EP2775142A1 - Device for ejecting granular material by venturi effect - Google Patents

Abstract

The device (3) has an opening (22) to admit a flow of granular material i.e. sand. A conduit (19) includes a converging portion and a diverging portion, where the conduit is intended to create a suction passage (23) to effect a flow of gas through the conduit, and the opening is connected to the conduit. An ejection channel (20) is arranged downstream of the conduit, where the suction passage opens downstream of the convergent part of the conduit, so as to allow, through suction effect, flow of sand from the opening to the ejector channel. An independent claim is also included for a system for ejection of granular materials for a railway vehicle.

Description

The present invention relates to a device for ejecting granular material, for example sand, capable of cooperating with a reservoir of granular material.

The present invention relates more particularly - but not exclusively - to such a device associated with a sand reservoir, the device generally being attached to the bottom of the tank. The combination of these elements form a so-called "equipped" sand pit intended to spread sand between the wheel of a vehicle, for example a train, and the track, for example rails.

An equipped sandpit is intended, during a braking, to spread sand on the track, below the braked wheel, to prevent slippage, increase grip, increase the braking efficiency, reduce the distance of stop and perform emergency braking, as well as to assist the electrical contact between wheel and rail. The equipped sandbox is also used at startup to improve grip. The equipped sandpit generally contains a sufficient quantity of sand to be poured during the entire braking period until the complete stop of the train, and this, starting from the maximum possible speed of the vehicle on a path considered, or during the entire duration of the start.

A sand ejection device is known from the document EP-B-1 470 981 . This device provides for the use of a vertically oriented flow of compressed air to cause suction of sand through horizontal suction channels. These channels open into an injection zone located downstream of the source of compressed air and upstream of the convergent portion of a conduit.

In addition, the fact that the suction channels are horizontal allows the accumulation of sand in them at the risk of clogging the device.

In addition, there are wide variations in flow of the granular material ejected by this ejection device and a distribution inhomogeneous sand out of the device. Indeed, it is necessary to have a regular flow and a homogeneous distribution of granulated material ejected to allow the driver of the vehicle to anticipate the braking distance and the time required for it.

The present invention aims to remedy at least some of the disadvantages of the prior art by providing a granular material ejection device according to claim 1.

Thus, the above-mentioned structural arrangement of the device makes it possible to provide a flow of granular material that is more homogeneous than in the prior art. The removal of the injection zone of the aforementioned prior art makes the device more compact.

In addition, this structure offers a versatility of the conduit arrangement, which allows to adapt the structure of the device and its size to the vehicle concerned.

The fact that said at least one passage opens downstream of the convergent portion and not upstream makes the suction effect more efficient than in the prior art. This also limits the risk of obstruction of the device by granular material. This arrangement requires a lower flow rate and / or a lower gas pressure, which advantageously makes it possible to save energy.

Given the above, the device is therefore particularly suitable for application to a rail vehicle and is particularly effective in this application.

Note that said at least one passage opens after the converging portion and / or in the diverging portion, and, for example, in the first third of the diverging portion.

Indeed, said at least one passage can lead to a neck located between the convergent and divergent portions.

According to a possible characteristic, said at least one passage comprises a baffle-shaped zone downstream of said at least one opening, which comprises an upward passage portion, and a downward passage portion placed downstream of said upward passage portion, said baffle zone being intended to guide said flow of granular material from said at least one opening towards the conduit.

According to another possible characteristic, the ascending passage portion comprises a ramp.

The ramp preferably has an inclination angle of between 10 and 85 ° with respect to a straight line orthogonal to the bottom of the tank with which the device is able to cooperate (vertical straight line).

This ramp makes it possible to regulate the quantity of sand sucked up and also has a sand holding function when the suction effect ceases, even under the effect of a vibratory disturbance.

According to another possible characteristic, the ascending passage portion and / or said downward passage portion is delimited by facing walls.

The abovementioned facing walls (parallel to each other or not) make it possible to channel the granular material to the ejection channel.

According to another possible characteristic, the facing walls delimiting at least one of the upward and downward passage portions are respectively inscribed on two portions of conical surfaces spaced apart from each other.

For example, the facing walls delimiting the ascending passage portion are inscribed respectively on two conical surface portions facing each other, while the facing walls delimiting the downward passage portion are inscribed on two conical surface portions facing inverted conicity.

According to another possible characteristic, said at least one passage comprises a mixing zone.

The mixing zone serves, in particular, to homogenize the flow of granular material and, optionally, to dry and / or at least partially stir the granular material.

According to another possible characteristic, said at least one passage comprises a duct connection zone.

According to another possible characteristic of a first embodiment, the duct connection zone is annular in shape.

According to another possible characteristic of a second embodiment, the duct connection zone opens onto one of the sides of the duct.

According to another possible characteristic, the connection zone is located downstream of the baffle zone.

