallel to the axis Z2 of the second pivot <NUM>.

An angular amplitude A of the swing arm <NUM> between the stowed position S and the extended position E is comprised between <NUM>° and <NUM>°. An angular amplitude of the turntable <NUM> relatively to the swing arm <NUM> is comprised between <NUM>° and <NUM>°.

As illustrated on <FIG>, the length L7 of the turntable <NUM> is about <NUM> centimeters. The width W7 of the turntable <NUM> is about <NUM> centimeters. These dimensions are chosen so that the turntable <NUM> can accommodate the various pieces of equipment that the cabin occupants may need to install.

A translation motion of the swing arm <NUM> relatively to the support plate <NUM> is blocked when the table assembly <NUM> is in use position. Similarly, a translation motion of the turntable <NUM> relatively to the second pivot <NUM> of the swing arm <NUM> is blocked when the table assembly <NUM> is in use position. In other words, when the table assembly is installed to be used in a nominal way, no vertical translation degree of freedom is provided.

In the stowed position S of the table assembly <NUM>, the turntable <NUM> is supported by the dashboard <NUM>. In other words, in the stowed position S there's a least a portion of a bottom surface of the turntable <NUM> which is in contact with the dashboard <NUM> and thus supported vertically by the dashboard <NUM>. This aspect is best seen on <FIG>. In the extended position E, the turntable <NUM> is overhanging the dashboard <NUM>. In other words, there's no vertical support provided by the dashboard <NUM> to the bottom surface of the turntable <NUM>. When the table assembly <NUM> is in extended position E, the turntable <NUM> may be vertically facing the floor of the cabin of the truck <NUM>.

According to an aspect of the table assembly, the support plate <NUM> comprises a first locking device <NUM> configured for holding the swing arm <NUM> in place relatively to the support plate <NUM>. The first locking device <NUM> can be selectively activated and deactivated.

The angular position of the swing arm <NUM> remains constant when the first locking device is activated. The swing arm <NUM> can be swiveled by a user when the first locking device <NUM> is deactivated. The position of the swing arm <NUM> can then by adjusted by the user according to its needs. In other words, a swiveling motion of the swing arm <NUM> relatively to the support plate <NUM> can be selectively blocked or released by a first locking device <NUM>.

As shown for example on <FIG>, the first locking device <NUM> comprises a first rotating knob <NUM> linked to the support plate <NUM>. As represented on <FIG>, the first rotating knob <NUM> is fixed to a threaded shaft <NUM>, and the threaded shaft <NUM> is engaged in a threaded bore <NUM> of the support plate <NUM>. A rotation of the first rotating knob <NUM> pushes an axial end of the first threaded shaft <NUM> against the first pivot <NUM>. The mechanical constraint that is generated prevents a rotation of the swing arm <NUM> relatively to the support plate <NUM>. Different locking mechanisms can also be considered.

The turntable <NUM> also comprises a second locking device <NUM> configured for holding the turntable <NUM> in place relatively to the swing arm <NUM>. The second locking device <NUM> can be selectively activated and deactivated. In other words, a swiveling motion of the turntable <NUM> relatively to the swing arm <NUM> can be blocked by a second locking device <NUM>.

The angular position of the turntable <NUM> relatively to the swing arm <NUM> remains constant when the second locking device <NUM> is activated. Turntable <NUM> can be swiveled when the second locking device <NUM> is deactivated, which allows the position of the turntable <NUM> to be adjusted as required by the user. In other words, a swiveling motion of the turntable <NUM> relatively to the swing arm <NUM> can be selectively blocked or released by a second locking device <NUM>.

In the illustrated example, the second locking device <NUM> comprises a second rotating knob <NUM> linked to the turntable <NUM>. The second rotating knob <NUM> is fixed to a second threaded shaft, and the second threaded shaft is engaged in a threaded bore of the turntable <NUM>. A rotation of the second knob <NUM> pushes an axial end of the second threaded shaft against the second pivot <NUM>. The mechanical constraint that is generated prevents a rotation of the turntable <NUM> relatively to the swing arm <NUM>.

