FR3007263A1 - STABILIZED TABLE STAND MODULE WITH ARTICULATED ARM FOR SELF-ASSISTED SEAT - Google Patents

Abstract

The invention relates to a table leg module comprising at least one articulated arm for maintaining a seat in suspension without it being in contact with the ground. The combination of several modules makes it possible to make a table base. The foot (1) receives on one side the articulation support (2) supporting the articulation (3) which gives the articulated arm (4) a rotation of -45 ° to + 45 °. At the end of the articulated arm (4) is assembled the cylinder receiver (5) which will be equipped with the cylinder seat (7). The base (1) has at its base the stabilizing plate (6) having two catching fingers (6,1) whose positions are determined by the axis of the cylinder receiver (5), which brought to the maximum open position by the intermediate articulated arm (4) overhangs the axis (6.5) of a catch-up finger (6.1). By symmetry with the foot (1), the axis (6.6) of the second catch-up finger (6.1) is defined. The combination of several modules makes it possible to produce a table base whose catching fingers (6.1) of each stabilizing plate (6) delimit the holding polygon containing the axis of each jack receiver (5) brought back to the maximum open position canceling thus any risk of tipping. The device of the invention would be ideal for the creation of meeting tables or conference in tertiary environment, table game in public, table of stay in a private environment.

Description

The present invention applies to the furniture industry. It relates to a table leg module comprising at least one articulated arm for maintaining in suspension a seat without it being in contact with the ground. The combination of several modules makes it possible to make a table base.

There are various technical solutions for tables and chairs on the market. The purpose of these solutions is generally to assemble seats to a table base, fixed or articulated, to remove the feet of these seats so that only the table base is in contact with the ground, facilitating the maintenance of it for example. In fixed seating, the garden table with four inclined legs and supporting a bench on each side, through two crossbars, is a popular model, whether on motorways or public areas and since a few years at the private individual. However, these technical solutions all face an identical problem: the tilting of the table according to the weight applied to the seat by the user. The seat being assembled cantilever on the foot of the table, it behaves like a lever arm. When it is outside or partially outside the perimeter defined by the legs of the table, it will cause the tilting of the table when the balance of moments of force is exceeded that is to say when the weight on the seat is greater than the weight of the table at its center.

We will now study the case of tables with articulated arm for seat support, area of the invention. Assume a rectangular table of 80kg, width 0.90m and length 1.40m, with four vertical feet at each corner of the plate, each receiving 1 articulated arm length 0.35m supporting a seat, the arrangement of seated being in the direction of the length two by side, face to face. Mathematically the formula of the critical equilibrium of the moments of force is written in the following way: the product of the weight of the seat (X) with the cantilever distance must be equal to the product of the weight of the table in its middle with the distance from the tipping point (the base of the foot of the seat in question) to its middle. The weights are expressed in Newton, for our example we will calculate from what weight on a seat, the table switches: X * 0,35 = 785 (80 * 9,81) * 0,45 (0,90 / 2 ) X = 785 * 0.45 / 0.35 or X = 1009N or X = 103kg. So if only one person of 104 kilos sits at this table, it falls over. If two people weighing 52 kilos sit on the same side, it also switches knowing that 52 kilos is not a very high weight for an adult. To overcome this disadvantage, the radical solution would be to fix the table to the ground. But this implies a final position of the table at its location without being able to move it with, as a bonus, the deterioration of the ground by piercing for fasteners. This solution can be considered in a workshop but certainly not in an office or a dining room for example. Patent No. KR101207382 discloses stools for seats assembled to the base of the table by articulated arms which, spring-loaded, allow to store themselves automatically under the table. Each seat has a foot with a base in contact with the ground to eliminate the risk of tipping. The seat is no longer self-supporting, the floor is congested again, the device is therefore of no interest. Patent EP 1707076 has similarities to the previous patent. The seat is assembled to the base of the table by a double jointed arm.