• ladite au moins une ouverture comprend un bord supérieur,
• ladite portion de passage ascendante et ladite portion de passage descendante comprennent une zone de jonction qui relie lesdites portions de passage entre elles, de telle manière que ledit bord supérieur de l'ouverture est situé à une altitude inférieure à l'altitude de ladite zone de jonction.

According to another possible characteristic:

• said at least one opening comprises an upper edge,
• said upward passage portion and said downward passage portion comprise a junction zone which connects said passage portions therebetween, such that said upper edge of the opening is located at an altitude lower than the altitude of said junction.

This arrangement allows, among other things, the granular material not to cross the junction area under the sole effect of gravity (holding effect).

According to another possible characteristic, the difference in altitude between the upper edge of said at least one opening and the junction zone of the passage portions, the passage section of the upward passage portion, the angle of inclination (angle defined with respect to an orthogonal straight line at the bottom of the tank) of the ascending passage portion (for example of the ramp), the shape and the dimension of each of the openings of the device and the inside diameter of a nozzle capable of injecting gas in the duct are parameters selected according to the particle size spectrum of the granular material, so as to obtain a determined value of the flow of granular material ejected by the device.

According to another possible feature, the device comprises at least three openings each comprising a center, said centers defining a plane with respect to which the conduit is arranged orthogonally (first mode) or parallel (second mode).

According to a possible characteristic, the device comprises three openings, which are arranged at an angular spacing of about 120 ° between them.

This arrangement makes it possible to homogenize the quantity of granular material penetrating into the device.

According to another possible feature of the first embodiment, the downward passage portion and the conduit define between them an angle of between 0 ° and 60 °, and preferably between 10 ° and 30 °.

Such an angle avoids the accumulation of sand in the device and therefore its engorgement by sand. In addition, this angle makes it possible to homogenize the sand without slowing down its speed.

According to another possible characteristic of the second embodiment, the downward passage portion and the conduit define between them an angle of between 70 ° and 110 °, and preferably equal to 90 °.

Such an angle avoids the accumulation of sand in the device and therefore its engorgement by sand. In addition, this angle makes it possible to homogenize the sand without slowing down its speed.

It is noted that the angles mentioned above make it possible to obtain the desired regularity for the flow of granular material.

According to another possible characteristic, the parts of the device in contact with the granular material are covered with an abrasion resistant material.

The abrasion-resistant material may be, for example, a polymer-based material.

According to one possible characteristic, the device is surmounted by a beveled cap which makes it possible to avoid the accumulation of sand on it.

According to another aspect, the subject of the invention is a system which is in accordance with claim 13. The device is able to cooperate with the bottom of said reservoir of granular material, so that said at least one opening of the device is located inside said tank of granular material and that it is in particular as close as possible to said bottom, in order to eject most of the granular material contained in the tank.

The invention also relates to a railway vehicle comprising the aforementioned system.

Thus, the system is mounted on the vehicle so that the device can eject granular material (eg sand) between a wheel of the vehicle and the track on which it travels (ex: rail).

This makes it possible to increase the adhesion between the wheel of the vehicle and the track and thus to increase the braking efficiency (vehicle braking aid).

• la figure 1a représente une vue en coupe axiale d'un réservoir de sable équipé d'un dispositif d'éjection de matière granuleuse selon un premier mode de réalisation de l'invention, l'ensemble étant destiné à être fixé sur un véhicule ;
• la figure 1b est une vue agrandie du corps du dispositif de la figure 1a ;
• la figure 1c est une vue partielle et agrandie du corps du dispositif de la figure 1b ;
• la figure 2 est une vue partielle et très schématique en coupe transversale du corps du dispositif des figures 1a et 1b ;
• la figure 3a représente une vue en coupe axiale d'un réservoir de sable équipé d'un dispositif d'éjection de matière granuleuse selon un deuxième mode de réalisation de l'invention, l'ensemble étant destiné à être fixé sur un véhicule ;
• la figure 3b est une vue agrandie du corps principal du dispositif de la figure 4a ;
• la figure 3c représente une vue en coupe axiale d'un réservoir de sable équipé d'un dispositif d'éjection de matière granuleuse selon une variante du deuxième mode de réalisation de l'invention, l'ensemble étant destiné à être fixé sur un véhicule ;
• la figure 4 est une vue en perspective du dispositif de la figure 3a ;
• la figure 5 représente une vue schématique en coupe transversale d'une variante d'un dispositif d'éjection de matière granuleuse selon l'invention.

