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Title:
TAMPERPROOF SCREWING COUPLING SYSTEM FOR VALVE OF A THERMAL/SANITARY PLANT FOR BUILDINGS
Document Type and Number:
WIPO Patent Application WO/2014/122266
Kind Code:
A1
Abstract:
A tamperproof screwing coupling system for valve (102) of a thermal/ sanitary plant for buildings comprises: - a first connecting part (3) and a second connecting part (4) that are mutually couplable through screwing by relative rotation of the first connecting part(3) with respect to the second connecting part (4) around an axis (X) and, - locking means provided on the first part (3) and on the second connecting part (4), arranged to allow such connecting parts to be mutually screwed to a clamping configuration (S), and configured to mutually lock the first connecting part (3) and the second connecting part (4) in the clamping configuration (S), thus preventing a relative unscrewing movement thereof.

Inventors:
CALEFFI MARCO (IT)
Application Number:
PCT/EP2014/052436
Publication Date:
August 14, 2014
Filing Date:
February 07, 2014
Export Citation:
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Assignee:
CALEFFI SPA (IT)
International Classes:
F16K27/00; F16L15/00
Domestic Patent References:
WO2006031386A22006-03-23
Foreign References:
EP2056009A22009-05-06
US5746454A1998-05-05
US3069187A1962-12-18
Other References:
None
Attorney, Agent or Firm:
CANDITO, Rocco et al. (Via E. De Amicis 25, Milan, IT)
Download PDF:
Claims:
CLAIMS

1. Tamperproof screwing coupling system for valve (2; 102; 202; 302) of a thermal/sanitary plant for buildings, comprising:

- a first connecting part (3) and a second connecting part (4) that are mutually couplable through screwing by relative rotation of said first connecting part (3) with respect to said second connecting part (4) around an axis (X),

CHARACTERIZED IN THAT IT COMPRISES

- locking means (5 , 6) provided on said first part (3) and on said second connecting part (4), arranged to allow said first connecting part (3) and said second connecting part (4) to be mutually screwed to a clamping configuration (S), and configured to mutually lock said first connecting part (3) and said second connecting part (4) in said clamping configuration (S), preventing a relative unscrewing movement thereof.

2. Tamperproof screwing coupling system according to claim 1, wherein said locking means (5, 6) substantially project along directions that are orthogonal with respect to said axis (X). 3. Tamperproof screwing coupling system according to claim 2, wherein said locking means (5, 6) comprise a notched circular portion (7; 17) the profile of which extends around said axis (X) according to a plane that is orthogonal to said axis (X).

4. Tamperproof screwing coupling system according to claim 3, wherein said locking means (6) comprise a stop protruding portion (8; 18) shaped for coupling with recess zones (9; 19) defined by said notched circular portion (7; 17).

5. Tamperproof screwing coupling system according to claim 4, wherein said stop protruding portion (8; 18) comprises a locking surface (10; 110) shaped for restingly receiving further locking surfaces (11; 111) of said notched circular portion

(7; 17) to prevent a relative rotation of said first part (3) and of said second connecting part (4) in an unscrewing direction (U).

6. Tamperproof screwing coupling system according to claim 5, wherein said locking surface (10; 110) and said further locking surfaces (11; 111) are oriented according to respective radial planes passing through said axis (X).

7. Tamperproof screwing coupling system according to claim 5 or 6, wherein said stop protruding portion (8; 18) comprises a sliding surface (12; 112) inclined with respect to said locking surface (10; 110), and said notched circular portion (7; 17) comprises further sliding surfaces (13; 113) inclined with respect to said further locking surfaces (11; 111) and suitable for sliding on said sliding surface (12; 112) to allow a screwing rotation (Sr) of said first part (3) with respect to said second connecting part (4).

8. Tamperproof screwing coupling system according to any one of claims 4 to 7, wherein said notched circular portion (7) is obtained on said first connecting part (3), and said stop protruding portion (8) is provided on said second connecting part (4).

9. Tamperproof screwing coupling system according to any one of claims 4 to 7, wherein said notched circular portion (17) is obtained on said second connecting part (4), and said stop protruding portion (18) is provided on said first connecting part (3).

