FR2913902A1 - DEVICE AND METHOD FOR REALIZING AN INDUSTRIAL THERMAL TREATMENT OF EXTENDED MECHANICAL PARTS. - Google Patents

Abstract

The present invention relates to a method and a device for heat treatment of elongated mechanical parts provided with an oven (20) provided with a cylinder (21) cylindrical arranged in a chamber (22) heated, said ring (C1, C2, C3 ) having at least one storage tube (25) parallel to said axis of symmetry (AX1). This device is remarkable in that it comprises at least one hollow elongate delivery tube (11) of said mechanical parts for guiding them towards a storage tube (25) which can contain at least one mechanical part via an inlet orifice ( E1, E2, E3), and in that it comprises at least one hollow elongate ejection tube (18) of said mechanical parts for guiding them when said mechanical parts leave the storage tube (25) of said cylinder (21) by said outlet orifice (S1, S2, S3) after a predetermined rotation of this barrel (21), said inlet orifices (E1, E2, E3) and outlet ports (S1, S2, S3) being arranged on an upstream face (F1) of the enclosure (22).

Description

Device and method for performing industrial heat treatment of

  The present invention relates to a device and a method for producing an industrial heat treatment of elongated mechanical parts, and more particularly for springs. In general, the springs are produced from a manufacturing unit in the form of a linear strip and then cut from this linear strip to the desired length. They must then undergo a heat treatment step by being heated to a predetermined temperature for a predetermined period of time before being packaged in transport bins. Document FR1598224 discloses a first device provided in particular with a heating chamber. The latter comprises a cylindrical carrier cylinder 15 equidistant radial compartments, that is to say, compartments directed along the radius of the barrel, and opening out at the periphery of this barrel. In addition, the barrel is animated by a jerky rotation movement. It then receives on the upstream side of the enclosure a cold mechanical part in an empty compartment and then the cylinder starts to rotate so that this cold room is heated during its rotation. Finally, on the downstream side of the enclosure, the barrel expels the heated mechanical part after a rotation of about a half-turn of this barrel.

  This first device therefore meets the needs by allowing the heating of a mechanical part. However, it has the disadvantage of not being able to heat the mechanical parts on a half turn which does not optimize the rate of production.

  However, this aspect is essential insofar as these production rates are very important being between 20000 and 40000 springs per hour for example. In addition, it is found that all mechanical parts will be heat treated, even if some mechanical parts 10 are defective. US Pat. No. 115,114 discloses a second device provided with a heating chamber in which is disposed a cylindrical barrel with equidistant and through axial compartments. Each compartment thus opens onto the upstream and downstream bases of the cylindrical barrel. In addition, the heating chamber has an inlet on its downstream face and an outlet on its upstream face, metal parts entering the enclosure on one side and out of this chamber by the opposite side. Specifically, a first metal piece falls from a funnel into a rotating gin that then rotates a quarter of a turn. The ginner then drops said first metal piece into a unitary receptacle and receives a second piece of metal in another of its cavities.

  The first metal part is then pushed by a cylinder to enter an empty compartment of the barrel via the inlet port of the enclosure. It can now be seen that each compartment can contain only one metal part at a time, the entire device being exclusively provided for this purpose. The cylinder is then rotated in a single direction by a motor. When the compartment containing said first metal part is vis-à-vis the outlet port, a second jack pushes the first piece to the out of the enclosure, the latter falling into a receptacle once the orifice of exit crossed. This second device is obviously effective. However, the production rates are limited insofar as it can only insert a metal part in an axial compartment without possibility of making another. In addition, the cylinder compartment vis-à-vis the outlet port is separated from the compartment vis-à-vis the inlet port by a third of the compartments. Once empty, a compartment will not be immediately filled which limits the rate of production. Finally, when they leave the enclosure, the metal parts fall into a receptacle, which does not facilitate their future conditioning.