The invention will be better understood, and other objects, details, features and advantages thereof will appear more clearly in the following description of particular embodiments of the invention, given solely for illustrative and not limiting, with reference to the accompanying drawings, in which:

• the figure 1a is an axial sectional view of a sand reservoir equipped with a granular material ejection device according to a first embodiment of the invention, the assembly being intended to be fixed on a vehicle;
• the figure 1b is an enlarged view of the body of the device from the figure 1a ;
• the figure 1c is a partial and enlarged view of the body of the device of the figure 1b ;
• the figure 2 is a partial and very schematic cross-sectional view of the body of the device of the figures 1a and 1b ;
• the figure 3a is an axial sectional view of a sand reservoir equipped with a granular material ejection device according to a second embodiment of the invention, the assembly being intended to be fixed on a vehicle;
• the figure 3b is an enlarged view of the main body of the device of the figure 4a ;
• the figure 3c is an axial sectional view of a sand reservoir equipped with a granular material ejection device according to a variant of the second embodiment of the invention, the assembly being intended to be fixed on a vehicle;
• the figure 4 is a perspective view of the device of the figure 3a ;
• the figure 5 is a schematic cross-sectional view of a variant of a granular material ejection device according to the invention.

The figure 1a is an axial sectional view of a system 1 comprising a reservoir of granular material 2, for example sand S, and a granular material ejection device 3 according to a first embodiment of the invention. The device is mounted in the tank 2, more particularly at the bottom 4 of the tank.

The system 1 (equipped pit) is mounted on a vehicle, for example rail such as a locomotive, so that the device 3 can eject granular material between the path on which the vehicle and a wheel of said vehicle, in order to increase the friction forces between the track and the wheel.

Such a system 1 makes it possible to improve, inter alia, the adhesion between the track and the wheel.

As shown on the figures 1a and 1b , the granular material ejection device 3 comprises two parts fixed to each other: a body 5 and a base 6 on which said body 5 is mounted.

The base 6 comprises a lower portion 6a having a substantially cylindrical shape and an upper portion 6b having a substantially circular collar 7.

A through hole 8 is made in the center of the base 6.

The body 5 is mounted on the upper part 6b of the base by partially inserting into the through hole 8.

The body 5 is fixed to the base 6 by known means, such as by welding, screwing, bolting, snapping ...

The body 5 has the general shape of a cylinder of revolution centered on an axis ZZ '(axis of revolution) which, here, is arranged perpendicular to the bottom 4 of the tank, that is to say vertically.

The base 6 comprises known fastening means (not shown) such as by welding, screwing, bolting, snapping ..., to position and fix the device in the bottom 4 of the tank.

The bottom 4 is pierced with a central opening 10 through which the device 3 extends, thus leaving an annular wall 11 around the opening 10.

The annular wall 11 comprises an upper face 11a facing the inside of the reservoir 2 and an opposite lower face 11b facing outwardly of the reservoir 2.

When the device 3 is mounted on the tank 2, the base 6 is fixed against the bottom 4 of the tank. The flange 7 is positioned and attached to the outside of the tank 2, in contact with the outer lower face 11b of the annular wall of the bottom 4. The body 5, for its part, is disposed inside said tank 2 .

Furthermore, the system 1 comprises a source of gas under pressure 12, for example compressed air, and a control means 13, for example a solenoid valve equipping the gas source 12 or independent thereof.

The control means 13 is a control means for regulating the quantity of gas delivered by the pressurized gas source.

The control means 13 may, for example, take the form of a two-state system which are: open or closed.

The pressurized gas source 12 is connected to the granular material ejection device 3 at the base 6. For this purpose, the system 1 comprises one or more pipes connecting the gas source 12, the control means 13 (if it is independent of the source) and the base 6 of the device 3.

The device 3 comprises a gas supply circuit 14 whose entry point 15 is in the base 6.

The gas supply circuit 14 more particularly comprises, in the base 6, a threaded housing 15 arranged parallel to the bottom of the tank 4 (horizontally) and provided with two ends whose first end 15a ( figure 1b ) allows the fitting of a connection connected to the pressurized gas source 12. The gas supply circuit 14 also comprises ( figure 1b ), connected to the second end 15b of the threaded housing 15, a channel 16 which extends from the base 6 to the upper part 5a of the body eccentrically with respect to the longitudinal axis ZZ '. The threaded housing 15 is arranged at the periphery of the base 6 relative to the central axis ZZ 'which passes through the center thereof.

The channel 16 comprises two channel portions: a first portion 16a which is a tube oriented vertically with respect to the horizontal bottom of the tank 4, and a second portion 16b which extends horizontally in the body 5 from the upper end of the tube 16a towards the axis ZZ '.

In the embodiment shown channel 16 is located inside the device 3, but in a variant it may be outside and / or take various shapes and orientations. The gas source 12 can also be connected to the device 3 via the second portion 16b of tube 16 (the threaded housing 15 and the first portion 16a of the tube 16 are omitted in this variant).

The second channel portion 16b opens onto a housing 17 disposed axially along the axis ZZ '.

A nozzle 18 is mounted in this central housing 17 and is oriented perpendicular to the bottom of the tank 4 (vertical orientation).