10. Tamperproof screwing coupling system according to claim 9, wherein said stop protruding portion (18) is obtained in a cantilever manner on an edge zone of said first connecting part (3), and is configured to flex elastically substantially radially towards said axis (X) to allow rotation in the screwing direction (Sr) towards said clamping configuration (S).

11. Tamperproof screwing coupling system according to claim 1, wherein said locking means (5, 6) comprises zones that project substantially axially parallel to said axis (X).

12. Tamperproof screwing coupling system according to claim 1 or 11, wherein said locking means (5, 6) projects along longitudinal planes parallel to said axis (X).

13. Tamperproof screwing coupling system according to claim 11 or 12, wherein said locking means (5, 6) comprises a notched circular portion (27; 37) extending around said axis (X) and having raised zones (29; 39) that project from a plane which is orthogonal to said axis (X).

14. Tamperproof screwing coupling system according to any one of claims 11 to 13, wherein said locking means (5, 6) comprises a stop protruding portion (28; 38) shaped to couple with groove zones (26; 36) defined by said notched circular portion (27; 37).

15. Tamperproof screwing coupling system according to claim 14, wherein said stop protruding portion (28; 38) comprises one or more locking surfaces (128; 138) shaped for restingly receiving further locking surfaces (211; 311) of said notched circular portion (27; 37) to prevent a relative rotation of said first part (3) and said second connecting part (4) in an unscrewing direction (U).

16. Tamperproof screwing coupling system according to claim 15, wherein said one or more locking surfaces (128; 138) and said further locking surfaces (211; 311) are oriented according to respective radial planes passing through said axis (X).

17. Tamperproof screwing coupling system according to claim 15 or 16, wherein said stop protruding portion (28; 38) comprises one or more sliding surfaces (212; 312) inclined with respect to said one or more locking surfaces (128; 138), and said notched circular portion (27; 37) comprises further sliding surfaces (213; 313) that are inclined with respect to said further locking surfaces (211; 311) and are suitable for sliding on said one or more sliding surfaces (212; 312) to allow a screwing rotation (Sr) of said first part (3) with respect to said second connecting part (4).

18. Tamperproof screwing coupling system according to any one of claims 11 to 17, wherein said stop protruding portion (28; 38) is provided on said first connecting part (3) and said notched circular portion (27; 37) is obtained on said second connecting part (4).

19. Tamperproof screwing coupling system according to any one of claims 14 to 18, wherein said stop protruding portion (28; 38) is obtained in a cantilever manner on an edge zone of said first connecting part (3), and is configured to flex elastically substantially in a plane parallel to said axis (X) to allow the rotation of said first connecting part (3) only in the screwing direction (Sr) towards said clamping configuration (S).

20. Air venting valve for a thermal plant of a building, comprising a tamperproof screwing coupling system according to any preceding claim, wherein said first threaded connecting part (3) is included in a cap element (50; 60) of said valve (2; 102), and said second threaded connecting part (4) is included in a cup- body (51; 61) of said valve (2; 102).

21. Safety valve for a thermal plant of a building, comprising a tamperproof screwing coupling system according to any one of claims 1 to 19, wherein said first threaded connecting part (3) is included in a sleeve cap (70; 80) of said valve (202; 302), and said second threaded connecting part (4) is included in a cup- body (71; 81) of said valve (202; 302).

Description:
TAMPERPROOF SCREWING COUPLING SYSTEM FOR VALVE OF A THERMAL/SANITARY PLANT FOR BUILDINGS

BACKGROUND OF THE INVENTION

The invention relates to a tamperproof screwing coupling system for a valve of a thermal/sanitary plant for buildings. The system according to the invention, in particular, may be provided on a safety valve or on an air venting valve of a heating plant, or a cooling plant. In particular, the system according to the invention is configured to prevent the accidental or intentional unscrewing of a cap element or a sleeve cap from a cup body or a glass body of the air venting valve or of the safety valve, respectively.

