ITPD990121A1 - VALVE UNIT FOR THE MODULATION OF THE DELIVERY PRESSURE OF A GAS. - Google Patents

Description

DESCRIPTION

The present invention relates to a valve unit for modulating the delivery pressure of a gas, according to the preamble of the main claim.

These units are known to be used to control the delivery of a gas to a burner or other similar user. In this context, the invention lends itself particularly though not exclusively to the modulation of the fuel gas delivery pressure in appliances intended for local heating. More particularly, the invention finds application in the modulation of the delivery pressure in gas fireplaces, for example those of the decorative type equipped with burners and for which a flame adjustment is also required, and consequently a modulation of the delivery pressure of the gas. gas between the maximum and minimum pressure values allowed for correct operation.

In such units it is known to regulate the gas delivery pressure in a controlled manner according to predetermined parameters, for example measured by an electric current fed to the solenoid of an electromagnetic actuator of the valve unit. Typically, the control, or the interception of the gas supply, is carried out by means of an interception valve while the modulation of the supply pressure, between the minimum and maximum values, can be carried out by means of a servovalve, enslaved by a membrane modulation group. On the one hand, the gas delivery pressure as measured in the delivery duct to the user acts on the membrane of the modulation unit and on the other hand an elastic load subjected to the action of the mobile device of an electromagnet and variable between a minimum value and a maximum value as a function of the driving current of the electromagnet.

In these valve groups there is a need to ensure the control and modulation function of the. supply pressure even in the absence of the mains power supply which is normally used for driving the aforementioned electromagnetic actuators. In this regard, for the sole purpose of intercepting the supply of gas, it is envisaged to use as voltage generators the thermogenerator devices such as thermocouples and thermopiles, capable of supplying electromagnetic safety devices. However, these thermogeneration devices lend themselves, by their very nature, to the generation of electrical voltages or relatively low powers which, on the one hand, effectively ensure the control of the gas interception function, are nevertheless insufficient to drive the actuators on the other. electromagnets in charge of the modulation function of the supply pressure. The modulation of the pressure in fact requires powers of some tens of times greater than those that can be generated by the thermopile safety devices normally used in these valve groups.

The problem underlying the present invention is that of providing a valve unit structurally and functionally conceived so as to overcome all the drawbacks complained of with reference to the cited prior art.

This problem is solved by the invention by means of a valve assembly made in accordance with the attached claims.

The characteristics and advantages of the invention will become clearer from the following detailed description of a preferred embodiment thereof illustrated, by way of non-limiting example, with reference to the accompanying drawings in which:

- Figures 1 and 2 are longitudinal section views of a valve unit according to the invention in two respective variants of embodiment,

- Figures 3, 4, 6, 7 and 9 are graphs illustrating pressure-time characteristic curves of the valve unit of this invention in different operating conditions, - Figures 5 and 8 are graphs illustrating characteristic curves of a control signal of the valve unit of this invention in two different operating conditions.

With reference to Figure 1, 1 generally indicates a first example of a valve unit according to the present invention, for modulating the delivery pressure of a fuel gas delivered to a burner or other similar user, not shown in the figure. The gas is fed to the unit 1 in correspondence with a supply duct 2 and is delivered from it through a delivery duct 3.

The ducts 2 and 3 are separated by a servo-valve 4 comprising an obturator 5 elastically stressed in closing a seat 6 by the elastic load of a spring system 7 and which can be opened by a membrane 8 sensitive to the pressure differential existing between the pressure Pu in the delivery duct 3, on the one hand, and by the pressure Pt in a pilot chamber 9, on the other side, the value of the pilot pressure Pt is controlled by the command of a modulation valve, indicated with 10, and described in details below.

The valve unit 1 further comprises a safety valve 11 controlled by an electromagnetic unit 12, powered by a thermogenerator device, for example including a thermocouple 12a heated by the flame of a pilot burner 13, schematically represented in the drawings. The electromagnetic assembly 12 is manually armed by means of a cocking member 14 provided with a maneuvering stem 15, so as to open the safety valve 11 and allow the gas to flow towards the delivery duct 3.

The valve unit 1 is also provided with a second safety valve 16 whose shutter 17 is urged, by a spring 18, to close a valve seat 19. Through the seat 19, the supply duct 2 is selectively placed in communication with a duct 20 for tapping the gas delivered to the inlet of the valve unit. The safety valve 16 has actuation means 21 mechanically coupled to the manual cocking member 14 of the safety valve 11. The mechanical coupling is such that, during cocking, the safety valve 16 is kept closed and only when release of the cocking member 14, after the ignition of the pilot flame, the valve 16 is urged to open by the actuation means 21 thus allowing the gas to flow through the tapping duct 20.

