ITMI20100616A1 - FLUID SHOCK ABSORBER, PARTICULARLY FOR HOUSEHOLD APPLIANCES SUCH AS OVENS, DISHWASHER OR SIMILAR OR FOR FURNISHING COMPONENTS SUCH AS DOORS OR DRAWERS. - Google Patents

Description

"FLUID SHOCK ABSORBER, PARTICULARLY FOR HOUSEHOLD APPLIANCES SUCH AS OVENS, DISHWASHER OR SIMILAR OR FOR FURNITURE COMPONENTS SUCH AS DOORS OR DRAWERS"

DESCRIPTION

The present invention relates to a fluid damper, particularly for appliance doors such as ovens, dishwashers or the like or for furnishing components such as doors or drawers.

Fluid shock absorbers are known which are used in particular to slow down the closing movement of doors or drawers of furniture components, but also of appliance doors such as ovens and dishwashers.

Known type shock absorbers generally comprise a body or casing with a substantially cylindrical conformation in which a first cylindrical chamber is defined which slidably houses a piston whose stem protrudes from an axial end of the casing and can be connected to the object that has to stop. The piston axially delimits a part of the first chamber in which a fluid is contained and this part of the first chamber communicates, through holes of calibrated diameter, with a second chamber which, in some types of shock absorbers, is arranged around the first chamber and, in other types of shock absorbers, develops partly around the first chamber and partly inside the casing on the side opposite the first chamber with respect to the piston. An elastically deformable element, such as a sponge, is arranged in the second chamber, or the second chamber is delimited by an elastically deformable element, such as a membrane, so that the useful volume of the second chamber can vary to exchange fluid with the first room.

In practice, in these types of shock absorbers, the movement of the piston relative to the casing, in the sliding direction which causes a volume reduction of the part of the chamber that contains the fluid and that communicates with the second chamber, determines an increase in the pressure at the inside this part of the first chamber and the passage of fluid into the second chamber through the calibrated holes. The movement of the piston in the opposite direction generates a depression inside the part of the first chamber which contains the fluid causing a return of fluid from the second chamber through the calibrated holes.

The passage of the fluid through the calibrated holes dissipates kinetic energy by braking the piston and therefore the object connected to it. Generally, the movement of the piston in the sense that it causes a reduction of the part of the first chamber containing the fluid is generated by the movement of the object to be braked, while the movement in the opposite direction or rearming movement of the shock absorber is generated by a return spring which is interposed between the piston and the casing.

The use of these shock absorbers, in particular in the furniture and household appliances sector, where a containment of the dimensions of the shock absorbers is required, has highlighted some problems.

One of the problems encountered in these types of shock absorbers is represented by the difficulty in being able to combine the need for reduced dimensions with the need for adequate mechanical strength that allows the shock absorber to withstand impulsive stresses, particularly when they are liquid shock absorbers.

Another problem is represented by the time required for rearming the shock absorber by the action of the return spring. In fact, due to the fact that the communication between the first chamber and the second chamber is realized by the calibrated holes, the passage section of which for the fluid must be suitably small to obtain a good braking effect, to have a quick reset it is necessary to use a return spring capable of developing a high force. This fact generally constitutes a problem since the force of the return spring is a force to be overcome during the actuation of the object to be braked.

The aim of the present invention is to solve the aforementioned problems, realizing a fluid damper, particularly for appliance doors such as ovens, dishwashers or the like or for furnishing components such as doors or drawers, which, with the same overall dimensions, can have a higher mechanical resistance to stresses, even of the impulsive type, with respect to known shock absorbers.

Within this aim, an object of the invention is to provide a shock absorber which, having the same overall dimensions transversely to the direction of motion of the object to be braked, and with the same applied force, can develop considerably lower pressures in the working fluid than to those found with known types of shock absorbers.

Another object of the invention is to provide a shock absorber structured in such a way as to have, if required, a high reset speed even with the use of a reduced reset force.

A further object of the invention is to provide a shock absorber which can have a long life and high operating reliability.

Yet another object of the invention is to provide a shock absorber which can be produced at competitive costs.