STATE OF THE ART

The state-of-the-art air venting valves for heating plants currently known, for example, of the floating type, comprise a hollow cup-shaped body having a lower connector for the connection to a pipe or a hydraulic equipment. Such valves further comprise superiorly a closing cap screwable on the cup body and having a housing seat for a mobile shutter operatively connected to a control float axially slidable in the cup body.

The closing cap is provided with a thread that is intended to engage with a respective further thread provided on the cup body.

Similarly, the safety valves for heating plants currently known in the state of the art comprise a cup- body to which a sleeve cap is screwed, suitable for housing a venting spring element calibrated to a detemiined pressure value. The sleeve cap is provided with a thread intended to engage with a respective further thread provided on the cup body. A drawback of the above-described air venting valves is given by the possibility of loosening the clamping torque between the cap element and the cup body, especially in the case where the material of the cup element and/or of the cup body is a technopolymer. Of course, this involves considerable risks, particularly when high pressures of the fluid are reached in the heating plant. Furthermore, there is still the risk that an incautious user may unscrew the cap from the cup body, thus exposing him/herself to high risks for his/her own safety.

A similar problem is found in the above-mentioned safety valves, in which the sleeve cap risks to be unscrewed from the cup element.

The above-mentioned problem is caused by the deformation of the sealing threads, due to the continuous cycles of pressure and temperature change. Measures aimed to solve such a problem, such as, for example to provide a glue or an adhesive between the threads of the cap and the threads of the cup body are troublesome, expensive, and also not very efficient.

OBJECTS OF THE INVENTION

An object of the invention is to improve the known air venting and safety valves.

Another object of the invention is to provide a tamperproof screwing coupling system that makes a valve for thermal/sanitary plant safer and more reliable.

Another object of the invention is to provide a tamperproof screwing coupling system that prevents an unscrewing operation of a cap from the cup element of a valve for a thermal/sanitary plant for buildings. BRIEF DESCRIPTION OF THE INVENTION

The above-mentioned objects are achieved by a tamperproof screwing coupling system for a valve of a thermal/sanitary plant for buildings according to claim 1.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention can be better understood and implemented with reference to the attached drawings, that show embodiments thereof by way of non-limiting example, in which:

Figs. 1 and 2 are perspective views of an air venting valve provided with a first version of a tamperproof screwing coupling system according to the invention;

Fig. 2A is an enlarged detail of Fig. 2, schematically showing the operation of the tamperproof screwing coupling system according to the invention;

Fig. 3 shows a cap element of the air venting valve of Fig. 1 , in which a part of the tamperproof screwing coupling system of the invention is incorporated;

Fig. 3 A is an enlarged detail of Fig. 3;

Fig. 4 shows a cup element of the air venting valve of Fig. 1, in which another part of the tamperproof screwing coupling system of the invention is incorporated;

Fig. 4 A is an enlarged detail of Fig. 4;

Fig. 5 shows an air venting valve provided with a second version of the tamperproof screwing coupling system according to the invention;

Fig. 5 A is an enlarged detail of Fig. 5, schematically showing the operation of the tamperproof screwing coupling system according to the invention;

Fig. 6 shows the cap element of the air venting valve of Fig. 5, in which a part of the second version of the tamperproof screwing coupling system is incorporated;

Fig. 6 A is an enlarged detail of Fig. 6;

Fig. 7 shows the cup element of the air venting valve of Fig. 5, in which another part of the second version of the tamperproof screwing coupling plant of the invention is incorporated;

Fig. 7 A is an enlarged detail of Fig. 7;

Fig. 8 shows a safety valve provided with a third version of the tamperproof screwing coupling system according to the invention;

Fig. 8 A is an enlarged detail of Fig. 8;

Fig. 9 shows a sleeve cap of the safety valve of Fig. 8, in which a part of the third version of the tamperproof screwing coupling system is incorporated;

Fig. 9 A is an enlarged detail of Fig. 9;

Fig. 10 shows the cup element of the safety valve of Fig. 8, in which another part of the third version of the tamperproof screwing coupling system of the invention is incorporated;

Figs. 1 1 and 12 show a safety valve provided with a fourth version of the tamperproof screwing coupling system according to the invention;