The seat has a removable wheel stand to counter the tilting of the table. Same result as above for the congestion of the ground and even finding the interest of the invention. The present invention overcomes the inconvenience of the previous state.

It relates to a module consisting of a foot, stabilized by a plate, having at least one articulated arm for self-wear a seat without it being in contact with the ground. The invention makes it possible, by combining several modules, to produce a table base. Each module will be equipped with a seat from the trade that must have a cylinder. Numerous terms such as secretarial chairs, office chairs, executive chairs, etc., are used to define these cylinder bases; for simplification we will call them "Seat with jack". The cylinder seat usually has a wheel base, assembled on the cylinder by a conical fitting. By "unsticking" the cylinder by shock, the wheel base can be removed.

The seat then becomes part of the invention by its jack. The invention comprises a foot of fixed height and variable length, of curved shape with its descending concavity, delimiting in the upper part a bearing surface of the plate between the outer edge of the protrusion of the foot and the end of the this. At its base, the foot has a stabilizer plate of curved shape, concavity directed towards the outside of the foot, with two catching fingers to correct flatness defects of the ground. The two fingers are positioned on either side of the attachment point of the foot on the plate. The distance between the two catching fingers is variable. The foot receives at its height centered on one of its faces, the articulation support. Due to the curved shape of the foot, the support is set back from the foot base but outside the bearing surface of the plate. At the end of the articulation support is assembled the articulation. This consists of the hinge body, assembled on the support, and receiving at each of its two ends, a conical bearing mounted vis-à-vis. A protective cover will be screwed at the top of the hinge body to protect the bearings. A window in the hinge body, positioned between the two bearings, to receive the ring to which was assembled the articulated arm variable length. The shaft, fitted in the two bearings, is held in vertical position by its shouldered head, abutting on the upper bearing. The axis receives in the middle the ring which is secured to the axis by two elastic pins, and thus gives the articulated arm a limited rotational movement by the two stops arranged at the base of the window, rotation of -45 ° at + 45 °, 0 ° being perpendicular to the foot. A counterplate screwed into the base of the axis allows to adjust the play and the hardness of the joint. On the end of the articulated arm is assembled the cylinder receiver, into which will be introduced the cylinder seat. When the articulated arm is in the maximum open position that is to say against the stop of the joint at -45 °, the seat being in the furthest position of the plate, the axis of the seat and therefore the axis of the cylinder receiver perfectly overhangs the axis of a catch-up finger of the stabilizer plate. All of these elements is the stabilized foot module with articulated arm, in a simple version, since it has only one articulated arm. To achieve the double version, the foot will receive on its opposite face, in perfect symmetry with respect to its axis, the articulating support elements, articulation, articulated arm and receiver of cylinder thus allowing to suspend 2 seats with jack on a single foot . A table base supporting a tray will be achieved by combining several modules having at least one articulated arm for suspending a seat on a foot. To seat, the user rotates the seat by means of the articulated arm to arrange it in the open maximum position is thus created a passage allowing the user to sit. Once seated, the user approaches the tray by bringing the seat by pivoting the articulated arm either with his feet or with his hands. To get up, simply push back the seat which by pivoting is found in the maximum open position by releasing the passage.