This task, as well as these and other purposes which will become clearer hereinafter, are achieved by a fluid damper, particularly for appliance doors such as ovens, dishwashers or the like or for furnishing components such as doors or drawers, characterized in that it comprises a shock absorber body internally defining a chamber containing a fluid and slidably housing a piston movable along an actuation direction relative to said shock absorber body and dividing said chamber into two parts, respectively a first part and a second part, located on opposite sides with each other relative to said piston along said actuation direction, said first part of the chamber being in communication with said second part of the chamber through at least one connection port defined in said piston and / or between said piston and the side walls of said chamber for allow the passage of the fluid from said p remains part of said second part of the chamber or vice versa and consequently to allow the sliding of said piston relative to said shock absorber body along said direction of actuation in one direction or in the opposite direction, said at least one connection port having a passage section for the variable fluid at least once in the stroke of said piston along said actuation direction relative to said shock absorber body.

Further characteristics and advantages of the invention will become clearer from the description of three preferred, but not exclusive, embodiments of the shock absorber according to the invention, illustrated, by way of non-limiting example, in the accompanying drawings, in which:

Figures 1 to 6 illustrate the shock absorber according to the invention in the first embodiment, more particularly:

Figure 1 is an axially sectioned view of the shock absorber, along the axis I-I indicated in Figure 2;

Figure 2 is a section of Figure 1 taken along the axis II-II;

Figure 3 is a section of Figure 1 taken along the axis III-III;

Figure 4 shows the shock absorber in section as in Figure 1, but in a different operating condition;

Figure 5 illustrates the shock absorber still in section as in Figure 1, but in a further operating condition;

Figure 6 illustrates an enlarged detail of Figure 5 in a particular operating condition of the shock absorber; Figures 7 to 13 illustrate the shock absorber according to the invention in the second embodiment, more particularly:

Figure 7 is an axially sectioned view of the shock absorber, along the axis VII-VII indicated in Figure 8;

figure 8 is a section of figure 7 taken along the axis VIII-VIII;

figure 9 is a section of figure 7 taken along the axis IX-IX;

Figure 10 shows the shock absorber in section as in Figure 7, but in a different operating condition;

Figure 11 is a section of Figure 10 taken along the axis XI-XI;

Figure 12 shows the shock absorber still in section as in Figure 7, but in a further operating condition;

Figure 13 illustrates an enlarged detail of Figure 7 in a particular operating condition of the shock absorber; Figures 14 to 18 illustrate the shock absorber according to the invention in the third embodiment, more particularly:

Figure 14 illustrates the shock absorber sectioned axially along the axis XIV-XIV indicated in Figure 15;

Figure 15 is a section of Figure 14 taken along the XV-XV axis;

Figure 16 illustrates the shock absorber in section as in Figure 14, but in a different operating condition;

Figure 17 illustrates the shock absorber still in section as in Figure 14, but in a further operating condition;

Figure 18 illustrates an enlarged detail of Figure 14 in a particular operating condition of the shock absorber.

With reference to the aforementioned figures, the shock absorber according to the invention, generally indicated in the three embodiments with the reference numbers la, 1b, le, comprises a body of the shock absorber 2 which defines, inside it, a chamber 3 which contains a fluid and which slidably houses a piston 4 which is movable along an actuation direction, indicated by the arrow 5, relative to the body of the shock absorber 2.

The piston 4 divides the chamber 3 into two parts, respectively a first part 6 and a second part 7, which are located on opposite sides relative to the piston 4 along the direction of actuation 5.

The first part 6 of the chamber 3 is in communication with the second part 7 of the chamber 3 through at least one connection port which is defined in the piston 4 and / or between the piston 4 and the side walls of the chamber 3 in such a way as to allow the passage of the fluid from the first part 6 to the second part 7 or vice versa and, consequently, to allow the piston 4 to slide relative to the body of the shock absorber 2 along the operating direction 5 in one direction or in the opposite direction. The connecting ports, or at least part of them, have a passage section for the fluid which is variable at least once in the stroke of the piston 4 along the direction of actuation 5 relative to the shock absorber body 2.