Fig. 12A is an enlarged detail of Fig. 12, schematically showing the operation of the fourth version of the tamperproof screwing coupling system;

Fig. 13 shows the sleeve cap of the safety valve of Fig. 1 1 , in which a first part of the fourth version of the tamperproof screwing coupling system is incorporated;

Fig. 13A is an enlarged detail of Fig. 13;

Fig. 14 shows the cup body of the safety valve of Fig. 8, in which a second part of the fourth version of the tamperproof screwing coupling system is incorporated;

Fig. 14A is an enlarged detail of Fig. 14. DETAILED DESCRIPTION OF THE INVENTION

With reference to the Figs. 1 to 4, an air venting valve 2 provided with a first version of tamperproof screwing coupling system 1 according to the invention is described. The air venting valve 2 has the function of automatically eliminating, i.e., without the need to manually intervene, the air that builds up in the thermal hydraulic circuits, allowing preventing negative phenomena such as the occurrence of corrosive processes due to oxygen, air pockets localized in the heating bodies, cavitation phenomena in the circulation pumps. The tamperproof screwing coupling system 1 generally comprises a first threaded connecting part 3 and a second threaded connecting part 4, mutually couplable through screwing by relative rotation of the first part 3 with respect to the second connecting part 4 around an axis X. In this specific case, the first part 3 is part of a cap element 50 of the valve 2, while the second part 4 is part of a cup body 51 of the valve 2. The cap element 50, closing the cup body 51 , comprises internally a housing seat for a mobile shutter operatively connected to a control float axially slidable in the cup body 51.

The cap element 50 and/or the cup body 51 in particular are made of a technopolymer.

As it shall be noticed from the following description, the screwing coupling system 1 performs the function of preventing a relative unscrewing of the first connecting part 3 and of the second connecting part 4, i.e., it is a safety unscrewing-proof coupling system.

The system 1 comprises locking means 5 and 6 provided on the first connecting part 3 and on the second connecting part 4, in this case on the cap element 50 and on the cup element 51, respectively, the locking means 5 and 6 being configured to allow the mutual screwing of the first 3 and of the second 4 connecting parts in a screwing direction Sr to a clamping configuration S. The locking means 5 and 6 are further configured for locking therebetween the first connecting part 3 and the second connecting part 4 in the above-mentioned clamping configuration S, preventing a relative unscrewing movement thereof.

According to this first version of the system 1, the locking means 5 and 6 comprises a notched circular portion 7 provided on the first connecting part 3, in this case on the cap element 50. The notched circular portion 7 has a profile extending around the axis X according to a plane orthogonal to the latter one. The notched circular portion 7 has a serrated profile comprising tooth-shaped protrusions defining a plurality of recess zones 9. The tooth- shaped protrusions extend along respective directions that are substantially orthogonal to the axis X. In other terms, the tooth-shaped projecting zones of the notched circular portion 7 project parallel to a transversally arranged plane, in particular orthogonally, to the axis X.

The locking means 6 of the first version of the tamperproof screwing coupling system 1 further comprises, on the second connecting part 4, i.e., on the cup body 51, a stop protruding portion 8 so shaped as to couple with the above-described recess zones 9. The stop protruding portion 8, facing inwardly of the valve 2, projects from an inner surface of a cylindrical wall of the cup body 61 according to a transversal direction, in particular orthogonal to the axis X.

The stop protruding portion 8 and the tooth-shaped zones of the notched circular portion 7 are suitably oriented, taking into account the screwing direction of the two parts 3 and 4, and therefore they are configured to allow a relative rotation in the screwing direction towards the clamping configuration S and to prevent an opposite relative rotation that tends to mutually unscrew the two parts, as indicated by the reference U.

In particular, the stop protruding portion 8 comprises a locking surface 10 shaped so as to restingly receive further locking surfaces 11 of the notched circular portion 7 to prevent a rotation in the unscrewing direction U.