The device 3 also comprises downstream of the nozzle 18 (aligned along the longitudinal axis ZZ ') and in alignment thereof, a conduit 19 arranged perpendicularly to the bottom of the tank 4. The conduit 19 comprises a convergent portion 19a and a diverging portion 19b disposed downstream of the convergent portion 19a and in alignment therewith.

The nozzle 18 opens into the convergent portion 19a of the duct.

The conduit 19 has substantially the shape of a nozzle.

The ejection device 3 comprises an ejection channel 20 (more particularly visible on the figure 1a ) whose inlet 20a is disposed in alignment with the diverging portion 19b of the duct and downstream thereof.

The ejection channel 20 is substantially bent shape and has at one of its ends the inlet 20a and at the opposite end an outlet 20b.

However, as a variant not shown the ejection channel 20 may have a straight profile.

The lower part 6a of the base comprises fastening means 21 for removably fixing the ejection channel 20 in this part.

These means 21 take for example the form of a collar fixed by studs to the lower part 6a of the base and coming to press the inlet of the ejection channel 20a against this part 6a.

The body 5 comprises openings 22, for example three, arranged in a generally cylindrical peripheral wall 5b which defines a portion of the outer casing of the body 5.

These openings are arranged at an angular spacing of about 120 ° between them. A different number of openings may also be suitable: two, four ...

The openings 22 are for example circular, but it will be noted that other forms of openings are conceivable: oblong, rectangular ... with various orientations.

These openings 22 establish a communication between the outside of the body 5 located inside the sand reservoir 2 and the inside of the body 5.

Each opening 22 comprises a center and the three centers C1, C2, and C3 define a plane P (here horizontal) perpendicular to the axis ZZ '(illustrated in FIG. figure 2 ).

It will be noted that, in the embodiment shown, the conduit 19 is arranged perpendicular to the plane P.

The body 5 comprises a passage 23 connecting the openings 22 to the conduit 19. The passage 23 more particularly comprises a baffle-shaped zone 24 downstream of the openings 22.

The baffle-shaped zone 24 of the passage 23 comprises, an upstanding passage portion 25 comprising a ramp 25a, a downstream passage portion 26 located downstream and which has a connecting zone 27 with the conduit 19 (these elements are more particularly visible to the figure 1c ).

The ramp 25a preferably has an angle (c) of inclination (this angle is visible at the figure 1c ) between 10 and 85 ° with respect to a straight line orthogonal to the bottom of the tank 4 (vertical right).

The angle (β) defined by the downward passage portion 26 and the longitudinal axis (here the vertical axis ZZ ') of the duct 19 is an angle between 0 and 60 °, preferably between 10 ° and 30 ° (this angle is visible at figure 1b ).

The connecting zone 27 has for example a form of annular chamber arranged immediately downstream of the convergent portion 19a of the duct.

The passage 23 opens into the conduit 19 via the connecting zone 27, at the neck 19c forming the junction between the convergent portion 19a and the diverging portion 19b.

According to a variant not shown, the passage 23 opens into the diverging portion 19b, more particularly in the first third of the diverging portion 19b.

The ascending and descending passage portions 26 are each delimited by walls 5c, 5d, 5e and 5f facing one another, internal to the body and which, in an axial sectional view, give the passage a profile. M-shaped (these elements are more particularly visible in the figure 1c ).

More particularly, the two walls, lower 5c and upper 5d, which delimit the ascending passage portion 25 are respectively inscribed on two conical surfaces 101 and 102 distant from each other and substantially parallel (these are more particularly visible to the figure 1b ). The vertices of the two conical surfaces are positioned on the axis ZZ 'in the direction of the upper part 5a of the body.

Similarly, the two walls, lower 5th and upper 5f, which delimit the downward passage portion 26 are respectively inscribed on two conical surfaces 103 and 104 distant from each other, substantially parallel (these are more particularly visible to the figure 1b ) and whose conicity is the opposite of that of the conical surfaces of the ascending passage portion 25.

It will be noted that the ascending and descending passage portions 26 are joined by a substantially horizontal junction zone 28.

Each of the openings 22 includes an upper edge 22a whose highest point is located at an altitude lower than the altitude of the junction zone 28. The difference between these two altitudes is noted a.

The passage 23 is delimited by the upper walls 5d, 5f and lower 5c, 5e above and the peripheral wall 5b of the body 5 which is provided with the openings 22, thus conferring on said passage 23 the shape of a generally annular space of revolution around duct 19 centered on the axis ZZ '.

• une première pièce inférieure 29 qui comporte la partie divergente 19b du conduit et les parois inférieures 5c, 5e du passage et s'insère en partie dans le trou traversant 8 de l'embase 6,
• une deuxième pièce supérieure 30 qui comporte la partie convergente 19a du conduit et les parois supérieures 5d, 5f du passage,
• une troisième pièce 31 surmontant la deuxième pièce 30 et qui comporte le logement 17 avec le gicleur 18.