More particularly, in all the embodiments illustrated, the chamber 3 is defined in an element 8 of the shock absorber body 2 which is substantially tub-shaped. The plunger 4 is housed in the tub element 8 and is connected to a slider 9 which is placed to close the open side of the tub element 8 and which can slide relative to the tub element 8 along the direction of actuation 5. A sealing gasket 10 is interposed between the edge of the open side of the tub element 8 and the slider 9, which can be constituted, as illustrated, by a gasket of the X-Ring or Q-Ring type.

Preferably, the shock absorber body 2 comprises a tubular body 11 which houses the tub element 8 and the slider 9 and which is oriented with its axis parallel to the direction of actuation 5. The slider 9 protrudes with at least one of its ends from an axial end of the tubular body 11.

In the illustrated embodiments, one end of the slider 9 is shaped like a fork 9a and is constantly placed, in any position of the stroke of the slider 9 relative to the body of the shock absorber 2 along the direction of actuation 5, outside the tubular body 11, while the opposite end, when the slider 9 is at the end of its stroke corresponding to the maximum distance of the fork-shaped end 9a of the slider 9 relative to the tubular body 11, is flush with an axial end of the tubular body 11.

Preferably, the chamber 3 and the piston 4, as well as the tub element 8 and the tubular body 11 that surrounds it, have a substantially rectangular conformation in a plane perpendicular to the direction of actuation 5.

The at least one connecting port, which connects the first part 6 of the chamber 3 with the second part 7 of the chamber 3 comprises a first port 12 which is defined between a first side wall 13 of the chamber 3, parallel to the direction of actuation 5, and the side of the piston 4 which faces this first side wall 13 of the chamber 3. This first port 12 has a passage section for the fluid with at least one variation along the actuation stroke of the piston 4 relative to the body of the shock absorber 2 .

Preferably, the first side wall 13 of the chamber 3 is constituted by the wall of the chamber 3 which is opposite to the side of the tub element 8 closed by the slider 9. The smaller passage section of the first opening 12 is defined by a section of the first side wall 13 which protrudes more towards the piston 4 than the remaining part of the first side wall 13.

More particularly, the first side wall 13 of the chamber 3 has, in its zone which is affected by the stroke of the piston 4 along the direction of actuation 5, at least a first portion 14 and at least a second portion 15 which lie in planes parallel to each other and to the direction of actuation 5. The second portion 15 of the first side wall 13 protrudes towards the piston 4 to a greater extent than the first portion 14 in such a way as to define, for the first port 12, a passage section for the fluid which is greater along the first section 14 and a passage section for the minor fluid along the second section 15.

Conveniently, the first section 14 and the second section 15 of the first side wall 13 are connected to each other by means of an inclined section 16.

The at least one port connecting the first part 6 with the second part 7 of the chamber 3 comprises a second connecting port which may consist of a hole 17 which passes through the piston 4. As illustrated in the second embodiment, the second port connection, in addition to or as an alternative to the hole 17, can be constituted by a port 27 which is defined between at least a second side wall of the chamber 3, parallel to the direction of actuation, and the side of the piston 4 facing it, as best will be detailed later.

Advantageously, unidirectional valve means 50 are arranged on this second port to allow the fluid to pass in one direction only. These unidirectional valve means 50 actuate the opening of the second port 17 and / or 27 in the sliding of the piston 4 along the direction of actuation 5 in one direction and effect the closing of the second port 17 and / or 27 during the sliding of the piston 4 along the the actuation direction 5 in the opposite direction.

Preferably, the minor passage section of the first port 12 is defined in the final portion of the actuation stroke of the piston 4 in the sliding direction which closes the one-way valve means 50.

More particularly, in the first embodiment, the connection between the first part 6 and the second part 7 of the chamber 3 is made by the first port 12 and by the hole 17 which passes through the piston 4 and constitutes the second port. The one-way valve means 50, in this first embodiment, consist of a one-way valve which is arranged on the hole 17. This one-way valve can simply consist of a ball 18 which meets the end of the hole 17 facing the second part 7 and which is held near the hole 17 by a transverse pin 19 connected to the piston 4. In practice, the ball 18 allows the passage of the fluid exclusively from the first part 6 to the second part 7 of the chamber 3 while preventing the passage of the fluid in opposite direction, i.e. from the second part 7 to the first part 6 of the chamber 3.

