ITMI20120535A1 - COUNTER DEVICE FOR FUEL GAS - Google Patents

Description

Fuel gas meter device

DESCRIPTION

TECHNICAL FIELD

The present invention relates to the sector of meter devices for combustible gas, such as methane or the like, according to the preamble of claim 1. STATE OF THE ART

Metering devices for combustible gases are known in the state of the art, comprising a measurement compartment and a compartment for housing the electronic components.

The measurement compartment is closed towards the outside and at least two ducts are connected to it, one for the delivery and one for the outlet of a gas.

In the measurement compartment there are one or more sensors for measuring the quantity of gas that is delivered, for example by means of a measurement of the volumetric type, flow rate or the like.

These sensors transmit the data detected in the measurement compartment to an electronic control unit housed in a separate compartment for housing the electronic components, in order to prevent a spark caused by a possible malfunction of the latter from triggering an explosion of the gas flowing into the compartment. of measurement.

To this end, the two compartments (measuring and housing the electronics) are physically adjacent to each other but separated by a septum through which the connectors that transmit the signals at least from the sensor to the control unit pass.

For this purpose, one or more gaskets are arranged around the connectors, which prevent gas from passing through the septum and accumulating in the electronics housing compartment.

A common problem of these counter devices (or counters) is linked to the fact that over time the watertightness guaranteed by the gasket in the passage area of the connectors tends to reduce, both due to the obsolescence of the gasket material and the effect of possible thermal deformation cycles. A reduction in watertightness causes the passage of gas from the measurement compartment to that housing the electronics, with the risks described above.

To avoid this problem, a periodic check of the integrity of the gasket and its preventive replacement is currently planned.

A further problem that can be noted, even in the condition of an intact gasket, is related to the passage of gas in the electronics housing compartment following osmotic processes that take place in the rubber of the gasket.

In this case, the programmed replacement or the gasket check becomes useless, effectively exposing the meter to a relatively high risk of explosion, made all the more important by the fact that the electronics housing compartment is immediately adjacent to the measurement one. , which contains significant quantities of gas and which is connected to the power supply network and to the user.

PURPOSE AND SUMMARY OF THE INVENTION

It is an object of the present invention to overcome the disadvantages of the known art.

In particular, the purpose of the present invention is to provide a fuel gas meter device in which any gas leakage in the area of the connectors of the measuring compartment does not cause the adjacent electronics housing compartment to be filled. .

Another object of the present invention is to provide an intrinsically safe gas meter device, in which a possible cracking of the gasket or an osmotic phenomenon of the gas in it cannot cause the electronics housing compartment to fill. The idea behind the present invention is to provide a fuel gas meter device comprising a single shell that incorporates a measurement compartment and one for the electronics that are separated by a gap crossed by a physical transmission line data from a sensor placed in the measurement compartment to an electronic control unit located in the electronics compartment, said interspace being in fluid communication with an environment outside the shell.

In this way, the drawbacks of the known art are overcome, since in the event of a gas leakage from the measurement compartment, the gas flows into the cavity, and from this towards the external environment, preventing filling of the electronics compartment.

Furthermore, in this way, any problems related to the formation of osmotic processes in the rubber of the gasket of the physical data transmission line from the sensor to the control unit are also prevented: in the event of a possible passage of gas through this gasket, in fact, the gas flows back into the gasket. Cavity and from this to the outside, with the same advantages discussed above.

Further advantageous characteristics of the present invention are the subject of the attached claims which are intended as an integral part of the present description.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be described hereafter with reference to non-limiting examples, provided for explanatory and non-limiting purposes in the annexed drawings. These drawings illustrate different aspects and embodiments of the present invention and, where appropriate, reference numerals illustrating similar structures, components, materials and / or elements in different figures are indicated by similar reference numerals. Fig. 1 illustrates a sectional view of a basic form of a counter device according to the present invention;

figs. 2 and 3 are sectional views of the measurement compartment and of the housing compartment for the electronics of the counter device of the previous figure;

fig. 4 is a perspective view of the counter device of the preceding figures; figs. 5 and 6 show two moments in the manufacture of the counter device of the preceding figures;

figs. 7 and 8 show details of the counter device of the present invention; fig. 9 shows another detail of the counter device of the present invention; fig. 10 shows a detail of an electrical connection of the meter device of the invention;

fig. 11 shows another moment of the manufacture of the counter device of the preceding figures;

figs 12 and 13 show details of the gas escape route from a cavity of the meter device of the invention;

fig. 14 and 15 show two moments of manufacture of a variant of the counter device of the present invention;

fig. 16 and 17 show details of the variant of figs. 14 and 15.