The body 5 more particularly comprises three assembled parts (more particularly visible to the Figures 1b and 1c ) in a simple way one above the other:

• a first lower part 29 which comprises the diverging part 19b of the duct and the lower walls 5c, 5e of the passage and is partly inserted into the through hole 8 of the base 6,
• a second upper part 30 which comprises the convergent portion 19a of the duct and the upper walls 5d, 5f of the passage,
• a third piece 31 surmounting the second piece 30 and which comprises the housing 17 with the nozzle 18.

Drilling holes are made in the three rooms to accommodate the two channel portions 16a and 16b of the gas supply circuit 14.

The operation of the granular material ejection device 3 will now be explained with reference to figures 1a and 1b .

When the gas supply circuit 14 is supplied with a pressurized gas from the gas source 12, for example air between 1 and 10 bar, a flow of pressurized gas flows in the circuit to the nozzle 18 where it is injected into the convergent portion 19a leads.

Because of the retention of the gas flow through the conduit 19, as the section of the conduit is reduced, the speed of the gas flow increases.

This increase in the speed of the flow of gas causes a depression in the zone where the section of the duct is reduced, more particularly at the level of the collar 19c joining the part divergent 19b and the convergent portion 19a of the duct, and induces a suction effect.

This phenomenon is also called Venturi effect.

It will be noted that the neck 19c mixes the flow of gas with the aspired granular material in determined proportions.

The passage 23 has been designed to open, via the annular chamber 27 (connection zone), downstream of the convergent portion 19a, more particularly at the neck 19c, so that the suction effect produced by the flow of gas through the conduit 19 is as effective as possible.

This suction effect makes it possible to establish a flow of granular material from the openings 22 to the ejection channel 20. More particularly, this makes it possible to suck the granular material successively through the openings 22, the upward passage portion 25 , the junction zone 28, the downward passage portion 26, the connection zone 27, the conduit 19, and the ejection channel 20.

The baffle-shaped zone 24 thus guides the flow of granular material from the openings 22 to the conduit 19.

The openings 22 are positioned as close as possible to the bottom 4 of the tank so as to consume the maximum amount of granular material contained in the tank 2.

The baffle-shaped zone 24, more particularly the downward passage portion 26 and the connection zone 27, ensure the mixing of the granular material from the different openings 22.

The flow rate of granular material is determined from parameters (more particularly visible at figure 1c ) of the device 3 which are selected according to the granulometric spectrum of the granular material S.

• la différence d'altitude (a) des bords supérieurs 22a des ouvertures 22 par rapport à l'altitude de la zone de jonction 28,
• la section de passage (b) de la portion de passage ascendante 25 offerte à la matière granuleuse,
• l'angle d'inclinaison (c) de la rampe 25a de la portion de passage ascendante 25 par rapport à une droite orthogonale au fond 4 du réservoir (droite verticale),
• la forme et la dimension de chacune des ouvertures 22 du dispositif 3,
• le diamètre intérieur du gicleur 18.

Relevant parameters include:

• the difference in altitude (a) of the upper edges 22a of the openings 22 with respect to the altitude of the junction zone 28,
• the passage section (b) of the upward passage portion provided to the granular material,
• the angle of inclination (c) of the ramp 25a of the ascending passage portion 25 with respect to a straight line orthogonal to the bottom 4 of the tank (vertical straight line),
• the shape and the dimension of each of the openings 22 of the device 3,
• the inside diameter of the nozzle 18.

An example of adjustment of these five structural parameters of the device (a = 1 mm, b = 5.5 mm, c = 45 °, circular openings with a diameter of 8 mm, internal diameter of the nozzle of 1 mm, with a Sand type SNCF spec ST041) provides output 20b of the ejection channel 20 a flow rate of 0.45 L / min of granular material with an accuracy of 3%. The precision of the flow is improved with regard to commonly used devices. Indeed, the latter generally provide a flow of granular material with an accuracy of about 15%.

When the gas supply circuit 14 is not powered, it does not deliver gas under pressure and there is no ejection of granular material.

As already explained above, the upper edge 22a of each of the openings 22 is at an altitude lower than the altitude of the junction zone 28.

Thus, in the absence of pressurized gas supply, the granular material is retained by the upward passage portion 25 located downstream of the openings 22 due to this difference in altitude (a).

A second embodiment of an ejection device according to the invention is illustrated in FIGS. Figures 3a-c and 4 .

It has the same functional elements as those of the first embodiment of the Figures 1a-c and 2 . However, the arrangement of all of these elements differs as well as the structure of at least some of them.

The figure 3a illustrates a system 50 comprising the granular material reservoir 2 of the figure 1a and a granular material ejection device 52 according to the second embodiment.