In the second embodiment, in addition to the hole 17, two second ports 27 are provided between two second side walls 20, 21 of the chamber 3 which extend from the first side wall 13 and which are parallel to the direction of actuation 5 and the two sides 22 , 23 of the piston 4 which face these two side walls 20, 21 of the chamber 3.

In this second embodiment, a block 24 is associated with the piston 4, also crossed by the hole 17 and formed as a lip 25, 26 which engage with the second side walls 20, 21 in the motion of the piston 4 in one direction along the direction of actuation 5, as illustrated in Figure 9, and which disengage from the second alternate walls 20, 21 in the motion of the piston 4 along the direction of actuation 5 in the opposite direction, as illustrated in Figure 11. The lips 25 , 26 of the block 24 constitute the unidirectional valve means 50 which activate the opening of the second ports 27 during the sliding of the piston 4 along the direction of operation in one direction and which act upon closing of the second ports 27 in the sliding of the piston 4 along the actuation direction 5 in the opposite direction.

In the third embodiment, the one-way valve means consist of a one-way valve which is arranged on the hole 17 which passes through the piston 4. As already described with reference to the first embodiment, this one-way valve is simply constituted by a ball 18 which faces the end of the hole 17 facing the second part 7 of the chamber 3 and which is held in proximity to this end of the hole 17 by means of a transverse pin 19.

Advantageously, the shock absorber according to the invention comprises safety means which are suitable for limiting the maximum pressure in one of the two parts 6, 7 of the chamber 3. In the embodiments illustrated, these safety means are suitable for limiting the maximum pressure in the second part 7 of the chamber 3 in such a way as to avoid damaging the shock absorber which could derive from an excessive pressure caused by the application of high and / or impulsive forces to the slider 9.

In the first and third embodiments, these safety means comprise a safety element which is arranged on the side of the piston 4 which delimits the first port 12 and this safety element is elastically yielding due to the overcoming of a predetermined pressure in a of the two parts 6, 7 of the chamber 3 in such a way as to increase the passage section of the first port 12.

More specifically, in the first embodiment, the safety element consists of an elastically deformable gasket 31 which is housed in a seat 32 defined on the side of the piston 4 which faces the first side wall 13.

Preferably, the elastically deformable gasket 31, which can simply consist of an O-Ring, as well as the relative seat 32, also extend to the other two sides of the piston 4 which face the second side walls 20, 21 of the chamber 3.

In the third embodiment, the safety element is constituted by an elastically flexible leaf 33 which is connected with its ends to the piston 4. The leaf 33 is placed on the side of the piston 4 which faces the first side wall 13 of chamber 3 and engages with the second section 15 of the first side wall 13 of chamber 3.

In the second embodiment, the safety means comprise a safety duct 34 which develops in the piston 4, or better in the block 24 which is connected to the piston 4, and which connects the first part 6 of the chamber 3 with the second part 7 of the chamber 3. A closing element 35 is arranged on this safety duct 34 which is yielding due to the overcoming of a predetermined pressure in the second part 7 of the chamber 3 in such a way as to put the second part 7 of the chamber 3 in communication with the first part 6 of the chamber 3 to rapidly reduce the pressure inside the second part 7 of the chamber 3. The closing element 35 can simply consist of a plug in synthetic material which has a greater elastic deformability than that of the block 24 in which it is inserted.

For the sake of completeness of description, it must be said that the chamber 3 is closed by a removable plug 40 to allow the chamber 3 to be filled with a fluid which is preferably constituted by a liquid.

Conveniently, the sides of the slider 9 and of the tubular body 11 which face each other are suitably coated with a layer 41, 42 of material with a low coefficient of friction, such as for example the material known commercially by the brand Teflon or other low friction materials. of a known type.

The operation of the shock absorber according to the invention is as follows.