The locking surface 10 and the further locking surfaces 11 are oriented according to respective radial planes passing through the axis X. The stop protruding portion 8 comprises a sliding surface 12 that is inclined with respect to the locking surface 10, while the notched circular portion 7 comprises further sliding surfaces 13 that are inclined with respect to the further locking surfaces 11. The further sliding surfaces 13 are suitable for sliding on the sliding surface 12 to allow the screwing rotation Sr of the cap element 50 with respect to the cup element 51. This is possible by virtue of a certain elasticity of the zone in which the stop protruding portion 8 is provided. In the example described above, as it has been noticed, the notched circular portion 7 is obtained on the cap element 51 , while the stop protruding portion 8 is obtained on the cup body 51. However, in a variant, it is possible to invert the position thereof, providing the stop protruding portion 8 on the cap element 51 and the notched circular portion 7 on the cup body 51.

The operation of the coupling system 1 is described herein below. During a screwing step of the cap element 50 on the cup body 51, the notched circular portion 7 progressively axially reaches the stop protruding portion 8 until touching it and sliding thereupon. This is made possible by the particular configuration of the sliding surface 12 and of the further sliding surfaces 13, suitably oriented to allow the relative rotation between the cap element 50 and the cup body 51 univocally in a direction, indicated by Sr. When the cap element 50 reaches a suitable clamping configuration S on the cup body 51, the locking surface 10 restingly receives one of the further locking surfaces 13, preventing the cap element 50 from rotating to the unscrewing direction U. In other terms, in the screwing step, in particular before the inner abutment between the cap element 50 and the cup body 51, an unscrewing-proof joint is established therebetween, by virtue of the projecting zones of the notched circular portion 7 and the stop protruding portion 8, that act as mutually cooperating hooking and sealing teeth. Therefore, in the clamping configuration S, a robust coupling between the first part 3 and the second part is obtained, the unscrewing being prevented, except for breakages of the locking means, which would thus indicate a tampering of the product. The locking means 5 and 6 of the system 1 act as ratchet safety means, allowing a rotation of the cap element 50 with respect to the cup body 51 only in the screwing direction.

Figs. 5 to 7A show a venting valve 102 similar to the one just described above, but provided with a second version of the tamperproof screwing coupling system 1 according to the invention. In this version also, the locking means comprises a notched circular portion 27, but, unlike the first version of the system 1, it comprises projecting zones projecting according to longitudinal planes parallel to the axis X, in particular they project substantially axially parallel to the axis X, and which are provided on the cup body 61 of the air venting valve 102. The notched circular portion 27 extends around the axis X and comprises relief zones 29 projecting from a plane orthogonal to the axis X.

The locking means 5 comprise a stop protruding portion 28 so shaped as to couple with groove zones 26 defined in the notched circular portion 27.

The stop protruding portion 28 is obtained in a cantilever manner on an edge zone of the first connecting part 3, i.e., on the cap element 60, and it is configured to elastically flex substantially in an axial direction, parallel to the axis X, to allow the rotation in the screwing direction Sr towards the clamping configuration S.

The stop protruding portion 28 comprises, by way of exemplary, non-limiting example, two locking surfaces 128 so shaped as to restingly receive further locking surfaces 211 provided on the notched circular portion 27 to prevent a rotation of the cap element 60 in the unscrewing direction U. The two locking surfaces 128 and the further locking surfaces 211 are oriented according to respective radial planes passing through the axis X.

The stop protruding portion 28 comprises two sliding surfaces 212 inclined with respect to the two respective locking surfaces 128. The notched circular portion 27 comprises further sliding surfaces 213 inclined with respect to the respective further locking surfaces 211 and suitable for slidably receiving the sliding surfaces 212 of the stop protruding portion 28 to allow the screwing rotation Sr of the cap element 60 with respect to the cup body 61. In the example described above, as it has been noticed, the notched circular portion

27 is obtained on the cup body 61, while the stop protruding portion 28 is obtained on the cap element 60. However, in a variant, it is possible to invert the position thereof, providing the stop protruding portion 28 on the cup body 61 and the notched circular portion 27 on the cap element 60.

What has described above for the operation of the first version of coupling system 1 applies mutatis mutandis also to the second version of the system 1 just described.