The device 52 and the system 50 have the same ends and operate on the same principles as in the first embodiment described above.

The ejection device 52 comprises a main body 54, a base 56 on which is mounted the main body 54, and a pipe 57 and a piece 58 in the form of a plug mounted in the base 56 and an ejection channel 53 fixed on the base 56.

The base 56 comprises fixing means 55 (means illustrated in FIG. figure 4 ) known such as welding, screwing, bolting, snapping ..., to position and fix the device 52 in the bottom 4 of the tank.

The main body 54 comprises openings 62 and a passage 60 located downstream of the openings 62 and connecting them to the duct 57.

This passage 60 more particularly comprises a baffle-shaped zone 66.

The elements described below will be more particularly visible on the figure 3b . The baffle-shaped zone 66 comprises successively from upstream to downstream, an ascending passage portion 68 comprising a ramp 68a, a junction zone 69, and a downward passage portion 70 downstream of the junction zone 69.

The ascending passage portion 68 and the junction zone 69 form a chamber, for example an annular chamber arranged immediately downstream of the openings 62.

The ramp 68a preferably has an angle (c ') of inclination of between 10 and 85 ° with respect to a straight line orthogonal to the bottom of the tank 4 (vertical straight line).

In addition, this passage 60 comprises a connecting zone 72 downstream of the downward passage portion 70.

The downward passage portion 70 and the longitudinal axis (here horizontal) of the duct 57 define between them an angle (β ') of between 70 ° and 110 °, and preferably an angle (β') of 90 °.

The main body 54 is positioned and attached to the upper portion 56a of the base by inserting partially therein.

The main body 54 more particularly comprises two parts assembled one above the other: a first lower part 74 and a second upper part 78.

The first lower piece 74 has a wall inside the main body 54 and whose general profile is funnel-shaped in the axial sectional view of the figure 3b . This funnel comprises an upwardly flared upper portion 74a in the opposite direction of the duct 57. The flared portion 74a forms an angle (δ) with a line parallel to the bottom of the tank 4 (horizontal right). The angle (δ) is between 30 ° and 90 °. The flared portion is extended by an elongate narrowed lower portion 74b which is provided with a lower peripheral edge 74c to be connected to the conduit 57. The funnel comprises, at the top of the flared portion 74a, an upper peripheral edge (corresponding to the junction zone 69) from which outwardly extends a return 74d towards the base and whose inclined portion corresponds to the ramp 68a. The narrowed and elongated portion 74b of the funnel fits into a through hole 76 of the base 56.

The second upper part 78, which caps the first lower part 74, comprises a peripheral wall 78a of substantially cylindrical shape, closed at its upper part by an upper wall 78b. The aforesaid walls 78a, 78b form the outer wall of the main body 54.

The walls 74d, 78a and 74a, 78b define the baffle-shaped zone 66 which is located immediately downstream of the openings 62 in the peripheral wall 78a.

It will be noted that part of the two walls, lower 74d and peripheral 78a, which delimit the ascending passage portion 68 respectively register on two conical surfaces 105 and 106 distant from each other and substantially parallel (these elements are more particularly visible to the figure 3b ). The vertices of the two conical surfaces are positioned, on the one hand, on the axis ZZ 'and, on the other hand, above the main body 54.

It will be noted that part of the lower wall 74a, which delimits the downward passage portion 70, is on a conical surface 107 whose conicity is inverted relative to that of the surfaces 105, 106. of this conical surface is positioned on the axis ZZ 'towards the narrowed and elongated portion 74b of the funnel. The downward passage portion 70 is, for example here, of conical shape but may have a circular shape 70a located upstream of the conical shape 70b (variant illustrated in FIG. figure 3c ) or can be composed of a succession of circular shapes of decreasing diameter connected for example by successive shoulders (other variant not shown).

The openings 62 are for example circular, but it will be noted that other forms of openings are conceivable: oblong, rectangular ... with various orientations. These openings 62 are for example three in number, but a different number may also be suitable: two, four ...

• le conduit 57 comprenant une partie convergente 57a et une partie divergente 57b, cette dernière étant située à l'extrémité 56c où vient se fixer le canal d'éjection 53 sur l'embase 56 ;
• la pièce 58 en forme de bouchon située à l'extrémité 56d de l'embase et qui comprend elle-même les éléments suivants : un logement 82 dans lequel est monté un gicleur 84, ainsi qu'un logement taraudé 80 qui sert de point d'entrée au circuit d'arrivée de gaz 81 sous pression.