Starting from the position illustrated in Figures 1, 7, 14, which corresponds to the condition of minimum volume for the second part 7 of the chamber 3, and moving the slider 9 along the direction of actuation 5 relative to the body of the shock absorber 2 to the left, i.e. in the direction indicated by the arrow 5a in figures 4, 10, 16, part of the fluid contained in the first part 6 of the chamber 3 is transferred to the second part 7 of the chamber 3 passing through the first port 12, the second port 17 and / or the second ports 27 allowing the translation of the slider 9 and therefore of the piston 4 relative to the body of the shock absorber 2 and opposing a reduced resistance to said translation. In fact, during the translation of the slider 9 in this direction, the ball 18 opens the hole 17 in the first and third embodiments, while in the second embodiment, the lips 25, 26 detach from the second side walls 20, 21 of the chamber 3. In this way, the fluid, in its passage from the first part 6 to the second part 7 of the chamber 3, has at its disposal a passage section sufficiently large not to brake or to brake in a minimal measure the motion of the piston 4 and therefore of the slider 9 relative to the shock absorber body 2.

When a force is applied to the slider 9 in the opposite direction with respect to the previous one, i.e. the slider 9 is translated along the direction of actuation 5 in the direction indicated by the arrow 5b in Figures 5, 12, 17, the unidirectional valve means 50 close the second port , that is the hole 17 in the first and third embodiments, and the second ports 27 in the second embodiment and therefore the fluid in its passage from the second part 7 of the chamber 3 to the first part 6, necessary to allow the translation of the piston 4 and therefore of the slider 9, has overall available a significantly lower passage section than in the previous situation. In practice, the passage section available for the fluid, in the first and third embodiments, is exclusively the first port 12 which, in the end portion of the stroke of the piston 4, is reduced, thus increasing the braking effect of the slider. 9. In the second embodiment, the fluid also has the hole 17 available which remains open.

It should be noted that, in this operating condition, the gasket 31 and the lamina 33 rest against the second section 15 of the first side wall 13 but their elastic deformability in any case allows the fluid to pass from the second part 7 to the first part 6 of the chamber 3. The braking effect obtained in this section can be suitably regulated and modulated by intervening on the viscosity of the fluid or on the elastic deformability of the gasket 31 or of the lamina 33.

In the second embodiment, the braking effect can be regulated and modulated by varying the viscosity of the fluid and the diameter of the hole 17.

In this way, by suitably dimensioning the first port 12, the second port 17 or the second ports 27 it is possible to obtain a practically unbraked motion of the slider 9 relative to the body of the shock absorber 2 in the direction of translation 5a and a braked motion of the slider 9 in its translation in the opposite direction 5b. In particular, it is possible to obtain a high braking effect in the last section of the stroke of the slider 9 relative to the body of the shock absorber 2 in the direction of translation 5b which makes the shock absorber according to the invention particularly suitable to be used for braking, in particular proximity of the closed position, of appliance doors such as ovens, dishwashers or similar or for furnishing components such as doors and drawers.

Should an overpressure occur in the second part 7 of the chamber 3 following the application of an excessive and / or impulsive force to the slider 9, in the sense 5b which involves a reduction in the volume of the second part 7 of the chamber 3, this overpressure is rapidly reduced by the intervention of the safety means which prevent damage or even the bursting of the shock absorber according to the invention.

More particularly, in the first embodiment, an overpressure inside the second part 7 of the chamber 3, when the gasket 31 is in engagement with the second section 15 of the first side wall 13, i.e. in the most critical conditions, the gasket 31 yields more rapidly increasing the passage section available for the fluid and therefore facilitating the passage of the fluid from the second part 7 of the chamber 3 to the first part 6 of the chamber 3, as illustrated in figure 6. In this condition, the branches can also yield of the gasket 31 which engage with the second side walls 20, 21 further increasing the passage section available for the fluid to rapidly reduce the pressure in the second part 7 of the chamber 3.

In the second embodiment, when an overpressure occurs inside the second part 7 of the chamber 3, this overpressure causes the elastically yielding closure element 35 to be compressed, opening the safety duct 34 which connects the second part 7 of the chamber 3 with the first part 6 increasing the passage section available for the fluid, as illustrated in figure 13.