  The object of the present invention is to propose a device and a method for the thermal treatment of mechanical parts such as springs, making it possible to overcome the limitations mentioned above, in particular by authorizing high industrial production rates and facilitating packaging. future mechanical parts. According to the invention, a device for heat treatment of elongated mechanical parts such as springs is provided with a furnace equipped with a cylindrical barrel arranged in a heated chamber, this barrel comprising at least one ring rotated around a axis of axial symmetry of the cylindrical barrel by a drive means. In addition, the ring has at least one storage tube parallel to the axis of symmetry adapted to receive at least one mechanical part to be heated, said chamber having an inlet and an outlet orifice of the mechanical parts located equidistant from the axis of symmetry for each ring of the barrel. Advantageously, the first ring comprises a plurality of storage tubes arranged on its periphery equidistant from each other.

  This heat treatment device is remarkable in that it is provided with at least one longiline conveying tube and hollow mechanical parts for guiding these mechanical parts to a storage tube to be filled via the inlet port of the device. enclosure along a filling axis parallel to the axis of symmetry of the cylinder and therefore the crown. The mechanical part is thus conveyed axially towards an axial compartment of a ring, in this case an axial storage tube and through, the storage tube can contain at least one mechanical part. In addition, the device comprises at least one elongated ejection tube and hollow mechanical parts for guiding these mechanical parts when they exit the storage tube of said cylinder through the outlet orifice after a predetermined rotation of the cylinder, said orifices input and output being arranged on the same upstream face of the heated enclosure perpendicular to the axis of symmetry of the barrel. The mechanical parts therefore enter a storage tube along a filling axis parallel to the axis of symmetry of the barrel and to said storage tube, via an inlet port. Similarly, they come out along an axis of ejection parallel to the filling axes. Instead of falling into a receptacle where they could get tangled, the mechanical parts are then conveyed to a packaging machine which will allow to place them carefully in storage bins provided for this purpose. However, it is conceivable to drop the mechanical parts into a receptacle, if they do not require strict packaging, instead of routing them to a conditioner. Furthermore, the inlet and outlet ports are arranged equidistant from the axis of symmetry on the same upstream face of the enclosure. This very particular arrangement makes it possible to limit the bulk of the production line by returning the mechanical parts in a direction opposite to their direction of arrival and not the opposite. As required, the furnace comprises a plurality of coaxial rings, said furnace thus being provided with an outlet port, an inlet port, a conveying tube and a crown ejection tube. arranged on the same upstream face of the enclosure.

  In order to limit the installation costs of the device, the same furnace therefore has several crowns, three for example, each ring being intended for a particular type of mechanical parts. In the frame of the springs, we can have different crowns depending on the diameters of the springs, by providing a first ring for springs with a diameter of five millimeters and a second ring for springs with a diameter of fourteen millimeters, for example . It is understood that the first ring will have storage tubes of one diameter smaller than those of the second ring. Depending on the nature of the metal parts to be heated in the various crowns, the crowns depend on each other. They are then set in motion by a single drive means, the rotation of a ring causing the rotation of another ring. By cons, otherwise, the crowns will be independent and set in motion by their own means of training. This variant is particularly useful if the heating times of the mechanical parts of a ring differ from the heating times of the mechanical parts of another ring. In addition, the device advantageously comprises a first air injection means for this air pushes the mechanical parts of a conveyance line to the storage tube 25 via a conveying tube. This first air injection means may be that for moving the mechanical parts of their manufacturing unit to the routing tube.