The lower part 56b of the base comprises a through hole 59 extending parallel to the bottom of the tank 4 (horizontal orientation) and in which are mounted, successively and coaxially with the through hole 59, the following elements ( figure 3a ):

• the duct 57 comprising a convergent portion 57a and a diverging portion 57b, the latter being located at the end 56c where is fixed the ejection channel 53 on the base 56;
• the piece 58 in the form of a plug located at the end 56d of the base and which itself comprises the following elements: a housing 82 in which is mounted a nozzle 84, and a threaded housing 80 which serves as a point d inlet to the gas inlet circuit 81 under pressure.

The threaded housing 80 is connected to the housing 82 which comprises the nozzle 84 opening into the convergent portion 57a of the conduit.

The conduit 57 is pierced by a lateral orifice 87 which, when the conduit 57 is inserted and fixed in the through-hole 59 of the lower part 56b of the base, is arranged opposite the lower peripheral edge 74c, thus forming a connecting zone 72 between the passage 60 and the conduit 57.

In this arrangement, the narrowed and elongate portion 74c of the funnel is perpendicular to the conduit 57.

It will be noted that in a variant (not shown) the narrowed and elongated portion 74b of the piece 74 can be omitted and the flared portion 74a then immediately opens into the duct 57.

This arrangement is made possible by reducing the height of the base 56 and thus by modifying the fixing system of the ejection channel 53 on the base 56.

The passage 60 opens downstream of the convergent portion 57a and more particularly in the first third of the divergent portion 57b of the conduit.

The ejection channel 53 is substantially bent shape and has at one of its ends an inlet 53a and at the other end an outlet 53b. However, in a variant not shown, the ejection channel 53 may have a straight profile.

The inlet 53a of the ejection channel is disposed in the longitudinal alignment of the duct 57, immediately downstream of the diverging portion 57b.

The lower part 56b of the base comprises fixing means 90 for detachably fixing the ejection channel 53.

These means 90 take for example the form of a flange fixed by studs at the end of the lower portion 56b of the base where the channel 57 opens and coming to press the inlet 53a of the ejection channel against this end 56c .

As in the first embodiment, the device 52 is implemented when the gas supply circuit 81 is supplied with a gas under pressure from a source represented such as the source 12 of the figure 1a .

A flow of pressurized gas through line 57 causes the creation of a suction effect which is sufficient to establish a flow of granular material from openings 62 to line 57 through passage 60.

The passage 60 includes a mixing zone 94 of the granular material from the different openings. This zone 94 comprises the ascending passage portion 68a, the junction zone 69 and the upper funnel portion of the downward passage portion 70.

The flow rate of granular material is determined from parameters (more particularly visible at figure 3b ) of the device 52 which are selected according to the granulometric spectrum of the granular material S.

• la différence d'altitude (a') des bords supérieurs 62a des ouvertures 62 par rapport à l'altitude de la zone de jonction 69,
• la section de passage (b') de la portion de passage ascendante 68 offerte à la matière granuleuse,
• l'angle d'inclinaison (c') de la rampe 68a de la portion de passage ascendante 68 par rapport à une droite orthogonale au fond 4 du réservoir (droite verticale),
• la forme et la dimension de chacune des ouvertures 62 du dispositif 52 et,
• le diamètre intérieur du gicleur 84.

Relevant parameters include:

• the difference in altitude (a ') of the upper edges 62a of the openings 62 with respect to the altitude of the junction zone 69,
• the passage section (b ') of the ascending passage portion 68 provided to the granular material,
• the angle of inclination (c ') of the ramp 68a of the ascending passage portion 68 with respect to a straight line orthogonal to the bottom 4 of the tank (vertical straight line),
• the shape and the dimension of each of the openings 62 of the device 52 and,
• the inside diameter of the nozzle 84.

An example of adjustment of these five structural parameters of the device (a '= 1 mm, b' = 5.5 mm, c '= 45 °, circular shape with a diameter of 8 mm, internal diameter of the nozzle of 1.2 mm, with a sand type SNCF spec ST041) provides output 53b of the ejection channel 53 a flow rate of 0.45 L / min of granular material with an accuracy of 3%. The precision of the flow is improved with regard to commonly used devices.

Indeed, the latter generally provide a flow of granular material with an accuracy of about 15%.

On the figure 5 a variant applicable to the two embodiments illustrated in FIGS. figures 1a and 3a .

The figure 5 is a sectional view of a variant of the body (5 or 54) of a device (3 or 52) according to the invention in a plane parallel to the bottom 4 of the sand reservoir (plane perpendicular to the axis ZZ ') .

In this variant, the passage connecting the openings (22 or 62) to the nozzle-shaped conduit comprises three separate radial channels 96 which each extend radially from one of the openings to a common central space 98 (mixing zone) in which they open.

In the first embodiment, this space 98 corresponds to the annular chamber forming the connecting zone 27 with the duct 19.

In the second embodiment, this space 98 extends vertically (perpendicular to the section plane of the figure 5 ) in the direction of the conduit 57 by a rectilinear portion of tube similar to the narrowed and elongate 74b of the funnel.