In the third embodiment, an overpressure in the second part 7 of the chamber 3, when the lamina 33 rests on the second portion 15 of the first lateral wall 13, causes a bending of the lamina 33 which detaches this lamina 33 from the second portion 15 to an extent greater than the detachment in the normal operating condition by increasing the passage section available for the fluid that passes from the second part 7 of the chamber 3 to the first part 6 of the chamber 3, as illustrated in figure 18.

In practice it has been found that the shock absorber according to the invention fully achieves the intended aim, since the particular arrangement of the first part and the second part of the chamber containing the fluid allows to reduce, with the same overall dimensions of the shock absorber, transversely to the direction of actuation of the piston, the operating pressures with the same applied forces and, consequently, to obtain greater resistance and duration for the shock absorber according to the invention with respect to known types of shock absorbers.

A further advantage, deriving from the reduction of the operating pressures with the same applied forces, is to stress the shock absorber components to a lesser extent and therefore to achieve a longer life.

The shock absorber thus conceived is susceptible of numerous modifications and variations, all of which are within the scope of the inventive concept; moreover, all the details can be replaced by other technically equivalent elements.

In the embodiment examples described above, individual characteristics reported in relation to specific examples may actually be interchanged with other different characteristics, existing in other embodiments.

In practice, the materials employed, so long as they are compatible with the specific use, as well as the dimensions, may be any according to the requirements and the state of the art.

Claims (19)

