A VALVE ASSEMBLY FOR PRESSURIZED CONTAINERS

Abstract

A valve assembly for pressurized containers includes a main structure, a rotary control element rotatably connected to the main structure and configured so as to allow a gas flow through the valve assembly in accordance with an angular position thereof about a main rotation axis, a detection device which includes an angular position sensor and a movable member. The angular position sensor is configured to detect the angular position of the movable member about an auxiliary rotation axis. The movable member is rotatably supported on the main structure and the angular position sensor is fixed to the main structure. The valve assembly further includes a movement conversion mechanism configured so as to convert the movement of the rotary control element about the main axis into a corresponding rotational movement of the movable member about the auxiliary axis which is different with respect to the main rotation axis.

Claims

1. A valve assembly (100) for pressurized containers, the valve assembly comprising a main structure (101), a rotary control element (1) which is rotatably connected to the main structure (101) and which is configured so as to allow a gas flow through the valve assembly in accordance with an angular position (a) of said rotary control element (1) about a main rotation axis (X), a detection device (2) which includes an angular position sensor (20) and a movable member (21), the angular position sensor (20) being configured to detect the angular position of the movable member (21) about an auxiliary rotation axis (Y), wherein the movable member (21) is rotatably supported on the main structure (101) and the angular position sensor (20) is fixed to the main structure (101), wherein the valve assembly (100) further comprises a movement conversion mechanism (3) which is configured so as to convert the movement of the rotary control element (1) about the main axis (X) into a corresponding rotational movement of the movable member (21) about the auxiliary axis (Y), the auxiliary axis (Y) being different with respect to the main rotation axis (X).

2. The valve assembly (100) according to claim 1, wherein the movement conversion mechanism (3) comprises a first toothed portion (31) which is fixedly joined to the control element (1) in terms of rotation and a second toothed portion (32) which is fixedly joined to the movable member(21) in terms of rotation and which engages with the first toothed portion (31).

3. The valve assembly (100) according to claim 2, wherein the first toothed portion (31) is constructed at a collar (11) which is formed in the control element (1).

4. The valve assembly (100) according to claim 3, wherein the control element (1) comprises a gripping portion (10), the collar (11) being formed in a position, during use, which is lower than the gripping portion (10).

5. The valve assembly (100) according to claim 1, wherein the angular position sensor (20) is a TMR magnetic tunnel effect angle sensor.

6. The valve assembly (100) according to claim 1, wherein the angular position sensor (20) defines a detection axis (U′), the auxiliary axis (Y) being aligned with the detection axis (U′).

7. The valve assembly (100) according to claim 1, wherein the movable member (21) comprises a substantially disk-like magnet (21A), the magnet (21A) being coaxial with the auxiliary rotation axis (Y).

8. The valve assembly (100) according to claim 1, wherein the main structure (101) comprises a support arm (101A) which projects radially with respect to the direction defined by the main rotation axis (X) and which is configured to support the angular position sensor (20).

9. The valve assembly (100) according to claim 1, wherein the main rotation axis (X) is perpendicular to the auxiliary rotation axis (Y).

10. The valve assembly (100) according to claim 1, wherein the auxiliary rotation axis (Y) is parallel and non-aligned with the main rotation axis (X).

11. The valve assembly (100) according to claim 1, further comprising a display device (103) which is configured so as to indicate parameters or characteristic conditions of a gas present inside a gas cylinder (B), to which the valve assembly is applied.

12. The valve assembly (100) according to claim 11, wherein the display device comprises a display.

13. The valve assembly (100) according to claim 1, further comprising a control device, the angular position sensor (20) being configured so as to transmit to the control device data items in relation to the angular position of the rotary control element (1), the control device being configured to determine characteristic parameters of a gas during the passage thereof through the valve assembly (100) in accordance with the data items in relation to the angular position of the rotary control element (1).

14. The valve assembly (100) according to claim 13, wherein the control device is interfaced with a display device (103) so as to display the characteristic parameters of a gas.

15. The valve assembly (100) according to claim 13, wherein the characteristic parameters of the gas comprise a residual supply time of the gas contained in a gas cylinder.