  Similarly, the device comprises a second means of injecting air so that air pushes the mechanical parts of the storage tubes to the ejection tube of the corresponding ring, the second air injection means being arranged on a downstream face of the enclosure, opposite its upstream face. The second injection means also makes it possible to propel the heated mechanical parts of the ejection tube towards a possible packaging machine while passing through an ejection line. Advantageously, the device is provided with a ginning means 10 for sequentially filling said at least one crown storage tube. According to a first variant, the filling is performed individually. The ginning means fills a crown storage tube by sending the mechanical parts one after the other until the storage tube is full. Then, the barrel rotates until it has an empty storage tube in front of the inlet port for refilling. According to a second variant, the filling is carried out by packet. The ginning means blocks the mechanical parts in the conveying tube until the latter contains all the mechanical parts to enter the empty storage tube. Then, it releases the set of mechanical parts thus formed and fills at once the storage tube. Preferably, the ginning means comprises two electromagnets, arranged on the conveying tube, which operate alternately, the downstream electromagnet being in the locked position when the upstream electromagnet is in the open position, and vice versa. According to a first and a second embodiment, in order not to waste time, it is advantageous that the device is provided with a sorting means so as not to heat-treat defective mechanical parts. These defective mechanical parts are then detected by means of a visual detection means, a camera for example, defects of a mechanical part upstream of the conveying tube.

  According to the first preferred embodiment, the sorting means comprises a ring waste orifice arranged on the upstream face between the inlet and outlet orifices of said ring, said waste orifices, inlet and outlet being located equidistant from the axis of symmetry.

  A complementary air injection means is for example used to expel a defective mechanical part through the waste orifice, the complementary air injection means blowing the air through the downstream face of the enclosure, opposed to said upstream face.

  Concretely, according to this first embodiment, a storage tube located opposite the waste orifice is disposed between a storage tube vis-à-vis the inlet orifice and a storage tube vis-à-vis the to the outlet port. The cooking of the mechanical parts takes place in the time interval allowing the crown to rotate 360 degrees minus two steps using a stepper motor, for example, the inlet and outlet ports. output being separated by two steps, a first step separating the inlet port and the waste port while another step separates the waste port and the outlet port. Such an arrangement maximizes this heating time. The sorting method according to this first embodiment will be explained later.

  Note that as needed, there may be a different number of steps between the various orifices, two steps between the inlet port and the waste port and two other steps between the waste port and the orifice Release. Indeed, to be able to arrange a large number of storage tubes on a ring in a small space, it may be necessary to separate the various orifices of two steps instead of one. According to a second embodiment, the sorting means is offset by being arranged upstream of the conveying tube or between this conveying tube and the spring manufacturing unit.

  The remote sorting means then comprising a flexible hose coaxial with a mechanical material conveying line, this sorting means is provided with a means of attraction which attracts the hose to offset it from the conveyance line. Therefore, the defective part will fall into a receptacle provided for this purpose since it will not enter the hose, the latter having been off-axis. Unlike the first embodiment, there is no waste orifice on the upstream face of the heated enclosure. The storage tube vis-a-vis the inlet port is thus also adjacent to the storage tube vis-à-vis the outlet port.

  Furthermore, according to a third embodiment, the device does not include sorting means. In this case, if a ring has a plurality of storage tubes, the storage tube vis-a-vis the inlet orifice is advantageously adjacent to the storage tube vis-à-vis the outlet port. As a result, once emptied, a storage tube will be immediately filled which optimizes production rates. Finally, the device comprises a control means for managing and controlling the heat treatment device. This control means manages in particular the speed of rotation of the crown (s) and the temperature of the enclosure. In addition, if a sorting means is provided on the device and a defective component is detected, the control means will instruct a sorting means to take action at the desired time to expel said defective component. Furthermore, the present invention also relates to a heat treatment process of elongated mechanical parts that can be implemented by a device according to the invention as described above with an oven comprising a barrel arranged in a heated chamber. The method is remarkable in that the following steps are successively carried out: a) the mechanical parts are inspected visually in order to detect the defective mechanical parts, b) at least one mechanical part which has no defect in a tube is penetrated; storing a barrel via an inlet orifice arranged on a downstream face of the chamber, the storage tube being parallel to an axis of axial symmetry of the barrel, c) the barrel is rotated in a first direction around its axis of axial symmetry so that said at least one mechanical part disposed in the storage tube is heated, and d) said furnace being provided with an outlet orifice on said downstream face, said at least one mechanical part contained by said tube storage is ejected from said furnace when said storage tube reaches said outlet port.