CLAIMS 1. Fluid damper, particularly for appliance doors such as ovens, dishwashers or the like or for furnishing components such as doors or drawers, characterized in that it comprises a damper body (2) internally defining a chamber (3) containing a fluid and slidably housing a piston (4) movable along an actuation direction (5) relative to said shock absorber body (2) and dividing said chamber (3) into two parts, respectively a first part (6) and a second part (7), located on opposite sides relative to said piston (4) along said actuation direction (5), said first part (6) of the chamber (3) being in communication with said second part (7) of the chamber ( 3) through at least one connection opening (12, 17, 27) defined in said piston (4) and / or between said piston (4) and the side walls (13, 20, 21) of said chamber (3) to allow the passage of the fluid from said first part (6) to said second part (7) of the chamber (3) or vice versa and consequently to allow the sliding of said piston (4) relative to said shock absorber body (2) along said actuation direction (5) in a direction or in the opposite direction, said at least one connecting port (12, 17, 27) having a passage section for the fluid which varies at least once in the stroke of said piston (4) along said actuation direction (5) relative to said shock absorber body (2). 2. Shock absorber, according to claim 1, characterized in that said at least one connection port (12, 17, 27) has a passage section for the fluid which varies according to the sliding direction of said piston (4) relative to said shock absorber body (2) along said actuation direction (5). 3. Shock absorber, according to claim 1, characterized in that said chamber (3) is defined in an element (8) of said shock absorber body (2) substantially shaped like a tub, said piston (4) being housed in said element tub (8) and being connected to a slider (9) positioned to close the open side of said tub element (8) and sliding relative to said tub element (8) along said operating direction (5), between the edge of the open side of said tub element (8) and said slider (9) a sealing gasket (10) being interposed. 4. Shock absorber, according to one or more of the preceding claims, characterized in that said shock absorber body (2) comprises a tubular body (11) housing said tub element (8) and said slider (9) and oriented with its axis parallel to said actuation direction (5), said slider (9) protruding with at least one of its ends from an axial end of said tubular body (11). 5. Shock absorber, according to one or more of the preceding claims, characterized in that said chamber (3) and said piston (4) have, in a plane perpendicular to said actuation direction (5), a substantially rectangular conformation. 6. Shock absorber, according to one or more of the preceding claims, characterized in that said at least one connection port (12, 17, 27) comprises a first connection port (12) defined between a first side wall (13) of said chamber (3), parallel to said actuation direction (5), and one side of said piston (4) facing said first side wall (13) of said chamber (3), said first connection port (12) presenting a section of passage for the fluid with at least one variation along the actuation stroke of said piston (4) relative to said body of the shock absorber (2). 7. Shock absorber, according to one or more of the preceding claims, characterized in that said first side wall (13) of said chamber (3) is constituted by the wall of said chamber (3) opposite to the side of said tub element (8 ) closed by said slider (9), said minor passage section of said first connection port (12) being defined by a portion (15) of said first side wall (13) more projecting towards said piston (4) than the remaining part of said first side wall (13). 8. Shock absorber, according to one or more of the preceding claims, characterized in that said first side wall (13) of said chamber (3) has, in its area affected by the actuation stroke of said piston (4) along said actuation direction (5), at least a first section (14) and at least a second section (15) protruding towards said piston (4) more than said first section (14) to define, for said first connection port (12), a section of passage for the greater fluid along said first portion (14) and at least one section of minor passage along said second portion (15) of said actuating stroke of the piston (4). Shock absorber, according to one or more of the preceding claims, characterized in that said at least one connection port (12, 17, 27) comprises a second connection port defined by a hole (17) passing through said piston (4). Shock absorber, according to one or more of the preceding claims, characterized in that said at least one connecting port (12, 17, 27) comprises at least one second connecting port (27) defined between at least one second side wall (20, 21 ) of said chamber (3), parallel to said actuation direction (5), and the side (22, 23) of said piston (4) facing it. 11. Shock absorber, according to one or more of the preceding claims, characterized in that, on said second connection port (17, 27), unidirectional valve means (50) are arranged for the passage of the fluid in one direction only, said valve means unidirectional (50) by opening said second connection port (17, 27) in the sliding of said piston (4) along said actuation direction (5) in one direction (5a) and closing said second connecting port (5a) connection (17, 27) in the sliding of said piston (4) along said actuation direction (5) in the opposite direction (5b). 12. Shock absorber, according to one or more of the preceding claims, characterized in that the smaller passage section of said first connecting opening (12) is defined in the final portion of the actuating stroke of the piston (4) in the sliding direction (5b ) closing said one-way valve means (50). 13. Shock absorber, according to one or more of the preceding claims, characterized in that said one-way valve means (50) consist of a one-way valve arranged on said hole (17) passing through said piston (4). 14. Shock absorber, according to one or more of the preceding claims, characterized in that said one-way valve means (50) consist of a lip seal (25, 26) interposed between said piston (4) and of the at least one second side wall ( 20, 21) of said chamber (3). 15. Shock absorber, according to one or more of the preceding claims, characterized in that it comprises safety means (31, 33, 34, 35) suitable for limiting the maximum pressure in one of said two parts (6, 7) of the chamber (3 ). 16. Shock absorber, according to one or more of the preceding claims, characterized in that said safety means comprise a safety element (31, 33) arranged on the side of said piston (4) delimiting said first connection port (12) and / or on the side of said piston (4) delimiting said second connection port (27), said safety element (31, 33) being elastically yielding due to the overcoming of a predetermined pressure in one of said two parts (6, 7) of the chamber (3) to increase the passage section of said first connection port (12) and / or of said second connection port (27). 17. Shock absorber, according to one or more of the preceding claims, characterized in that said safety element is constituted by an elastically deformable gasket (31) housed in a seat (32) defined on the side of said piston (4) facing said first side wall (13) and / or to said second side wall (20, 21) of the chamber (3). 18. Shock absorber, according to one or more of the preceding claims, characterized in that said safety element is constituted by an elastically flexible leaf spring lamina (33) connected with its ends to the side of said piston (4) facing said first wall side (13) of said chamber (3) and engaging with said second portion (15) of said first side wall (13) of said chamber (3). 19. Shock absorber, according to one or more of the preceding claims, characterized in that said safety means comprise a safety conduit (34) developing in said piston (4) and connecting said first part (6) of the chamber (3) with said second part (7) of the chamber (3), on said safety duct (34) being arranged a closing element (35) yielding due to the overcoming of a predetermined pressure in one of said two parts (6, 7) of the chamber (3) to put in communication said first part (6) with said second part (7) of the chamber (3).