All the ingenuity of the invention for canceling the tilting of a base lies in the shape of the foot and the stabilizing plate. Each foot constituting the base, of curved shape transmits the table of charge descent, consisting of the table's own weight plus that of the users, towards its stabilizing plate. Each plate of curved shape whose concavity is directed towards the outside of the base moves this lower load to the two fingers catching that composes it. The catching fingers of each platen form the support polygon of the base, therefore the table. Thus, the descents of load are positioned on the support polygon stabilizing perfectly the table. The seat held cantilevered by the articulated arm exerts a force on the foot at the junction of the articulating support on the foot via the joint. This force is called the lever arm. By the curved shape of the foot, the polygon delimited by the base of each foot contains the polygon delimited by the junction of each articulation support on each foot. When the articulated arm is in the closed position, that is to say the seat close to the plate, the forces exerted by each lever arm tend to tilt the base towards its center, forces which are then canceled by the other feet . In the maximum open position, the axis of each seat and therefore of each cylinder receiver exceeds the polygon delimited by each foot but is found in the support polygon delimited by the catching fingers of each plate. The leverage effect is then canceled since it is contained at any point in the lift polygon. For a good functionality of the articulated arm stabilized foot module, its total height, overall, will be 75cm minimum with the seat of the cylinder seat 48cm from the ground, the cylinder piston fully retracted. These ratings are intended to leave enough room for the user's legs. The height adjustment of the seat via the cylinder allows the use of the module to small people. The seat height 48cm from the ground determines the position of the cylinder receiver assembly on the articulated arm, depending on the type of cylinder seat purchased commercially. The distance between the top of the cylinder and the top of the seat, piston fully retracted, is variable depending on the manufacturer. This distance is called DVA (Distance above Cylinder on Seat). By subtracting the DVA to 48cm, the assembly position of the cylinder receiver is obtained.

In most cases, manufacturers equip their seats with a tapered cylinder. The cylinder consists in the upper part of a cylinder generally 50mm diameter, and in the lower part of a conical cylinder with a re-entrant angle. The proportion of cylinder length, straight and conical, may vary from manufacturer to manufacturer. The cylinder receiver will have at its base a conical bore of 20mm length with an identical angle to the cylinder. In the upper part, it will have a cylindrical bore of length identical to that of the cylinder. The fitting of the seat is achieved when the conical cylinder of the cylinder is in contact with the conical bore of the receiver. The cylinder head is then aligned with the head of the cylinder receiver.

The interest of the invention is to allow the realization of a large number of legs, various provisions and sizes.

However, for a good functionality of the base and, in particular, for sufficient space in the legs of the user, the minimum size of the trays will be 1 meter diameter for round trays, 1 meter wide for rectangular trays with screw modules and 90cm aside for the square trays.

Beyond these minimum dimensions, the choice of a table base is determined by 2 criteria: the desired seating number and the shape of the desired tray. After validation of these two criteria, the stabilized table leg module with articulated arm has 3 variables allowing the realization of the chosen base. The first variable called V1 determines the length of the foot according to the size of the plate. The foot of the invention has, in the upper part, a bearing surface receiving the table top. The bearing length of this surface called "minimum LA" is 48cm, at least, for round and rectangular tray and 60cm for the square plate given the base arranged at 45 ° to the tray. "The minimum" is delimited in the upper part of the foot by the outside of the outgrowth of the foot, and the horizontal end of the foot, corresponding to the center or middle of the plate. For a quality finish, the tray always exceeds 2cm of the outgrowth. If we add "LA minimum" with the edge of 2cm, we get 50cm, the radius or the minimum width of the tray. Depending on the size of the tray, the support length should be adjusted. It is done by extending the horizontal end of the foot according to variable V1. In the minimum sizes of trays V1 = 0. The variable V1 corresponds to the difference in size between the new tray and the minimum tray. For example, for a round tray of radius 60cm, V1 will be 60-50 is 10cm. The foot will, during its manufacture, extended by 10cm. The support length will then be "LA minimum" + V1 is 48 +10 = 58 cm. Same procedure for rectangular tray using half width. For the square plate, the base being arranged at 450, V1 is calculated by the Pythagorean theorem. Take a square board 100x100cm, so it increases by 5cm on each side compared to the minimum size, which is 90cm per side, so V1 = NI52 + 52 is 7,071cm. The length of support = "LA minimum" + V1 is 60 + 7,071 is 67,071cm.

