ITPD990272A1 - SAFETY VALVE STRUCTURE AND / OR FLOW REGULATOR PARTICULARLY FOR GAS. - Google Patents

Description

"STRUCTURE OF SAFETY AND / OR FLOW REGULATOR VALVE PARTICULARLY FOR GAS"

DESCRIPTION

The present invention relates to a safety valve and / or flow rate regulator particularly for combustible gas heaters.

The safety valves normally used in this type of equipment are solenoid valves, in which the solenoid controls the opening of a shutter which, with the passage of current, is in the opening position, while in the absence of current it is in the closing position of the gas passage openings.

For safety reasons, two valves are usually arranged in series, so that if one valve should fail, the safety function would still be performed by the second valve.

The shutter is integral with a permanent electromagnet, which moves due to the variation in intensity of the magnetic field generated by the solenoid.

Once the valve is activated, there is a high current consumption, which also leads to heating of the valve, with dissipation of powers that can even reach values of 4-5 W.

In addition, the valve is particularly noisy due to the activation and deactivation of the magnetic field.

As for the control valves, there are no constraints such as. the interposition of several valves in series, but equally, this type of valve is subject to problems.

Usually, valves with modulation of the flow rate to the main burner with analogue control on an electromagnet are used.

These valves consist of a main body containing a solenoid generating a magnetic field flowing inside the main body, and a fixed and a movable core, in turn contained within the solenoid, generating an air gap.

In practice, by exciting the solenoid with a direct current of variable intensity, I create a magnetic force in the air gap which tends to move the mobile core into the closed position of the air gap itself.

To counteract the magnetic force, a spring is positioned which tends to increase the width of the air gap.

The portion of the movable core not contained within the solenoid is shaped to define a shutter for an opening that allows the passage of gas inside the valve itself.

Therefore, by varying the intensity of the current, I command the displacement of the mobile core, more or less obstructing the passage of the gas and then more or less regulating the flow rate.

However, this type of valve cannot carry out a continuous flow rate adjustment, managing to modulate the passage of gas only for a small initial displacement range and not for the entire possible stroke of the mobile core.

In fact, after a given opening position of the passageway, the gas flow reaches a maximum value that does not undergo further variations due to the further movement of the shutter.

Furthermore, the presence of the spring leads to the occurrence of the phenomenon of mechanical hysteresis, which, in the long run, does not allow adequate and precise regulation of the flow rate, even in the narrow range of initial displacements.

The aim of the present invention is to provide a safety valve and / or flow rate regulator particularly for gas which solves the problems of known types of valves.

A consequent object is to provide a valve which allows a continuous adjustment of the flow rate from zero to a predetermined value according to a desired law.

Another object is to provide a valve which solves the safety problem by involving a low current consumption.

Another object is to provide a valve which is silent. Another object is to provide a valve which performs the function of regulating the flow rate without being subjected to any phenomenon of mechanical hysteresis.

Yet another object is to provide a valve which simultaneously performs the safety and regulation function.

Not least object is to provide a valve the use of which involves an overall low consumption of electric current.

The main aim, the intended aims and still other aims, which will appear more clearly in the following, are achieved by a safety and / or flow-rate regulating valve structure particularly for gas, characterized in that it comprises a hollow body provided with passage of the gas, shutters for said ducts, at least one translation actuator for the movement of said shutters, at least one kinematic transmission for connecting said actuator to a permanent magnet disposed inside the gas passage area and means for rotating said permanent magnet arranged outside the gas passage area.

Further characteristics and advantages of the invention will become clearer from the detailed description of an embodiment thereof illustrated by way of example, but not limiting its scope, in the attached tables of figures and drawings, in which:

fig. 1 shows a safety valve according to the invention, which solves both the safety problem and the flow rate regulation;

fig. 2 shows a second embodiment of a valve according to the invention;

fig. 3 shows a third embodiment of a valve according to the invention;

fig. 4 shows a valve according to a fourth embodiment of the invention which performs only the safety function.

With particular reference to Figure 1, a safety and / or flow rate regulator valve structure particularly for gas in a first embodiment, according to the invention, is generally indicated with the number 110.

The valve 110 is mainly constituted by a hollow body 111, on which ducts are formed for the passage of gas consisting of an inlet port 112 for an inlet area 113 separated from an intermediate area 114 by a first partition 115 provided with a through hole 116.

From the intermediate zone 114, through a second partition 117, provided with a through hole 118, it is possible to reach an outlet zone 119 for the gas through an outlet path 120.

The inlet zone 113, the intermediate zone 114 and the outlet zone 119 are arranged along the longitudinal direction of the hollow body 111.

Two anchor magnets, respectively indicated with the numbers 121a and 12 Ib and overall with the number 121, are arranged inside the inlet area 113 and in the outlet area 119, arranged opposite each other carrying a corresponding plate 122a and 122b provided of sealing gasket 123a and 123b on the surfaces facing the baffles 115 and 117.

When not excited, the springs 139a and 139b, compressed respectively between the plates 122a and 122b of the bodies 140a and 140b of the anchor magnets 121, push the plates 122 against the septa 115 and 117 to obstruct the passage of gas through the through holes 116 and 118 and then through the entire valve 110.