The duct 20 is in communication with a chamber 22 through a valve seat 23 on which a shutter 24, which can be moved by the action of a control rod 25 of the modulation valve 10, is urged to close.

The chamber 22 is always in communication with the pilot chamber 9 through a transfer 26 and with the delivery duct 3 through a passage 27. Said passage 27 is in communication with the chamber 22 through a calibrated hole 28.

The reference number 30 indicates a valve for regulating the maximum delivery pressure. Said valve 30 is provided with a membrane 31 integral with a shutter holder plate 32 associated with a corresponding valve seat 33. The membrane 31 is subject, on one side, to the load exerted by a spring 34 and adjustable by screwing a spring holder 35 , and on the other side to the pressure existing in a chamber 36. Said chamber 36 is in communication with the chamber 22 through the valve seat 33 and with the delivery duct 3 through a transfer 37.

The modulation valve 10 comprises an electromagnet actuator 38 whose solenoid is supplied with an operating signal S controlled by a driving circuit 39 only schematically represented in the figures. Alternatively, the actuator of the modulation valve 10 may be of the piezoelectric type, for example with double foil.

In the driving circuit 39 means are provided for generating the signal S with a trend (as a function of time) of the type shown in Figure 5. The signal S has a constant frequency with a preselected period T and has a variable amplitude in the period T. More in particular, the signal S, of the impulsive type, is generated as a continuous signal in a first interval T1 and as a signal with zero amplitude in a second interval T2 in sequence with the first and such that the overall duration of the intervals T1 and T2 is equal to period T. Preferably the signal S is an electric voltage signal with which the solenoid of the modulation valve 10 is supplied.

With reference now to Figure 3, 40 indicates a first characteristic curve of the pressure Pt as a function of the time generated in the chamber 22 when the obturator 24 of the valve 10 is kept in the open condition for the entire time interval of the inlet of the valve. gas in the chamber itself, while 41 indicates the gas discharge curve from chamber 22 in which the pressure Pt decreases over time, tending to cancel itself out. Figure 4 shows the pressure-time graph of the pilot pressure Pt in the condition in which the modulation valve 10 is supplied with the pilot signal S of figure 5. It should be noted that in the intervals T1 the pressure Pt tends to increase while in the intervals T2 it tends to decrease respectively with the variation laws of the curves 40 and 41 shown in Figure 3. It should also be noted that the pressure-time function can be broken down into the sum of a first and a second part, respectively continuous and oscillating, of which the first continuous part, represented in figure 6, is constituted by the integrated average value of the pressure function Pt of figure 4. The piloting pressure Pt actually detectable in the pilot chamber 9 consists only of the continuous part of the function in addition to the oscillating part which however, having zero average value in the period, does not influence the integrated average value of the pressure Pt.

In figure 7, a curve similar to that of figure 4 is shown, in which a ratio between the interval Tl and the period T, indicated by D, has been selected, greater than that assumed for the trend in figure 4. you will notice the curve of figure 7 is representative of an integrated mean pressure value Pt, shown in figure 9, greater than that of figure 6.

Through the modulation of the ratio D, by adjusting the duration of the interval T1 with respect to the period T selected, a continuous modulation of the integrated average value of the pilot pressure Pt and consequently of the gas supply pressure is obtained in a proportionally correlated way. duct 3, with consequent modulation of the gas flow. The pressure Pt is modulated within a range of values between a maximum pressure value established by the valve 30 and a minimum pressure value established by the minimum value assumed by the ratio D.

In the example of embodiment of Figure 1, the modulation valve 10 also performs the function of intercepting the flow of gas delivered to the inlet of the valve unit 1.

Furthermore, the driving signal S controlled by the circuit 39 is preferably selected as a low voltage signal, for example of the order of magnitude of hundreds of milliVolts. Due to the relatively low driving voltages required, the modulation valve therefore advantageously lends itself to being fed by the same energy created by the thermoelectric phenomenon in a thermopile 12b of the thermogenerator device.

Figure 2 illustrates a second example of a valve unit according to the invention, indicated as a whole with 50, and in which details similar to those of the previous example are marked with the same numerical references. The group 50 differs mainly from that of the previous example in that a modulation valve 51 of the pilot pressure Pt is provided, whose modulation function is similar to that of the valve 10 of the previous example and to which reference should be made for a detailed description. For the function of interception of the gas flow, a further valve 52 ON-OFF is provided in the valve unit 50 which, unlike the valve 51, is not supplied with a pilot signal modulated in duration.