The second variable, called V2, determines the center distance between the articulation and the cylinder receiver. V2 is dependent on V1. Each seat has a shelf space, obtained by dividing the length, circumference or side of the board by the number of seats. For comfort, this space will be at least 70cm wide. The seat is in an ideal position when it is at the axis of its space, and, that its backrest is receding of 35cm compared to the edge of the plate. Average distance to be "sitting well at the table". The joint being at a fixed distance from the foot, it is sufficient to measure the distance between the articulation and the seat cylinder. The articulated arm will be adjusted side cylinder receiver, depending on this length. Whatever the size of the tray, it is imperative that the cylinder seat is brought by the articulated arm to this ideal position.

The third variable called V3 determines the position and the distance between the two catching fingers of the stabilizing plate. V3 is dependent on V2. To determine this position, simply place the cylinder seat in the maximum open position, the axis of its jack then overhangs the axis of the catch-up finger. By symmetry at the foot of the module, we obtain the second axis. The dimensions of the stabilizing plate are defined by the distance between the two catching fingers. These become the tipping pivot of the table. The leverage effect of the cantilever cylinder seat is canceled because the user's weight on the seat in its axis does not exceed the lift polygon. Failover becomes impossible. Nevertheless, the user can create a new lever arm by positioning himself as follows: he places the seat in the maximum open position, rotates the seat on its cylinder by 180 °, so that the backrest is found on the plateau side, sitting outwards. He sits on the seat, not at its center, but at the very end. The distance of the lever arm therefore corresponds from the end of the seat to its axis, so the axis of its cylinder, a maximum dimension of 30cm (the standard seat is of average size between 45 and 55cm with a axis placed 30cm from the end of the seat). For the calculation of the critical equilibrium, we take the case of a smallest feasible base, that is to say the case where the polygon delimited by the catching fingers of each stabilizing plate is the smallest, either a round top table with a diameter of 1 meter, consisting of 4 modules foot stabilized table articulated arm simple version, for 4 seats. The weight of the complete table is about 150 kilos or 1471N. The distance from the pivot point corresponding to the axis of the catch-up finger and the center of the table is 87cm. Therefore X * 0.3 = 1471 * 0.87 is X = 1471 * 0.87 / 0.3 is X = 4265.9 N or X = 434Kilos. At 435 kilos on the seat, the table tilts. In the case of a rectangular table, minimum width 1m tray, composed of 4 modules double version allowing 8 seats, or 4 per side, weight of the table 220kg or 2158,2N, distance from the pivot to the center of the table 87cm and lever arm 30cm, X = 638kg. For the table to rock, it would take 4 people 160kilos 640 kilos, sit on the same side, at the same time, at the end of the seat. What remains impossible except in the case of wanting to tip it. These two examples demonstrate, in the case of the smallest legs and with the greatest risk of tipping, the margins of safety that provides the invention. The catching fingers of each stabilizer platen receive the descent load of the table. The heavier the users, the more the descent of load will be important. To protect the soil, they will be equipped with polyurethane pads, glued to their bases. During the first installation of a table it is imperative that each catch finger is in contact with the ground, in order to stabilize the base following the flatness defects of the ground. To do this, simply screw the catching finger in the stabilizer plate, if the soil has a hollow at this point, or unscrew it if the soil has a bump. Following descents of load, in order not to deteriorate the catching finger, it is imperative that there remains 5mm of catch in the thread of the stabilizing plate. To do this, the stabilizer plate has a shoulder receiving the finger cover. This is held in position by a screw inserted into the catching finger. The length of the screw is determining, it defines the limit of screwing of the finger so that it remains 5mm of catch. Indeed, if the soil has too large a hollow, the catch-up finger will be too screwed, the finger cover can not be maintained, its screw being too short. It will therefore add a wedge under the finger. In the case where the soil has too much bump, if the catching finger is too loose, the finger cover is no longer in contact with the bottom of the shoulder, it then overflows the stabilizer plate. It may be in contact with the ground and not the pad Pu. To correct this problem, simply screw the other fingers to catch the top of the bump.