DETAILED DESCRIPTION OF THE INVENTION

While the invention is susceptible of various modifications and alternative constructions, some related embodiments illustrated are shown in the drawings and will be described in detail below. It must be understood, however, that there is no intention to limit the invention to the specific embodiment illustrated, but, on the contrary, the invention intends to cover all modifications, alternative constructions, and equivalents that fall within the Scope of the invention as defined in the claims.

The use of â € œfor exampleâ €, â € œeccâ €, â € œorâ € indicates non-exclusive alternatives without limitation unless otherwise indicated. Use of â € œincludeâ € means â € œinclude, but not limited to â € unless otherwise indicated.

Figures 1 to 3 show a basic form of a fuel gas meter device according to the present invention, indicated as a whole with the reference 1.

It comprises an outer shell 2, which incorporates all the functional parts of the counter device 1 itself.

More in detail, the outer shell 2 comprises a measurement compartment 3 in fluid communication with at least one inlet duct 10 and one outlet 11 for a combustible gas.

Typically the inlet duct 10 is connected to a fuel gas supply network, while the outlet duct 11 is connected to a user that can be fed with said combustible gas (e.g. a cooking appliance, a boiler or the like).

The measurement compartment 3 is internally provided with at least one sensor 4 for measuring a quantity indicative of a volume of said combustible gas delivered by said counter device 1.

In particular, the sensor 4 is shown in the figure as a simple black box, as it can be of different types, according to preferences, without this impacting on the present invention: in particular, the sensor 4 can be of the mass type, ultrasound. o electronic ionization; these types of sensors are known per se and therefore we will not dwell any further.

In any case, the sensor 4 detects data which are directly or indirectly indicative of the volume of gas that is delivered from the duct 11 and transmits them to an electronic control unit 6 for their subsequent processing / recording.

Said electronic control unit 6 for detecting the data sent by the sensor 4 is located in the housing compartment 5 of the electronics.

Also in this case the type of electronic control unit can change according to the needs of realization, without this substantially impacting on the present invention.

As can be seen, the sensor 4 and the electronic control unit 6 are connected to each other by means of a physical data transmission line 7.

The term â € œphysical data transmission lineâ € here means to indicate a line that includes at least one, preferably several solid connectors, such as pins, rigid connections, conductor wires or the like; in this sense, any wireless connections (wireless) - radio, bluetooth or similar - which would involve the insertion in the measurement compartment 3 of a transmission apparatus that must be electrically powered, with negative consequences in terms of safety (in the measurement compartment 3 in fact the combustible gas is present in a very high concentration and therefore the presence of any electrical power supply is to be considered inadvisable in order to avoid triggering unwanted explosions in the event that there is an infiltration of oxygen or air and the ratio reaches the stoichiometric one).

In accordance with the teachings provided herein, the shell 2 also comprises an interspace 8 which separates, at least in part, the measurement compartment 3 from the electronics housing compartment 5 and which is arranged in correspondence with the physical data transmission line 7; in other words, it can be seen from the attached figures 1-3 how the physical data transmission line 7 (which in this example comprises a male / female socket with rigid connectors) crosses said interspace 8.

The latter is in fluid communication with an environment external to the meter device 1, for example by means of suitable passages or ducts 80 (which will be described in detail hereinafter), so that any gas that may have escaped from the measurement compartment 3 in correspondence of the physical data transmission line 7 is conveyed outside, thus advantageously preventing both its concentration in the cavity and its diffusion in the electronics housing compartment 5.