When required, the turntable <NUM> can be disengaged from the swing arm <NUM>. The swing arm <NUM> can also be mechanically disengaged from the support plate <NUM>. The turntable <NUM> can be stored when the table assembly <NUM> is not in use. The sub-assembly comprising the swing arm <NUM> equipped with the turntable <NUM> can also be stored when there's no intention to use the table assembly <NUM>. It can for example be stored under the bunk of the cabin. The table assembly <NUM> can then be easily reassembled so that it comes back in normal use conditions.

As best seen on <FIG>, the swing arm <NUM> comprises a first pivot <NUM> extending about a first axis Z1 and a second pivot <NUM> extending about a second axis Z2. The swing arm <NUM> comprises a first portion <NUM> extending transversely to the first axis Z1 and a second portion <NUM> extending transversely to the second axis Z2. The first portion <NUM> and the second portion <NUM> are offset one from the other along the first axis Z1. The swing arm <NUM> comprises a curved portion <NUM> linking the first portion <NUM> and second portion <NUM>. The curved portion <NUM> comprises a first curvature directed towards the first pivot <NUM> and comprises a second curvature directed in the opposite direction. In other words, the swing arm <NUM> has a shape similar to a flat 'S'. The offset along the first axis Z1 between the first portion <NUM> and the second portion <NUM> is selected so that the top surface of the turntable <NUM> is aligned, or nearly aligned, with the first portion <NUM>. Furthermore, this offset may compensate the vertical height difference existing between the first portion <NUM> of the swing arm <NUM> and the top surface of the dashboard <NUM>. The bottom of the turntable <NUM> can be more easily supported by the top surface of the dashboard <NUM>, as illustrated on <FIG>.

Preferably, the first pivot <NUM> of the swing arm <NUM> is cylindrical, the support plate <NUM> comprises a cylindrical bore, and the first pivot <NUM> is inserted in the cylindrical bore of the support plate <NUM>. Preferably, the second pivot <NUM> of the swing arm <NUM> is cylindrical, and the turntable <NUM> comprises a cylindrical bore <NUM>, and the second pivot <NUM> is inserted in the cylindrical bore <NUM> of the turntable <NUM>.

As illustrated on <FIG>, the support plate <NUM> comprises a protection pad <NUM>, and the swing arm <NUM> is in contact with the protection pad <NUM> when the swing arm <NUM> is in the stowed position S.

More precisely, the protection pad <NUM> comprises a first wing <NUM> with which a lateral surface 19a of the swing arm <NUM> is in contact when the swing arm <NUM> is in the stowed position S. The first wing <NUM> of the protection pad <NUM> extends in a first plane parallel to the axis Z1 of the first pivot <NUM>.

The protection pad <NUM> also comprises a second wing <NUM> with which a lateral surface 19b of the swing arm <NUM> is in contact when the swing arm <NUM> is in the extended position E. The second wing <NUM> extends in a second plane parallel to the axis of the first pivot <NUM>. The relative position of the first wing <NUM> and of the second wing <NUM> define the amplitude between the stowed position S and the extended position E. The protection pad <NUM> prevents the swing-arm <NUM> from wearing and damaging the dashboard <NUM>. Scratches that may result from repeated contacts and impacts of swing arm <NUM> against dashboard <NUM> are avoided. The protection pad <NUM> is for example in polyacetal, or in polyoxymethylene (POM) material.

In the present example, illustrated for example on <FIG>, a cross-section of the swing arm <NUM> has a U shape defining a base <NUM> and two sides wings <NUM>, <NUM>. The base <NUM> of the U-shaped cross-section is perpendicular to the axis Z1 of the first pivot <NUM>. The sides wings <NUM>, <NUM> of the U-shaped cross-section are parallel to the axis Z1 of the first pivot <NUM>. The axis Z1 of the first pivot <NUM> is located between the side wings <NUM>, <NUM>.