The mechanical torsion and bending type constraints that each articulated arm table foot module undergoes according to the weight of the users, encourage us to use solid aluminum steels or alloys of sufficient thickness. The assemblies will preferably be made by mechanics. welding. The curved shapes of each foot, articulation support, articulated arm and platinum stabilizer may also be angular or faceted according to the desired aesthetic appearance. Drills, degressive sizes, can be made in the foot to reduce its weight without impairing its strength.

The drawings in the appendix illustrate the invention: FIG. 1: Axonometric view of the stabilized table leg module with articulated arm FIG. 2: AA section of the stabilizing plate, showing the device for catching ground flatness defects FIG. Elevation view of the stabilized single-hung table leg module with a cylinder seat. Fig.4: Vertical section B-B of the assembly, articulation representing its operating principle.

Fig.5: Horizontal section CC of the assembly, joint representing the principle of rotation of the articulated arm with its stops Fig.6: Definition of the variables for a table base with 3 modules Fig.7: Example of realization of a base Fig.8: Placing modules of different lengths Here is a detailed description of the invention, from an exemplary embodiment, in relation to all of the figures. FIG. 1 is an axonometric view of the device of the invention: the stabilized table leg module with articulated arm in a simple version. The foot (1) of curved shape with its concavity directed downwards, has in the upper part of a support surface receiving the tray delimited by the edge (1.1) of the protrusion of the foot (1) and the edge (1.2) corresponding to the end of the foot (1) and therefore in the center or middle of the plate. These two edges define the minimum support length "LA minimum" of 48 cm for the round and rectangular trays and 60 cm for the square trays. The variable V1 determines the length of the foot (1) according to the size of the plate. In minimum size, V1 = 0. The base (1) has at its base the stabilizing plate (6) curved in shape, concavity directed towards the outside of the foot (1), having the two catching fingers (6.1) (see fig2) to correct the defects ground flatness.

The foot (1) receives on one of its faces the articulation support (2) centered on the total height of the foot (1) and positioned horizontally in the middle of the curvature of the foot (1). The articulation (3), assembled to the articulation support (2), receives the articulated arm (4), conferring on it a rotational movement of -45 ° to + 45 °, 0 ° being perpendicular to the foot (1) (position of the figure). The articulated arm (4) has at its end the cylinder receiver (5). The articulation distance (3) and cylinder receiver (5) corresponds to the variable V2 which is dependent on V1. When the articulated arm (4) is brought to the maximum open position, at -45 ° in the figure, the axis of the cylinder receiver (5) perfectly overhangs the axis (6.5) of the stabilizing plate (6). To obtain the second axis (6.6), it is sufficient to perform a symmetry of the axis (6.5) relative to the middle of the base of the foot (1). The center distance (6.5) and (6.6) corresponds to the variable V3 which is dependent on the variable V2. In our example, the module will be made of brushed stainless steel, thickness 25mm for the foot (1) and 20mm for the articulation support (2), the articulated arm (4), the stabilizing plate (6). The hinge assembly (3) and the cylinder receiver (5) will be machined from stainless steel. Drills will be made in the foot (1) to reduce its weight, without impairing its strength.

FIG. 2 represents, in section A-A, the catch-up device of the stabilizing plate (6). The stabilizing plate (6) receives a through boring with fine pitch threading. The piercing is surmounted by a shoulder receiving the finger cover (6.3). The height of the shoulder corresponds to the thickness of the finger guard (6.3).