In this regard it is useful to refer to figs. 12 and 13 in which an arrow indicates a possible path P for the escape of the gas which may have accumulated in the cavity.

In the embodiment shown by way of example in these figures, the inlet duct 10 and the outlet duct 11 comprise a terminal union which is sealed connected to the measurement compartment 3 (as shown in figure 13 for the duct 10 only, similar to the duct 11).

To allow the evacuation of any gas that may have accumulated in the cavity 8, the ducts 80 are provided, which put the cavity 8 in fluid communication with the environment external to the meter device 1.

These ducts 80 are, in this example, obtained in the material of the shell 2B, in particular in correspondence with the wall of the shell 2B which carries the unions of the ducts 10 and 11 and extend from the interspace 8 to the outside, opening in a position adjacent to the filler.

It should be noted right now that these ducts 80, instead of being obtained with suitable passages and notches in the material of the shell 2B, could equivalently be made by means of tubes applied to the counter device 1 or with other solutions which provide for the combination of ducts obtained and applied on the counter device 1; it is equally evident that the solution shown here must be understood as a mere example of embodiment, since the skilled in the art can provide equivalent solutions, which for example provide for the realization of the channels on the shell 2A alternatively or in combination with those just discussed. In particular, it should be noted that in this example the outlet of the duct 80 (i.e. its mouth open towards the outside) has an at least partly annular shape, being arranged at least in part around the union of the duct 10 (or, similarly , 11).

Going into more detail and with reference to figs. 2 and 3 (in which some details are absent for reasons of clarity) the measurement compartment 3 is configured as a cavity in which the sensor 4 is housed, said cavity being defined by perimeter walls 3A, 3B, 3C: in particular yes they note a first wall 3A, a second wall 3B, substantially parallel to each other, and shell walls 3C which connect the first two walls 3A, 3B to close and define the measuring space 3 itself, which in this example has a substantially box-like shape.

The housing compartment 5 is also defined by respective perimeter walls 5A, 5B, 5C: a first wall 5A, a second wall 5B substantially parallel to each other and shell walls 5C which connect the first two walls 5A, 5B to close and define the housing compartment 5 itself, which in this example also has a substantially box-like shape.

Note that in this solution none of the perimeter walls 3A, 3B, 3C of the measuring compartment 3 is in common with the perimeter walls 5A, 5B, 5C of the housing compartment 5: the two compartments 3 and 5 therefore each have perimeter walls distinct from those of the other room.

In detail, and with reference also to Figures 2 and 3, at least one perimeter wall 3A of said measuring compartment 3 faces at least one perimeter wall 5A of the housing compartment 5.

On these facing walls 3A and 5A there are openings for the passage of the physical data transmission line 7, in this example a male / female plug connector: between the connector and the respective walls 3A and 5A respective sealing gaskets 13A and 15A to avoid the passage of combustible gas.

The sealing gaskets 13A and 15A can be indifferently single or multiple, according to the requirements.

The interspace 8, visible in fig. 1 is defined at least in part by the facing walls 3A, 5A respectively of the measuring compartment 3 and of the housing 5.

It is therefore possible to appreciate how in correspondence with the interspace 8 the physical line 7 for transmitting data from the sensor 4 to the control unit 6 passes, with the advantages described above: in this sense it should also be noted now that this interspace 8 could extend even only in a small area comprised between the perimeter walls 3A, 5A, for example only in the area immediately surrounding the physical line 7. The assembled counter device 1 assumes in this embodiment the appearance shown in fig. 4, ie its outer shell 2 is simply formed by the union of the perimeter walls 3B, 3C and 5B, 5C which define the compartments 3 and 5, with the exception of the walls of these compartments which are facing each other, ie 3A and 5A.

Further advantageous features of the counter device 1 are shown in figs. 5 to 8.