Two different versions of the safety valve are now described, which are provided with the tamperproof screwing coupling system 1 implemented according to two different possible embodiments.

With reference to the Figs. 8 to 10, a safety valve 202 is shown, provided with a third version of the tamperproof screwing coupling system 1 according to the invention. The safety valve 202 comprises a cup body 71 provided with connections 74 and 75 for the connection to a pipe of a plant, and a sleeve cap 70 that is threaded and hollow to house therein a venting spring member calibrated to a given pressure value which is found in predetemiined operative conditions. The function of the safety valve 202 is to control the pressure in plants, such as hydraulic or heating plants, etc. Upon reaching a desired calibration pressure, the safety valve 202 intervenes, by opening and releasing the overpressure to the atmosphere, thus preventing the plant from reaching dangerous pressure limits.

In this version, the locking means 5 and 6 comprises a notched circular portion 17 the profile of which extends around the axis X according to a plane orthogonal to the axis X, and a stop protruding portion 18 so shaped as to couple with recess zones 19 obtained in the notched circular portion 17. The relief zones of the notched circular portion 17 and the stop protruding portion 18 extend along directions that are oriented orthogonally to the axis X.

The stop protruding portion 18 comprises a locking surface 110 so shaped as to rest on further locking surfaces 111 of the notched circular portion 17 to prevent a relative rotation of the sleeve cap 70 with respect to the cup body 71 in the unscrewing direction U. The above-mentioned locking surface 110 and the further locking surfaces 111 are oriented according to respective radial planes passing through the axis X. The stop protruding portion 18 comprises a sliding surface 1 12 inclined with respect to the locking surface 110, while the notched circular portion 17 comprises further sliding surfaces 113 inclined with respect to the respective further locking surfaces 111. The further sliding surfaces 113 are oriented to allow a sliding thereupon of the sliding surface 112 only in the screwing direction Sr. The stop protruding portion 18 is obtained in a cantilever manner on an edge zone of the sleeve cap 70, and it is configured to elastically flex substantially radially towards the axis X to allow the rotation in the screwing direction Sr towards the clamping configuration S.

In a variant, it is possible to provide the notched circular portion 17 on the sleeve cap 70, and the stop protruding portion 18 on the cup body 71.

The operation of this version of the system 1 is similar to what has described above for the operation of the first and the second versions of the coupling system 1. Figs. 11 to 14 show a safety valve 302 similar to the one just described, but provided with a fourth version of the tamperproof screwing coupling system 1 according to the invention, partially similar to the second version of the coupling system 1 described with reference to the Figs. 5 to 7. In this version, the locking means 6 includes a notched circular portion 37 comprising relief zones 39 projecting according to longitudinal planes parallel to the axis X, in particular, they project substantially axially parallel to the axis X and are provided on the cup body 81 of the safety valve 302. The notched circular portion 37 extends around the axis X, and the relief zones 39 project from a plane orthogonal to the axis X.

The locking means 5 comprise a stop protruding portion 38 so shaped as to couple with groove zones 36 defined in the notched circular portion 37.

The stop protruding portion 38 is obtained in a cantilever manner on an edge zone of the sleeve cap 80, and it is configured to elastically flex substantially in an axial direction, parallel to the axis X, to allow the rotation in the screwing direction Sr towards the clamping configuration S.

The stop protruding portion 38 comprises a locking surface 138 (best shown in Fig. 13 A), so shaped as to rest onto further locking surfaces 31 1 of the notched circular portion 37 to prevent a rotation of the sleeve cap 80 in the unscrewing direction S.

The locking surface 138 and the further locking surfaces 311 are oriented according to respective radial planes passing through the axis X. The stop protruding portion 38 comprises a sliding surface 312 that is inclined with respect to the locking surface 138, while the notched circular portion 37 comprises further sliding surfaces 313 inclined with respect to the respective further locking surfaces 311. The sliding surface 312 is suitable for sliding along the further sliding surfaces 313 in the screwing step.

The operation principle of this version of the system 1 is similar to the previous versions described.

In a possible variant, it is possible to invert the position of the locking means, providing the stop protruding portion 38 on the cup body 81 and the notched circular portion 37 on the sleeve cap 80.