The catching finger (6.1), threaded at the same fine pitch as the stabilizing plate (6), receives at its center a through thread. This tapping allows the screw (6.4) to hold in position the finger cover (6.3). The catching finger (6.1) also receives 2 penetrating through holes of diameter and spacing corresponding to that of a commercially available spur wrench. Finally, the catching finger (6.1) receives at its base a bore in which will be glued a Polyurethane pad (6.2) of diameter 20mm minimum and 6mm minimum thickness. For a stabilizer plate (6) with a thickness of 20mm, a finger cover (6.3) with a thickness of 2.5mm, the stroke of the catch-up finger (6.1) will be 12.5mm keeping a 5mm grip in the stabilizer platen (6) for safety. The length of the screw (6.4) will then be 15mm. During the first installation of a table with a base composed of several articulated-arm table leg modules, the user proceeds on all the stabilizer plates (6) in the following manner: he removes the finger-covers (6.3) by unscrewing the screws (6.4). Using a hook wrench, he screws or unscrews the catching fingers (6.1), until they are in contact with the ground via their pad Pu (6.2). He remixes the finger covers (6.3) with the screws (6.4).

The table is stabilized. FIG. 3 represents an elevation of the articulated arm stabilized table leg module with the situation of a cylinder seat. The wheel base is removed from the commercial cylinder seat (7). It is assembled by conical fitting. Our cylinder (7.1) consists, in the upper part, of a 50mm diameter cylinder for a length of 60mm, and, in the lower part, a 180mm long conical cylinder with a re-entrant angle of 1.26 °. The cylinder receiver (5) will be adapted according to this jack (7.1). It will have a total length of 80mm, present, in the upper part, a cylindrical bore with a diameter of 50.1mm and a length of 60mm, then, at the bottom, it ends with a tapered bore with a re-entrant angle of 1 °, 26 °. length 20mm. The cylinder seat (7) is then fitted by means of its cylinder (7.1) into the cylinder receiver (5). When the conical cylinder comes into contact with the conical bore, the cylinder seat (7) is in place. The Distance on Cylinder on Seat (DVA) from our seat is 18cm. To obtain the seat rating of 48cm from the ground, the head of the cylinder receiver (5) will be positioned 30cm from the ground allowing its mechanically welded assembly with the articulated arm (4).

Figure 4 shows the joint assembly (3) in vertical section B-B. The hinge body (3.1) of hollow cylindrical shape, receives at each of its ends a bore for fitting the cups of conical bearings (3.3 and 3.4). A window (F1, F2, F3) is machined in the hinge body (3.1) in the left part, centered on its height. It will be sufficiently high, delimited by (F1) and (F3), included a set of operation, to receive the articulated arm (4), provided with its ring (3.7), and sufficiently deep (F2), to allow the fitting elastic pins (3.8). In the lower part (F3), it will be machined at 45 ° to achieve the stops (B) of the articulated arm (4) (see Fig.5). The hinge body (3.1) has, in the right part, centered on its height, a flat of width and height identical to the hinge support (2) facilitating the assembly, welded type, the two parts . Finally, three tappings arranged at 120 ° in the upper part of the hinge body (3.1), allow to fix the protective cover (3.9) by means of the screws (3.91). The ring (3.7) has a flat width and height identical to the articulated arm (4) facilitating the assembly, welded type of the two parts. It also has two holes receiving the elastic pins (3.8). The axis (3.2) is integral with the ring (3.7) by means of the elastic pins (3.8). Its shouldered head holds it upright through the tapered cone (3.3). Its withdrawal from the conical bearing cone (3.4) allows adjustment of the game and the hardness of the rotation. The axis (3.2) has a tapping at its base receiving the screw (3.6) which closes the joint via the backplate (3.5). The hardness of rotation is a function of the tightening force of the screw (3.6) which tightens the cones in the bearing cups (3.3 and 3.4) via the backplate (3.5) and the shaft (3.2). ).