Referring first to figs. 5 and 6 there is a manufacturing step for assembling the counter device 1: to speed up the operations, the box-like structures or half-shells 2A, 2B are first made, which define the two compartments 3 and 5 comprising the perimeter walls first identified and then the two half-shells 2A, 2B are assembled together by means of simple snap coupling operations finished by means of a perimeter frame (optional) 90 visible in fig. 11. Basically, each of the two compartments 3 and 5 is contained by a half-shell 2A, 2B which is snapped onto the other.

As can be seen in figs. from 5 to 8 on one of the perimeter walls of the electronics housing compartment 5, corresponding to the half-shell 2A, there are engagement teeth 20 with ends, substantially in the form of a â € œCâ € (or in any case including an undercut) which project towards the outside and which are able to engage with an edge of the perimeter walls of the measuring compartment 3; in this way the two half-shells 2A, 2B can be pre-positioned respectively and then joined by a simple linear translation of one towards the other, as shown in fig. 5 and 6 To facilitate snap coupling, the two facing walls 3A, 5A each have at least one pair of pin 21 and relative seat 22: in the example shown there are four pairs of pins 21 and relative seats 22, but there could also be only one, or three or more.

These pins 21 and seats 22 collaborate with each other to guide the coupling of the two half-shells 2A, 2B during the straight line approach of the half-shells themselves, and engage each other before engaging the teeth 20, so that this Last is done when the alignment is already correct.

Yet another advantageous feature is shown in the detail of figs. 9 and 10, where the physical data transmission line 7 is shown in detail.

In this example, it advantageously comprises a socket 71 provided with a plurality of rigid plugs 72 which project from the wall 3A of the measurement compartment 3: these plugs 72 are electrically connected to the sensor 4 and transmit the data detected by it.

A gasket is provided around each pin 72 on the side of the compartment 3, to prevent the gas from escaping around, described above and identified with the reference 13A.

The pins 72 project towards the wall 5A where they find openings which receive them in assembled condition, until they come into electrical contact with the control unit 6, for example with its electronic card, as shown in the attached figures.

The gasket 15A is provided between the wall 5A and the control unit board 6, to prevent any gas infiltrations through these openings.

It should be noted that, for each pin 72, a locking means is advantageously provided, for example a clip 73 preferably mounted on the electronic control unit board 6 and adapted to hold the pin 72 in position.

With regard to the clip 73, it advantageously performs not only the locking function for the corresponding pin 72, but also that of ensuring good electrical contact and, therefore, correct data transmission, thus becoming part of the transmission line itself: the clip 73 is in fact welded to the control unit board 6 and is operationally connected to the electronic components of the board itself, so as to perform both the mechanical locking function of the pin and the data transmission function at the same time.

Finally, a further advantageous feature, shown in fig. 11, is related to the presence of an anti-tampering seal, which comprises portions of plastic frame 90 which are welded onto the half-shell 2A and fix part of the edge of the adjacent half-shell 2B, thus that the counter device 1 is not only easy to assemble but a possible tampering attempt is also easily visible.

A variant of what has been described up to now, relative to the coupling of the half-shells 2A, 2B, is shown in figs. 14-17, in which the same parts are indicated with the same numbers and therefore we cannot go back further.

In this case, in short, the coupling takes place through a rotation of one half-shell with respect to the other.

Referring first to figs. 14 and 15 show a manufacturing step for assembling the meter device according to this variant: in this case too the half-shells 2A, 2B are first made which define the two compartments 3 and 5 and then assembled together by means of a snap coupling: as can be seen in fig. 14 on one of the perimeter walls of the electronics housing compartment 5, corresponding to the half-shell 2A, there is an engagement seat 20â € ™, substantially in the form of a â € œCâ € which projects outwards and which is ̈ able to engage with an edge of the perimeter walls of the measuring compartment 3; in this way the two half-shells 2A, 2B can be pre-positioned respectively and then joined by rotation, as shown in fig. 14,16 and 17: the engagement seat 20â € ™ therefore constitutes a rotation seat in this example.

A further advantageous feature is that shown in fig. 16,17: the two facing walls 3A, 5A each have at least one pair of pin 21â € ™ and relative seat 22â € ™: in the example shown there are two pairs of pins 21â € ™ and relative seats 22â € ™, but there could also be only one, or three or more.