  This process therefore makes it possible to optimize the heat treatment by only thermally treating the valid mechanical parts, which causes a considerable saving of time. In addition, because of the arrangement of its inlet and outlet ports, it is easy to dispose the device on an existing production line. In addition, this method optimizes production rates by minimizing the time during which a storage tube is empty. advantageously; prior to step b), the mechanical parts are skewed to enter said at least one storage tube in a predetermined sequence. According to the first variant of the device explained above, the sequence is to penetrate the mechanical parts one by one in a storage tube and then move to the next tube once the storage tube filled.

  According to the second variant of the device explained above, the predetermined sequence consists in storing a plurality of mechanical parts one after the other in a conveying tube in front of the inlet orifice, and then filling in a single operation the storage tube. by sending at once all the mechanical parts stored. Once the storage tube fills, we move on to the next. According to a first embodiment, a sort is made at the oven. This furnace is provided with a waste orifice arranged on its downstream face between the inlet and outlet orifices of the ring concerned, the waste ports, inlet and outlet being located equidistant from the axis of symmetry. if, during step a), the presence of a defective mechanical part is detected, when this defective part is in front of the inlet orifice and the barrel comprises a plurality of storage tubes, the following operations are performed: the barrel is rotated in the first direction in order to inject the said defective piece into the first empty storage tube which is in front of the inlet orifice, and then the defective piece is injected into the first storage tube which is present in front of the inlet port, and - the barrel is rotated in a second direction, contrary to the first direction, until the first storage tube containing the defective piece reaches the discharge port to evacuatethis defective piece through this scrap hole.

  It should be noted that the filling of a storage tube, carried out during step a), resumes simultaneously with the ejection phase of evacuating the defective piece through the reject orifice, which optimizes the rate of production. . The ejection is thus done in masked time. According to a second embodiment, sorting is carried out upstream of the conveying tube. If a detection means notices the presence of a defective mechanical part, the sorting means is instructed to off-set a flexible pipe from the routing line so that the defective piece falls into a receptacle and does not reach the tube. routing. According to a third embodiment of the invention, no sorting of the mechanical parts will be carried out. The invention and its advantages will appear in more detail in the context of the following description, which illustrates preferred exemplary embodiments, given without any limiting character, with reference to the appended figures which represent: FIG. 1, a longitudinal section of FIG. treatment device according to the second embodiment, - Figure 2, a radial section of the processing device according to the first embodiment at the inlet and outlet ports, - Figure 3, a radial section of the device of treatment according to the second embodiment at the cylinder, - Figure 4, a radial section of the processing device according to the second embodiment at the second air injection means, - Figure 5, a schematic view. a sorting means according to the second embodiment, and - Figure 6, a schematic view of a ginning means according to the invention. The elements present in several separate figures are assigned a single reference.

  Figure 1 shows a longitudinal section of the heat treatment device according to the second embodiment. This device is provided with an oven 20 containing a heated enclosure 22 inside which is arranged a cylindrical barrel 21 adapted to receive elongated mechanical parts to be heated, springs for example. Referring to Figure 3, the cylindrical barrel 21 is provided with a first, a second and a third coaxial rings C1, C2, C3. These first, second and third rings are integral with each other and are rotated about the axis of axial symmetry AX1 of the barrel being connected to a drive means 23, a stepper motor for example, via a belt 24.