Advantageously, the gaskets 123 perform an excellent seal.

An actuator 125 slides within a guide 124 in the intermediate zone 114.

Said actuator 125 has a longitudinal development and has the end portions 126a and 126b which can thrust on the plates 122, counteracting the action of the anchor magnets 121.

Adjacent to the end portion 126b, corresponding to the through hole 118, the actuator 125 is shaped like a cone 127.

The actuator 125 translating, generates between the cone 127 and the hole 118 a port 128 of variable size, which allows the modulation of the gas flow rate.

The translation of the actuator 125 is allowed by coupling a counter-shaped portion 129 of the same with a toothed wheel 130 keyed on a shaft 131 arranged orthogonal to the actuator 125 itself, in turn keyed on a permanent magnet 132 of substantially cylindrical shape. .

The permanent magnet 132 is arranged outside the hollow body 111 through an opening 133.

The permanent magnet 132 is internal to the gas flow, and therefore isolated from the outside by means of a substantially cylindrical element 134, containing the permanent magnet 132 itself, integral with its base 135 to the hollow body 111.

A sealing gasket 136 is advantageously arranged between the base 135 and the hollow body 111.

Since the means adapted to rotate the permanent magnet 132 are arranged outside the cylindrical element 134, the cylindrical element 134 is constructed of low resistivity material in order to avoid the propagation of eddy currents.

Advantageously, in this case, said means for making the permanent magnet rotate take the form of a stepper motor 137 comprising four coils 138 arranged radially at 90 ° from each other.

As regards the operation, the stepper motor 137 controls the rotation of the shaft 131 so that the actuator 125 pushes the plate 122a of the anchor magnet 121a positioned at the entrance way 112.

Subsequently the motor 137 rotates in the opposite direction by commanding through the actuator 125 the opening of the plate 122b, thus allowing the flow of the gas flow, and positioning itself in such a way as to modulate its value through the variation of the section of the passage opening 128.

A second embodiment of the invention is illustrated in Figure 2 where the valve structure is indicated as a whole with the number 210.

The valve 210 consists of a hollow body 211, substantially parallelepiped in shape, in which an inlet way 212 is made transversal, to an inlet area 213 connected through the hole 214 of a septum 215, to an intermediate area 216, connected in turn to a gas outlet area 217 provided with a longitudinal outlet 218.

The intermediate zone 216 and the outlet zone 217 are connected through a conical shaped hole 219 obtained on the partition 220.

In this embodiment 210, only one anchor magnet 221 is used, which in rest conditions pushes a plate 222 to completely obstruct the hole 214 of the septum 215.

In the intermediate zone 216 there is an actuator 223, still with longitudinal development, sliding inside a guide 224.

The end 225 of the actuator 223, in correspondence with the anchor magnet 221, acts as a thrust on the plate 222, commanding its opening.

The opposite end 226, on the other hand, carries a substantially cylindrical shaped conical shutter 227 integral in a portion 228 defines it with the hole 219, a gas passage opening 241 of variable section with the translation of the shutter 227 itself.

The shutter 227 also carries a seal 229 circumferentially which allows the complete obturation of the hole 229 when in rest conditions.

The translation of the actuator 223 is controlled by the toothed wheel 230 keyed on the shaft 231 in turn keyed on the permanent magnet 232.

The permanent magnet 232 is still arranged outside the hollow body 211 and isolated from the outside through the hollow cylinder 233 in low resistivity material.

The permanent magnet 232, in addition to being able to be rotated by the stepper motor 234, can also be moved by a conductive metal ring 235 which surrounds the permanent magnet 232 at least for a longitudinal portion 242.

The conductive metal ring 235 can be rotated manually or through an electric motor 236 whose shaft 237 is coaxial and integral with the metal ring 235 itself.

In this embodiment, the safety device is constituted by a thermocouple 238 which alone allows the opening of the anchor magnet 221 when operated by a pilot flame 239 derived from a transversal opening 240 obtained on the hollow body 211 in correspondence with the area intermediate 216.

The third embodiment of the invention 310, illustrated in figure 3, is substantially similar to the previous one except for the different coupling between the shutter 327 and the actuator 323.

In this case, in fact, the actuator 323 acts as a thrust on the shutter 327, counteracting the action of a spring 338 arranged in the exit area 317 and which normally positions the shutter 327 in the position of occlusion of the conical hole 318.

The spring 338 is compressed between a circumferential groove 339 obtained in the exit area 317 and a shoulder 340 obtained in the shutter 327.

The fourth embodiment 410 of the invention differs from the previous ones in that it performs only the safety functions.

As in the embodiment 110, there are two anchor magnets 421a and 421b arranged opposite each other in an inlet area 413 and an outlet area 419.

Otherwise, this time the anchor magnets 421 are fed respectively by a thermocouple 439 and 440, which are in contact with a pilot flame 441 derived from a transverse opening 442 obtained on the hollow body 411 in correspondence with the intermediate zone 414.

In practice it has been found that the main aim and objects of the present invention have been achieved.