Figure 5 shows the joint assembly (3) in horizontal section C-C. This section makes it possible to define well the machining depth of the window (F2) in the articulation body (3.1). In the lower part of the window, the stops (Bu) make it possible to stop the rotation of the articulated arm (4) at + 45 ° or -45 °, ie a total angle of rotation of 90 °. The bottom of window (F2), in the upper part, slightly exceeds the elastic pins (3.8), allowing their assembly or disassembly. This section also defines the positioning of the hinge body (3.1), by its flat surface, on the hinge support (2) and, the positioning of the hinged arm (4) on the flat part of the ring (3.7). The tapered bearings (3.3 and 3.4) provide a rotation to the axis (3.2) integral with the articulated arm (4) via the ring (3.7) and the elastic pins (3.8). This rotation is limited to + or - 45 ° by the stops (B) of the hinge body (3.1). In normal use, the wear parts to be replaced, if any, are the conical bearings (3.3 and 3.4) which support the eccentric loads. To do this, simply remove the protective cover (3.9) by unscrewing the 3 screws (3.91), remove the spring pins (3.8), remove the back plate (3.5) by unscrewing the screw (3.6). Remove the shaft (3.2) to release the articulated arm (4) and the ring (3.7). The tapered bearings (3.3 and 3.4) are then accessible. Reverse procedure for reassembly.

Figure 6 shows our example embodiment. The two imposed criteria are 6 seated with a round plate. The table base will be composed of 3 modules with articulated arm, in double version, allowing to receive 6 seats. The 3 modules will be arranged at 1200. To define the diameter of the plate we multiply the number of seats by the minimum space is 6 x70 = 420cm circumference or 133.75cm minimum diameter. For convenience, we choose a diameter of 140 cm or 73.26cm of space per seat. To know the first variable V1 which determines the length of the foot (1), it suffices to subtract the minimum shelf radius from the new shelf radius V1 = 70 - 50 or V1 = 20cm. Each foot (1) will be extended by 20cm for its manufacture. For each module, the support length for the tray will be 68cm defined by "LA minimum" + V1 is 48 +20 = 68cm To know the second variable V2 which defines the interaxial length of the articulation (3) to cylinder receiver (5), the tray is divided into 6 quarters. The cylinder seat (7) is positioned at the axis of a neighborhood, with a backrest of the backrest 35cm from the edge of the plate. The axis of the joint (3) being at the fixed distance of the foot is 9cm, the measurement obtained from the spacing Articulation (3) - cylinder receiver (5) is 33cm. The articulated arm (4) can be adjusted according to this distance. To know the third variable V3 which determines the position and the distance between the two catching fingers of the stabilizing plate, the articulated arm (4) is brought back to the maximum open position by the articulation (3). On our figure it is at -45 ° in the trigonometrical direction. The axis of the cylinder receiver (5) overhangs the axis (6.5) of the catching finger (6.1) of the stabilizer plate (6). The second axis (6.6) is obtained by foot symmetry (1). The distance between centers is 68cm. The width of the stabilizing plate (6) at the base of the foot (1) is 8cm. Its ends end in 2 semicircles of radius 20mm whose centers correspond to each axis (6.5 and 6.6). The shape of the stabilizing plate (6) is obtained by the drawing method of the 3-point circle. The 3 variables are defined, the base can be realized.

Figure 7 shows the particular case of the square table. For the realization of the base, 4 stabilized table leg modules with articulated arm in simple version were used. The same base can be realized with 2 modules double version and 2 modules without articulated arm. The determination of the variables remains the same. FIG. 8 represents a simulation of modules of different lengths.

This type of 16-seat base for the example, with an elliptical tray, allowing all users to see each other, would be ideal for a conference table. The variable V1 of the 4 central modules is greater than the variable V1 of the 4 external modules. Despite this elliptical shape of the plate, the 2cm overhang is always respected, the support length being adjusted by the variable V1 as a function of the position of each module relative to the plate. For large bases, groups of modules can be assembled, mechanically, on site. In the example, the base is composed of a group of 4 modules assembled to the central cross member (8) and having 2 half-cross members (9) for the extension of the base. This set corresponding to a rectangular table base with 8 seats. The 2 groups of ends composed of 2 modules each receive two half-crosspieces (9), one serving to support the end of the plate, the other serving for connection to the group of 4 modules via the spacer (9.1) The device of the invention would be ideal in the tertiary environment for the creation of meeting or conference table. In public, the invention would be interesting for the realization of leu table and especially poker whose parts can last for many hours, in view of the comfort of certain ranges of cylinder seats. In a private environment and by adapting the style of the seats, the invention could allow the realization of a living room table. 30 35