16. A method for determining a residual supply time for a gas present in a gas cylinder (B) comprising a valve assembly (100) according to claim 1, the method comprising: rotating the rotary control element (1) in order to allow a flow of gas being discharged of the gas cylinder (B); detecting the angular position (a) of the rotary control element (1) by means of the angular position sensor (20); estimating the residual supply time by means of a plurality of parameters including the angular position (a) of the rotary control element (1).

17. A method for determining a residual supply time of a gas present in a gas cylinder (B), comprising a valve assembly (100) according to claim 11, the method comprising: rotating the rotary control element (1) in order to allow a flow of gas being discharged of the gas cylinder (B); detecting the angular position (a) of the rotary control element (1) by means of the angular position sensor (20); estimating the residual supply time by means of a plurality of parameters including the angular position (a) of the rotary control element (1); and displaying the residual time by means of the display device.

Description

[0032] The features and advantages of the invention will be better appreciated from the detailed description of a number of embodiments thereof which are illustrated by way of non-limiting example with reference to the appended drawings, in which:

[0033] FIG. 1 is a perspective view of a valve assembly according to the present invention;

[0034] FIG. 2 is a perspective sectional view of a detail of the valve assembly of FIG. 1;

[0035] FIG. 3 is a perspective view of a valve assembly according to an alternative embodiment of the present invention;

[0036] FIG. 4 is a perspective view of a valve assembly according to the present invention during the use of a pressurized container;

[0037] FIG. 5 is a schematic illustration of a detection device used in the valve assembly of the present invention; and

[0038] FIG. 6 is a perspective view of a valve assembly according to another alternative embodiment of the present invention.

[0039] Initially with reference to FIG. 1, a valve assembly according to the present invention is generally designated 100.

[0040] The valve assembly 100 is of the type intended to be used in pressurized containers, for example, a gas cylinder B, in order to control the discharge and where applicable the introduction during the recharging step, of the pressurized gas present inside the container, as illustrated in the embodiment depicted in FIG. 4.

[0041] The valve assembly 100 may advantageously be combined with a protection shell 102 which is provided where applicable with a handle, and a display or other display device 103 capable of indicating parameters or conditions characteristic of the gas present inside the container.

[0042] Preferably, the valve assembly 100 comprises a control element 1 which can partially project from the protection shell 102 in order to allow the manual actuation thereof by acting on a suitable gripping portion 10.

[0043] On the basis of an aspect of the invention, when the control element 1 is rotated in one direction, there is released a passage of gas being discharged by the valve assembly 100 while a rotation in the opposite direction then brings about the closure thereof again. To this end, the valve assembly 100 may comprise an interception device which is not illustrated in the Figures and which is capable of intercepting a gas discharge opening. When the interception device is closed, the discharge of the gas is prevented while, by rotating the control element, the interception device is opened and the gas can be supplied.

[0044] The rotation of the control element 1 is preferably carried out about a main rotation axis X.

[0045] Now with reference to FIG. 1, the valve assembly of the present invention further comprises a detection device 2, by means of which there can be determined, indirectly, the angular position α of the control element 1. In this manner, the detection device 2 may detect any rotations of the control element 1 and the resultant opening of the interception device and therefore generally of the valve assembly 100.

[0046] In some embodiments, the detection device 2 includes an angular position sensor 20 and a movable member 21, preferably comprising a magnet 21A, as better illustrated in the example of FIG. 2.

[0047] The movable member 21 is advantageously rotatably supported on the main structure about an auxiliary rotation axis Y.

[0048] As will be better appreciated below, the auxiliary rotation axis Y is different with respect to the main rotation axis X of the control element. In other words, the two axes are not aligned with each other.

[0049] In some embodiments, such as the one illustrated in FIG. 1, the rotation axis Y is perpendicular to the rotation axis X.

[0050] In some construction variants, the rotation axis Y may be parallel and not aligned with the axis X.

[0051] Generally, the detection device is arranged laterally relative to the control element 1, that is to say, arranged at the side thereof in a radial direction with respect to the axis X.

[0052] According to another aspect of the invention, the angular position sensor 20 is configured to detect the angular position of the movable member 21 about the auxiliary rotation axis Y.