In particular, it should be noted that for the regulation of the flow rate, the traditional ultra-precise mechanics consisting of membranes and springs in equilibrium with each other is no longer necessary.

In fact, by using a digital input signal, the displacement of a shaped shutter is commanded so as to define a passage opening with a variable gas flow rate with a counter-shaped duct according to a predetermined algorithm.

In this way any hysteresis phenomenon of the mechanical components is avoided.

In addition, usually to reduce the size and electrical power of the solenoids, traditional valves are used to build a pneumatic circuit to amplify the movement and force.

The valve according to the invention is much smaller than current valves, since all the elements work in symbiosis, reducing the overall power of the solenoids to 0.1 watt, without having to build any pneumatic circuit, while maintaining the shutters with large lifts.

The invention thus conceived is susceptible of numerous modifications and variations, all of which are within the scope of the inventive concept.

Furthermore, all the details can be replaced by other technically equivalent elements.

In practice, the materials used, as long as they are compatible with the contingent use, as well as the dimensions, may be any according to requirements.

Claims (20)

CLAIMS 1) Structure of safety valve and / or flow rate regulator particularly for gas, characterized in that it comprises a hollow body provided with gas passage ducts, shutters for said ducts, at least one translation actuator for moving said shutters, at least one kinematic transmission for connecting said actuator to a permanent magnet arranged inside the gas passage area and means for rotating said permanent magnet arranged outside the gas passage area. 2) Structure, as in claim 1, characterized by the fact that said shutters comprise at least one closing plate for a corresponding opening made in a septum interposed in said ducts, said plate carrying a sealing gasket on the surface facing said septum. 3) Structure, as in claim 2, characterized in that said plate is integral with the stem of an anchor magnet which, in rest conditions, pushes the plate into the closing position of said opening. 4) Structure, as in claim 1, characterized by the fact that said shutters comprise a longitudinal element, shaped to define with a corresponding shaped portion of said duct, a gas passage opening of variable value, following the movement of the shutter , according to a predetermined law, from zero to a predetermined value. 5) Structure, as in claim 1, characterized in that said permanent magnet has a substantially cylindrical shape, and has a kinematic connection shaft keyed to said actuator, the opposite end to that of keying with the permanent magnet being inserted into a corresponding blind hole obtained at the base of said hollow body. 6) Structure, as per claims 1 and 5, characterized in that said actuator is a longitudinal element, sliding within a corresponding rectilinear guide, obtained in said hollow body, with head portions for coupling with said shutters and counter-shaped body to making a toothed wheel-worm coupling, with a corresponding toothed wheel keyed on said shaft between said end inserted in the hollow body and the permanent magnet. 7) Structure, as per claims 5 and 6, characterized in that said actuator is arranged along the longitudinal development direction of said body and perpendicular to said shaft. 8) Structure, as claimed in one or more of the preceding claims, characterized in that the portion of said shaft which carries said permanent magnet keyed is arranged outside the encumbrance of said hollow body. 9) Structure, as in claim 8, characterized in that said permanent magnet is contained in a cylinder made of low resistivity material whose base is fixed to the hollow body, between said base and said hollow body a sealing gasket is placed between said base and said hollow body. 10) Structure, as in claim 1, characterized in that said means for making the permanent magnet rotate take the form of a plurality of coils, alternately or simultaneously excited, arranged radially around said cylinder made of low resistivity material. 11) Structure, as in claim 1, characterized in that said means for making the permanent magnet rotate are made of a conductive metal ring arranged above said cylinder made of low resistivity material. 12) Structure, as in claim 11, characterized in that said conductive metal ring is axially integral with the shaft of an electric motor. 13) Structure, as per one or more of the preceding claims, characterized in that it comprises a gas inlet, a gas outlet, two baffles, provided with through holes, inside the hollow body, suitable for defining an area inlet, an outlet zone and an intermediate zone containing said actuator. 14. Structure, as in claim 13, characterized in that said intermediate zone is provided with a pilot flame path. 15) Structure, as in one or more of the preceding claims, characterized in that it comprises two anchor magnets, each carrying a disc shutter for closing corresponding holes made in said baffles, arranged opposite each other in the entrance area and in the area of gas outlet. 16) Structure, as in claim 15, characterized in that it comprises a longitudinal shutter, integral with said actuator between the thrust ends on the corresponding plates, able to define a gas passage opening with variable section with the corresponding hole in the septum defining the gas outlet area. 17) Structure, as in one or more of the preceding claims, characterized by the fact of comprising an anchor magnet positioned in the gas inlet area carrying a plate shutter, closing the hole made in the corresponding septum, and a longitudinal shutter , integral with the opposite end of the actuator, able to define a gas passage opening with variable section with the corresponding hole in the septum defining the gas outlet area. 18) Structure, as in claim 17, characterized by the fact that said shutter is released from said actuator, the actuator pushing the shutter against the action of a corresponding spring for positioning the shutter in the closed position. 19) Structure, according to one or more of the preceding claims, characterized in that it comprises a thermocouple connected to said pilot flame for at least one anchor magnet. 20) Structure, as per one or more of the preceding claims, which is characterized by what is illustrated and described in the attached tables of figures and drawings.