The tamperproof screwing coupling system 1 may also be applied to further types of valves, not only the safety valves or the air venting valves having the above-described configurations.

From what has been described above, it follows that all the versions of a tamperproof screwing coupling system for a valve described above have in common some characteristics as explained herein below. In all the versions, the locking means 5 and 6 comprises a notched circular portion (7; 17; 27; 37, respectively) extending around the axis X, and one or more stop protruding portions (8; 18; 28; 38, respectively) so shaped as to be coupled with the respective notched circular portion (7; 17; 27; 37).

An important feature, shared by all the versions described above, is to be pointed out. In all the versions, each stop protruding portion (8; 18; 28; 38) is configured so as not to project outwardly with respect to the first part 3 and the second part 4 in the clamping configuration S. In other terms, when the first connecting part 3 and the second connecting part 4 are mutually coupled in the coupled clamping configuration S, each stop protruding portion 8, 18, 28, 38 is contained in the volume defined by an outer surface of the valve, particularly by a surface defined by the coupling of the two parts 3 and 4. In other terms, in the clamping configuration S, there are no zones of the stop protruding portions 8, 18, 28, 38 projecting outwardly. In equivalent terms, the surfaces of the stop protruding portions 8, 18, 28, 38 are innermost located with respect to the outer surfaces of the first part 3 and the second part 4 in the clamping configuration S. The exposed surfaces of the stop protruding portions 8, 18, 28, 38 are recessed, or at most flush with the outer surfaces of the connecting parts 3 and 4.

This involves that, in the clamping configuration S, each stop protruding portion 8, 18, 28, 38 is hardly reachable or even inaccessible for a user. By virtue of such configuration, any possible accidental or intentional action from the outside is prevented, on the stop protruding portion, thereby preventing the undesired mutual unscrewing of the two parts 3 and 4. Therefore, a tampering of the system is more efficiently prevented.

A further important feature shared by all the versions described above is to be pointed out. In all the versions, the first connecting part 3 and the second connecting part 4 are configured so that, in the clamping configuration S, each stop protruding portion

8; 18; 28; 38 is visible from outside. The visibility from outside of the stop protruding portions 8; 18; 28; 38, particularly when the two parts 3 and 4 are mutually coupled, advantageously provides a clear indication of a possible occurred tampering. In other terms, even when the two parts 3 and 4 are in a mutually coupled configuration, i.e., in an operative configuration, it is possible to visually inspect from the outside in a simple and immediate manner, and to verify the possible tampering of a valve. If an anomaly, damage, failed integrity, breakage, or even the absence of a stop protruding portion 8; 18; 28; 38 are noticed, the indication is immediately given, that an opening of the valve is occurred or attempted. Therefore, the coupling system also performs a tampering indication function. In other terms, the locking means 5 and 6 also act as tampering indicating means, providing information that may be useful in several circumstances or for different aims.

From what has been indicated above, it shall be apparent that the coupling system 1 according to the invention is efficient and reliable, while being constructively simple and inexpensive to be manufactured.

In particular, by virtue of the system 1 according to the invention, it is possible to obtain a safer and more reliable air venting valve, or safety valve for a plant, such as a heating plant, a hydraulic/sanitary plant, a cooling plant, etc. Owing to the system 1 according to the invention, it is possible to prevent accidental or intentional loosening or unscrewing operations of the cap from the cup element of a valve, thus preserving the safety of an individual who may imprudently attempt to break the valve, and thereby making the respective plant safer. Furthermore, the system allows obviating the clamping loosening problem due to temperature and pressure changes, which subject the material to continuous stresses.

What has been stated and shown with reference to the attached drawings was given by way of mere exemplary, illustrative example of the general characteristics of the invention, as well as of some preferred embodiments thereof; therefore, other modifications and variations are possible, without for this departing from the scope of the claims. It is possible to shape and size the coupling system 1 in the desired manner as a function of the particular applications and as a function of the type and geometry of valve in which it is desired to incorporate the system 1. Finally, the used materials may be selected according to the needs, provided that they are suitable for the specific use for which they are intended.