The modulation valve 51 comprises an obturator body urged to close a valve seat 53 through which the chamber 22 communicates with a conduit 54. Said conduit 54 is open in the passage 27 through a hole 55 on which an obturator is active. needle valve 56 adjustable by screwing in an obturator holder 57. The minimum tolerated pressure for the correct operation of the valve unit is regulated by means of the needle obturator 56.

In operation, the pilot pressure Pt in the chamber 22 is generated as widely described above and in a similar way for both valve groups of the examples reported. This pilot pressure Pt is transferred through the transfer 26 into the pilot chamber 9. Assuming that the pressure in the pilot chamber is increased due to an increase in the pressure Pt, the latter acts on the diaphragm 8, urging the obturator 5 to open The partial opening of the obturator 5, due to a decrease in the pressure drops, causes a corresponding increase in the delivery pressure and consequently the delivered gas flow rate. Obviously, due to a decrease in the pilot pressure, there will be an increase in the aforementioned load losses, while the shutter 5 is pressed to close the seat 6, with a consequent proportional decrease in the delivery pressure and the flow rate. For each average value of the piloting pressure Pt, modulated in the manner described, a proportionally correlated average value of pressure and delivery flow rate is therefore obtained.

The invention thus solves the problem proposed by achieving numerous advantages with respect to known solutions.

A first advantage consists in the fact that with the valve unit of the present invention a modulation of the gas delivery pressure and flow rate is obtained through a piloting circuit powered by the same thermoelectric energy inside the system, thus not requiring any external power supply. This advantageously allows to exclude both the use of the mains power supply, which in the event of an interruption would not guarantee the safe operation of the valve unit, and the use of battery voltage generators to power the pressure modulation device. . It also follows that it is possible to advantageously obtain low consumption due to the reduced power required for controlling the modulation valve.

A further advantage consists in the fact that the valve unit of this invention guarantees the modulating finishing of the pressure through the control of a single modulation valve, with consequent constructive simplicity at reduced costs.

Claims (10)

CLAIMS 1. Valve unit for modulating the delivery pressure of a gas comprising: - a servo-valve having a diaphragm-controlled shutter, said membrane being subjected on one side to the gas supply pressure and on the other side to a pilot pressure established in a pilot chamber of the servo-valve, - a pressure regulating device associated with said servo valve and comprising a modulation valve for modulating the pilot pressure and consequently the gas supply pressure, - actuator means for the operative control of said modulation valve, - a piloting circuit of said actuator means, characterized in that said piloting circuit comprises means for generating an operating signal for piloting the modulation valve at a constant frequency with a preselected period, and means for modulating the amplitude of the signal in duration of the period so as to modulate the pilot pressure in a proportionally correlated way. 2. Valve assembly according to claim 1, in which the amplitude of the driving signal is variable in said period between a maximum value and a minimum value, said values being respectively assumed in a first and in a second time interval, said time intervals being adjustable in duration and the ratio between the durations of said intervals being proportionally correlated to the value of the piloting pressure generated in said piloting chamber. 3. Valve assembly according to claim 1 or 2, further comprising an ON-OFF gas interception valve communicating with said pilot chamber and interposed between a gas inlet duct and the modulation valve, said modulation valve being piloted by said piloting circuit for the sole function of modulating the piloting pressure. 4. Valve assembly according to one or more of the preceding claims, wherein said driving signal is an electric voltage signal. 5. Valve assembly according to one or more of the preceding claims, in which said first and second time intervals are in sequence to each other, the sum of their durations being equal to the period of the signal, said signal being continuous in each of said intervals. 6. Group according to claim 5, wherein said driving signal assumes an amplitude of null value in one of said intervals. 7. Assembly according to one or more of the preceding claims, comprising safety valve means controlled by thermogenerator means to supply sufficient energy to drive said valve means in the presence of flame, said pilot circuit of the modulation valve being powered by the thermoelectric energy generated by said heat-generating means. 8. A group according to claim 7, wherein said thermogenerating means comprise at least one thermocouple. 9. Group according to claim 7, wherein said thermogenerating means comprise at least one thermopile. 10. Assembly according to one or more of claims 4 to 9, wherein gas flow throttling means are provided, arranged between the modulation valve and a gas delivery duct, said throttling means being adjustable for controlling the minimum pressure gas supply. 12. Assembly according to claim 1, wherein said actuator means comprise an electromagnet capable of being supplied with said driving signal. 13. Assembly according to claim 1, in which said actuator means are of the piezoelectric type.