[0053] To this end, the movable member 21 is advantageously supported rotatably on the main structure 101 and the angular position sensor 20 is fixed to the main structure 101.

[0054] In some embodiments, the main structure 101 may comprise a support arm 101A which projects radially with respect to the direction defined by the main rotation axis X and which is configured to support the angular position sensor 20.

[0055] In preferred embodiments, the angular position sensor 20 is a magnetic tunnel effect angle sensor (TMR).

[0056] As may be observed from the example of FIG. 5, the angular position sensor 20 preferably defines a detection axis Y′ which is, where applicable, formed by the geometric centre of the sensor 20 and which may advantageously be aligned with the auxiliary axis Y.

[0057] In other words, the magnet 21A and the sensor are coaxial so as to optimize the operation of the device.

[0058] It will be appreciated that, in some embodiments, the magnet 21A has a substantially disk-like form and is precisely coaxial with the auxiliary rotation axis Y.

[0059] In order to transmit the movement from the control element 1 to the movable member 20, the valve assembly 100 comprises a movement conversion mechanism 3.

[0060] The movement conversion mechanism 3 is advantageously configured so as to convert the movement of the rotary control element 1 about the main axis X into a corresponding rotational movement of the movable member 21 about the auxiliary axis Y.

[0061] The movement may advantageously be brought about with a gearing-up gear ratio in order to increase the sensitivity of the sensor. In some embodiments, such as, for example, the one illustrated in FIG. 6, a movement reduction unit 33 may be provided.

[0062] In some embodiments, the movement conversion mechanism 3 comprises a first toothed portion 31 which is fixedly joined to the control element 1 in terms of rotation and a second toothed portion 32 which is fixedly joined to the movable member 20 in terms of rotation and which engages with the first toothed portion 31.

[0063] In other words, the transmission of the movement can be carried out by means of a gear system.

[0064] In the example of FIG. 6, the reduction unit is advantageously formed by a pair of coaxial gears which engage with the first toothed portion 31 and the second toothed portion 32, respectively.

[0065] Naturally, there may in any case be provided other movement transmission systems, such as, for example, ones using friction, and other types of reduction units.

[0066] Preferably, the first toothed portion 31 is constructed at a collar 11 which is formed in the control element 1, as depicted more clearly in FIG. 2.

[0067] In some embodiments, the collar 1 is formed in a position, during use, lower than the gripping portion 10 so that the presence of the movement conversion mechanism 3 does not make it impossible to manipulate the control element 1.

[0068] Therefore, it will be appreciated that the valve assembly according to the present invention allows the implementation of effective detection of the angular position of the control element 1 without requiring complex construction solutions or substantial variations during the construction of the control element 1.

[0069] The data item obtained by the sensor can further advantageously be transmitted, preferably by means of a suitable wire 22, to a control device which is advantageously integrated in the display 103 in order to take account of the position of the control element 1 during the establishment of the characteristic parameters of the gas, both during the storage step in the gas cylinder and during the supply step.

[0070] In preferred embodiments, therefore, this information can be used to establish a residual supply time for the gas present inside the gas cylinder. In other words, when the supply of the gas takes place by acting on the control element 1, the angular position thereof can be detected in a substantially immediate manner by means of the position sensor 20.

[0071] This data item can advantageously be used to estimate, where applicable in conjunction with other parameters, such as, for example, pressure of the gas cylinder and/or dimensions thereof, the flow of gas being discharged and, consequently, the residual supply time. This solution advantageously allows the acquisition of a value which is also sufficiently reliable in limited situations, for example, in the first moments of opening or with the gas cylinder being depleted.

[0072] In order to obtain the estimate of the residual time according to what has been set out above, the angular position sensor 20 can advantageously be configured so as to transmit to the control device the data items acquired in relation to the angular position of the rotary control element 1.

[0073] The control device may further be interfaced with the display device 103 so as to display the estimated residual time or other characteristic parameters of the gas present inside the gas cylinder.

[0074] In this manner, the user can be readily informed about the duration of possible supply of gas by the gas cylinder, limiting the risks of depletion of the gas.