When the table assembly <NUM> is installed, the base <NUM> of the U-shaped cross section is orientated away from the surface of the dashboard <NUM>. In other words, the base of the U is facing upwards when the table assembly <NUM> is installed in the truck <NUM> and ready for normal use.

When the swing-arm <NUM> has such a cross section, a side wing <NUM> rests against the first wing <NUM> of the protection pad <NUM> when the swing arm <NUM> is in the stowed position S. A side wing <NUM> rests against the second wing <NUM> of the protection pad <NUM> when the swing arm <NUM> is in the extended position E. In other words, the first wing <NUM> of the protection pad <NUM> acts as a lateral end-stop for the rotation of the swing arm <NUM>. Similarly, the second wing <NUM> acts as another end-stop for the rotation of the swing arm <NUM>.

The protection pad <NUM> comprises a base <NUM> extending in a plane perpendicular to the axis Z1 of the first pivot <NUM>, and a bottom surface <NUM> of the swing arm <NUM> is in contact with the base <NUM> when the swing arm <NUM> is in the stowed position S. In other words, a weight acting on the turntable <NUM> tends to push the swing arm <NUM> against the base <NUM> of the protection pad <NUM>. The base <NUM> can provide a mechanical support to the swing arm <NUM> in case of deflection because of the weight of the loads put on the turntable <NUM>.

The protection pad <NUM> also prevents the creation of scratches on the top of the support plate <NUM>, due to the repeated angular strokes of the swing arm <NUM>. Preferably, the protection pad <NUM> comprises an anti-friction additive.

As represented on <FIG> and <FIG>, the swing arm <NUM> comprises a friction insert <NUM> configured to slide over the protection pad <NUM> when the swing arm <NUM> is rotated from one position between the stowed position S and the extended position E to the other position. A surface <NUM> of the friction insert <NUM> may be in contact with the base <NUM> of the protection pad <NUM>. In other words, the bottom surface <NUM> of the swing arm <NUM> contacting the protection pad <NUM> is provided by the surface <NUM> of the friction insert <NUM>. In the illustrated example, the friction insert <NUM> is fixed to swing arm <NUM> by one or several fixing screws <NUM>. Other fixing solutions are possible, like clipping or over molding of the friction insert <NUM> on an internal surface of the swing arm <NUM>.

For example, the friction insert <NUM> is in polyacetal and polyoxymethylene (POM) material. The supporting contact between the swing arm <NUM> and the dashboard <NUM> is thus made through materials with good friction properties.

As represented on <FIG>, the turntable <NUM> comprises a protection mat <NUM> configured to be in contact with the dashboard <NUM> when the swing arm <NUM> is in the stowed position S. The protection mat <NUM> is fixed to a surface of the turntable <NUM> configured to face the dashboard <NUM>. The protection mat <NUM> protects the dashboard <NUM> against possible damages of the dashboard <NUM> because of the repeated friction of the turntable <NUM> against the dashboard <NUM>.

Another idea, not according to the present invention, is that the swing arm <NUM> further comprises a weakened area <NUM> configured to break when a mechanical constraint exerted on the swing arm <NUM> is higher than a third predefined threshold Th3. This weakened area is particularly visible on <FIG>.

The swing arm <NUM> has a U-shaped cross section defining a base <NUM> linking two side wings <NUM>,<NUM>, and each side wing <NUM>,<NUM> comprises a weakened area 34a, 34b configured to break when a mechanical constraint exerted on the swing arm <NUM> is higher than a fourth predefined threshold Th4,Th4'.

In case mechanical constraint applied on the swing arm <NUM> is too high, like it can be the case when someone accidentally falls over the table assembly, a weakened area <NUM> of the swing arm <NUM> is designed to break so that an injury of the falling occupant may be avoided, or at least limited. For this, each side wing <NUM>, <NUM> of the U-shaped cross section of the swing arm <NUM> comprises a weakened zone 34a, 34b, ie a zone in which the wall is thinner than the rest of the side wing. Once these weakened zones 34a, 34b are ruptured by an excessive mechanical constraint, only the top section <NUM> of the swing arm <NUM> remains. Therefore, the flexion resistance of the swing arm <NUM> becomes much lower than with the original cross-section, and the swing arm <NUM> may plastically deflect in a controlled way. The risk of injury for the falling person is eliminated, or at least reduced. The weakened area is designed to resist to the maximum payload recommended for the table assembly, while used according to normal use case. For the same purpose of operational safety, sharp edges are avoided on the external profile of the swing arm <NUM>. A minimum radius is provided between the base <NUM> and each of the side wings <NUM>, <NUM>.