These pins 21â € ™ and seats 22â € ™ collaborate with each other to guide the coupling of the two half-shells 2A, 2B during rotation, so as to ensure correct coupling.

On a half-shell, for example the half-shell 2A, in correspondence with an edge opposite to that provided with the engagement seat 20 there is a snap-on sealing lip 25, visible in fig. 14, which is intended to engage with a corresponding edge of the other half-shell 2B, so that, once the rotation of one half-shell with respect to the other has been completed, there is a snap fastening between the two.

The above-mentioned purposes are thus achieved.

Variants equivalent to what has been described up to now are obviously within the reach of those skilled in the art, all to be understood as included within the scope of the present invention.

Claims (10)

CLAIMS 1. Metering device (1) for combustible gas comprising an outer shell (2) comprising: - a measuring chamber (3) in fluid communication with at least one inlet (10) and one outlet (11) conduit for a combustible gas and internally provided with at least one sensor (4) for measuring an indicative quantity of a volume of said fuel gas delivered by said meter device (1) - a housing compartment (5) for an electronic control unit (6) for detecting data sent by said sensor (4) - said sensor (4) and said electronic control unit (6) being connected by means of a physical data transmission line (7) characterized by the fact that said shell (2) further comprises a gap (8) at least partly crossed by said physical data transmission line (7), said gap (8) being in fluid communication with an environment external to said meter device (1). 2. Counter device (1) according to the preceding claim, wherein said shell (2) is divided into two half-shells (2A, 2B) each incorporating one between said measuring compartment (3) and said housing compartment (5), said gap (8) being defined between said two half-shells (2A, 2B). Counter device (1) according to claim 1 or 2, wherein said measuring compartment (3) and said housing compartment (5) are defined by respective perimeter walls (3A, 3B, 3C; 5A, 5B, 5C) , being at least one perimeter wall (3A) of said measuring compartment (3) facing at least one perimeter wall (5A) of said housing compartment (5) and being said interspace (8) defined at least in part by said facing walls ( 3A, 5A) of said measurement compartment (3) and of said housing compartment (5). 4. Counter device (1) according to claim 3, wherein said physical data transmission line (7) comprises a socket (71) provided with a plurality of rigid pins (72) projecting from a wall (3A) of said compartment measurement (3) in the direction of a wall (5A) facing said electronics housing compartment (5) being operatively connected to said control unit (6). 5. Counter device (1) according to claim 4, wherein for each pin (72) there is at least one locking means (73) mounted on said electronic control unit (6) and able to hold said pin (72) in position . 6. Counter device (1) according to one or more of claims 3 to 5, in which sealing gaskets (3A, 5A) of said measuring compartment (3) and said housing compartment (5) are provided (13A, 15A). Counter device (1) according to one or more of claims 2 to 6, wherein said half-shells (2A, 2B) are mutually snap-together, at least a first of said half-shells (2A, 2B) being provided with teeth (20 ) adapted to engage with an edge of the second half-shell. 8. Counter device (1) according to one or more of claims 2 to 6, in which said half-shells (2A, 2B) are mutually snap-together, at least a first of said half-shells (2A, 2B) being provided with a seat for engagement (20â € ™) able to engage with an edge of the second half-shell, said engagement seat (20â € ™) being a rotation seat, and also being said first half-shell, in correspondence with an edge opposite to that provided with said seat engagement (20â € ™) provided with at least one snap sealing lip (25) intended to snap engagement with a corresponding edge of the second half-shell. 9. Counter device (1) according to one or more of claims 3 to 8, in which said facing walls (3A, 5A) each have at least one element of a pair of pin (21) and seat (22) suitable for guiding the Coupling of said half-shells (2A, 2B). Counter device (1) according to one or more of claims 2 to 9, further comprising an anti-tampering seal which comprises portions of plastic frame (80) welded to at least a first half-shell (2A), said portions of plastic frame ( 80) being suitable for fixing part of the edge of a second adjacent half-shell (2B).