Claims (9)

CLAIMS1) stabilized table leg module articulated arm for self-supporting seat, characterized in that the foot (1) of curved shape with its concavity directed downwards, delimiting at its upper part a bearing surface for the plate between the edge (1.1) of the protrusion and the ridge (1.2) corresponding to the center or middle of the plate, has at its base a stabilizing plate (6) of curved shape with its concavity directed towards the outside of the foot (1). ), comprising two catching fingers (6.1) in contact with the ground, arranged on either side of the point of attachment of the foot (1) on the stabilizer plate (6), for correcting ground flatness defects. 2) Module according to claim 1, characterized in that the foot (1) receives at its mid-height at least one hinge support (2) supporting a hinge (3) which allows rotation of an angle between - 45 ° to + 45 ° to an articulated arm (4) at the end of which is assembled a cylinder receiver (5) for receiving a cylinder (7.1) of a cylinder seat (7) chosen to equip said module . 3) Module according to claim 2, characterized in that the combination of several modules allows for a table base whose polygon delimited by the base of each foot (1), by its curved shape, contains the polygon delimited by the joining each articulation support (2) on each leg (1), junction receiving the lever effect of the seat transmitted by the articulated arm (4) and the articulation (3). 4) Module according to any one of claims 2 or 3, characterized in that the combination of several modules allows for a table base whose catching fingers (6.1) of each stabilizer plate (6) delimit the support polygon containing the polygon delimited by the base of each foot (1) and containing the axis of each cylinder receiver (5) returned to the maximum open position by its articulated arm (4). 5) Module according to any one of claims 2 to 4, characterized in that the joint (3) consists of a hinge body (3.1), assembled on the hinge support (2), receiving at each of its ends a tapered bearing (3.3 and 3.4) mounted opposite and allowing via an axis (3.2), held in position by its shouldered head abutting on one of the tapered bearings (3.3) , a rotation of 90 ° to the articulated arm (4) assembled to a ring (3.8) integral with the axis (3.2) by resilient pins (3.8), rotation limited by the contact of the articulated arm (4) on stops ( Bu) in the lower part of the window (F3) of the hinge body (3.1), whose play and hardness are adjusted by the clamping force of a screw (3.6), tightening the tapered bearings (3.3 and 3.4). ) via a back plate (3.5) and the axis (3.2). 6) Module according to any one of the preceding claims, characterized in that the load decreases of the base of the table consisting of the weight of the table and that of the users are transmitted by each foot (1) to each platinum stabilizer (6). ) which moves them to its catching fingers (6.1) delimiting the lifting polygon. 7) Module according to any one of the preceding claims characterized in that the length of the foot (1) is determined by adding the minimum support length with a variable V1 corresponding to the increase, per side, the radius, by Pythagoras the size of the new board relative to the minimum tray size. 8) Module according to any one of the preceding claims, characterized in that the articulation distance (3) and cylinder receiver (4) is defined by a variable V2 corresponding to the distance between the axis of the joint (3). ) and the axis of the cylinder receiver (5) when the cylinder seat (7) is in the ideal position, the axis of its space, its backrest receding 35cm from the plate. 9) Module according to any one of the preceding claims characterized in that the position and the distance between the two catching fingers (6.1) of the stabilizer plate (6) is determined by a variable V3 which is obtained by reducing the intermediate of the articulated arm (4), the cylinder receiver (5) in the maximum open position, its axis overhangs the axis (6.5) of the first retrieval finger (6.1), the position of the axis (6.6) of the second catch-up finger (6.1) being obtained by foot symmetry (1).