Each of the channels 96 comprises, in a view in axial section similar to those of figures 1a and 3a , an upward passage portion (25 or 68) and a downward passage portion (28 or 70) that opens into the common central space 98.

In both embodiments, the parts of the device in contact with the granular material are coated with an abrasion-resistant material or made of a material of this type. The abrasion-resistant material may be, for example, a polymer-based material.

Claims (14)

Device (3; 52) for granular material ejection for railway vehicles, comprising: - at least one opening (22; 62) capable of allowing a flow of granular material into the device (3; 52), a duct (19; 57) comprising a convergent portion (19a; 57a) and a diverging portion (19b; 57b) downstream from said convergent portion (19a; 57a), said duct (19; 57) being capable of creating a suction effect by passage (23; 60) of a gas flow through said conduit (19; 57), said at least one opening (22; 62) being connected to said conduit (19; 57), at least one ejection channel (20; 53) of said flow of granular material disposed downstream of said conduit (19; 57), characterized in that at least one passage (23; 60) connecting said at least one opening (22; 62) to said conduit (19; 57) opens downstream of the convergent portion (19a; 57a) of said conduit (19; ), so as to allow, by said suction effect, to establish said flow of granular material of said at least one opening (22; 62) to said at least one ejection channel (20; 53). A granular material ejection device (3; 52) according to claim 1, characterized in that said at least one passage (23; 60) opens out after the converging portion (19a; 57a) and / or in the diverging portion (19b). 57b), and, for example, in the first third of the diverging portion (19b; 57b). A granular material ejection device (3; 52) according to any one of the preceding claims, characterized in that said at least one passage (23; 60) comprises a baffle-shaped zone (24; 66) downstream of said at least one opening (22; 62), which includes an upward passage portion (25; 68) and a downward passage portion (26; 70) disposed downstream of said portion of ascending passage (25; 68), said baffle zone (24; 66) being for guiding said flow of granular material from said at least one aperture (22; 62) towards the conduit (19; 57) . A granular material ejection device (3; 52) according to claim 3, characterized in that said upward passage portion (25; 68) comprises a ramp (25a; 68a). A granular material ejection device (3; 52) according to claim 3 or 4, characterized in that the upward passage portion (25; 68) and / or said downward passage portion (26; 70) is delimited by walls (5c, 5d, 5e, 5f, 74d, 78b) opposite. Device (3; 52) for granular material ejection according to Claim 5, characterized in that the facing walls (5c, 5d, 5e, 5f, 74d, 78b) delimit at least one of the passage portions (25). , 26; 68, 70) are respectively inscribed on two portions of conical surfaces (101, 102, 105, 106) distant from each other. Device (3; 52) for granular material ejection according to one of Claims 3 to 6, characterized in that said at least one opening (22; 62) comprises an upper edge (22a; 62a), the upward passage portion (25; 68) and the downward passage portion (26; 70) comprise a junction zone (28; 69) connecting said passage portions (25,26; 68,70) to each other; in such a way that the upper edge of the opening (22a; 62a) is located at an altitude lower than the altitude of said junction zone (28; 69). Device (3; 52) for granular material ejection according to claim 7, characterized in that : the difference in altitude (a; a ') between the upper edge (22a; 62a) of the at least one opening (22; 62) and the junction zone (28; 69) of the passage portions (25, 26); 68, 70), - the passage section (b; b ') of the ascending passage portion (25; 68), the angle of inclination (c; c ') of the ascending passage portion (25; 68), the shape and size of each of the openings (22; 62) of the device (3; 52) and the inside diameter of a nozzle (18; 84) capable of injecting gas into the duct (19; 57), are parameters selected according to the particle size spectrum of the granular material (S), so as to obtain a determined value of the flow of granular material. A granular material ejection device (3; 52) according to one of the preceding claims, characterized in that said at least one passage (23; 60) comprises a mixing zone. A granular material ejection device (3; 52) according to one of the preceding claims, characterized in that said at least one passage (23; 60) comprises a connection zone to the conduit (19; 57), said zone being ring-shaped. Granular material ejection device according to any one of the preceding claims, characterized in that the said at least one passage (23; 60) comprises a connection zone to the conduit (19; 57), the said connection zone opening on a sides of the duct (19; 57). A granular material ejection device (3; 52) according to one of the preceding claims, characterized in that the device (3; 52) comprises at least three openings (22; 62) which each comprise a center, said centers defining a plan by wherein the conduit (19; 57) is arranged orthogonally or in parallel. System, characterized in that it comprises: a reservoir of granular material comprising a bottom, - A granular material ejection device according to one of claims 1 to 12, the device being adapted to cooperate with the tank bottom to suck the granular material and establish a flow of said material from said at least one opening until auditing at least one ejection channel of the device. Railway vehicle, characterized in that it comprises a system according to claim 13.

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