The weakened area 34a, 34b can be a notch machined in a side wing on the U-shaped cross section of the swing arm <NUM>. Preferably, each side wing <NUM>, <NUM> of the swing arm <NUM> comprises a machined notch 34a, 34b. The two notches 34a, 34b may face each other in a direction perpendicular to the main direction Y of the swing arm <NUM>, as it the case on <FIG>. The two notches may also be offset along the direction perpendicular to the main direction Y. The weakened area <NUM> can also be a portion with a lower thickness in the casting. In other words, no machining is performed, and the notch is formed by the shape of the mold.

Although the described table assembly is intended to equip trucks as original equipment, a retrofit kit can be proposed to equip vehicles not originally fitted. Such a retrofit kit comprises :.

and the bracket <NUM> is configured to receive the support plate <NUM> of the table assembly <NUM>.

As illustrated on <FIG>, the bracket <NUM> is fixed to the supporting frame <NUM> of the dashboard <NUM>. The support plate <NUM> is bolted to the bracket <NUM>. The bracket <NUM> is an intermediate part that makes a mechanical link between the support plate <NUM> and the supporting frame <NUM> which is a structural part of the dashboard <NUM>. The supporting frame <NUM> is able to carry the mechanicals loads generated by the weight and acceleration of the objects disposed on the turntable <NUM>.

On the example illustrated on <FIG>, the bracket <NUM> comprises two different bracket elements fixed to two different locations of the dashboard <NUM>. The bracket elements are sufficiently spaced to resist to the bending moments generated by the loads disposed on the table assy <NUM>.

Preferably, the support plate <NUM> carries internal mechanical constraints when the support plate <NUM> of the table assembly <NUM> is fixed to the bracket <NUM>. In other words, the mechanical assembly of the support plate <NUM> and the bracket <NUM> is an hyperstatic assembly. When the bolts <NUM> of the support plate <NUM> are tightened, the support plate <NUM> is not only pressed against the bracket <NUM>, but receives also a bending moment that tends to distort the support plate. The internal constraints that are generated in the support plate <NUM> when the fixing bolts <NUM> are tightened limit the propagation of vibrations in the dashboard <NUM>. Rattling noises due to vibrations are eliminated, or at least reduced.

Claim 1:
A table assembly (<NUM>) for a truck (<NUM>), configured for being moved between a stowed position (S) and an extended position (E), the table assembly (<NUM>) comprising :
- a support plate (<NUM>) configured to be mounted on a dashboard (<NUM>) of the truck (<NUM>),
- a swing arm (<NUM>) pivotally mounted on the support plate (<NUM>) about a first axis (Z1),
- a turntable (<NUM>) pivotally mounted on the swing arm (<NUM>) about a second axis (Z2),
in which the swing arm (<NUM>) is configured to retain its angular position as long as a torque applied on the swing arm (<NUM>) is less than a first predetermined threshold (Th1),
and in which the turntable (<NUM>) is configured to retain its angular position as long as a torque applied on the turntable (<NUM>) is less than a second predetermined threshold (Th2), characterized in that the support plate(<NUM>) comprises a protection pad (<NUM>), and in which the swing arm (<NUM>) is in contact with the protection pad (<NUM>) when the swing arm (<NUM>) is in the stowed position (S), the swing arm (<NUM>) comprises a friction insert (<NUM>) configured to slide over the protection pad (<NUM>) when the swing arm (<NUM>) is rotated from one position between the stowed position (S) and the extended position (E) to the other position.