  It should be noted that the number of crowns can vary according to the need being reduced to its congruent portion, namely a single crown. However, the use of a plurality of rings makes it possible to use a single furnace for a plurality of production lines, which has a certain advantage. Similarly, it is conceivable to separate the crowns depending on the need and in particular the heating times of the mechanical parts. Each ring has at least one through-tube 25 which opens onto the downstream face FI and the upstream face F2 of the barrel 21. The storage tubes 25 are arranged on the periphery of the rings, being parallel to the axis of symmetry AX1 of FIG. barrel. Furthermore, the device comprises a hollow elongate routing tube 11 visible in Figure 6 and masked by the ejection tubes 18 in Figure 1, by ring C1, C2, C3. The mechanical parts from their manufacturing unit are then guided by these routing tubes 11 to an inlet port E1, E2, E3 located on the upstream face F1 of the enclosure as shown in Figure 2. Once With the inlet orifice crossed, the mechanical parts penetrate directly into the storage tube of the cylinder opposite this inlet orifice. The routing of the mechanical parts is then performed along a filling axis parallel to the axis of symmetry AX1.

  Advantageously, with reference to FIG. 3, each ring has a plurality of storage tubes 25, each storage tube 25 being able to contain a plurality of mechanical parts. As a result, the device is able to ensure high production rates industrial. For each ring C1, C2, C3, there is therefore an inlet port E1, E2, E3 and 11 hollow elongate routing tube.

  In addition, the device comprises an elongate and hollow crown ejection tube 18 opposite an outlet orifice S1, S2, S3 located on the upstream face F1 of the chamber with reference to FIG. It should be noted that the inlet and outlet orifices of the same ring are arranged equidistant from the axis of symmetry AX1 because of the cylindrical shape of the barrel and therefore of the rings. At the end of their heating period, the mechanical parts leave the cylinder storage tube through the outlet orifice corresponding to their ring and are removed from the device by an ejection tube 18 parallel to the axis of symmetry AX1 barrel. This device can be implemented by the method according to the invention. During a step a), the mechanical parts are inspected visually at their output from a manufacturing unit.

  This inspection can be performed by a fault inspection means which is therefore located upstream of the relevant routing tube of the device. The routing line separating the manufacturing unit from the routing tube then comprises a portion consisting of a transparent pipe, not shown in the figures, through which the visual detection means, a camera for example, inspects the parts. mechanical devices in transit.

  During a step b) which follows step a), a control means of the device causes one or more faultless mechanical parts to penetrate into a first storage tube 25 via an inlet orifice E1, E2, E3. It should be noted that a first air injection means blows air into the conveying line to push the mechanical parts into the storage tube.

  Once the first storage tube 25 is filled, during a step c), the control means rotates the barrel ring in a first direction around the axis of symmetry AX1. A second empty storage tube then being vis-à-vis the inlet port, the control means repeats the previous step to fill it. Meanwhile, the mechanical parts contained in the first storage tube are heated.

  When the first storage tube reaches the outlet orifice, after having made a rotation of 300 if one refers to the schematic version in the figures, the mechanical parts are ejected from the first storage tube. As a result, with reference to FIG. 4, the device comprises a second injection means 44, 45, 46 of air that blows air into the storage tube via the downstream face F 2 of the opposite heating chamber. at the upstream face F1, to propel the mechanical parts through the outlet orifice and the ejection tube to direct them to a packaging unit for example. Moreover, in order to perfectly control the routing of the mechanical parts to the inlet orifice, during an intermediate step prior to step b), the mechanical parts are stripped to penetrate the storage tubes 25 in a predetermined sequence by means of ginning means 10. For each conveying tube 11, the ginning means comprises a downstream electromagnet 14 and an upstream electromagnet 15.

  The upstream electromagnet 15 is fixed while the downstream electromagnet 14 is movable along an axis parallel to the axis of symmetry AX1 so as to allow local adjustment as a function of the length of the mechanical parts. In addition, each electromagnet activates a locking means which passes through the delivery tube to block or let the mechanical parts circulate, a needle or a retractable blade adapted to pass through a spring to block for example. The two electromagnets of a tube operate alternately, an electromagnet being in the locked position when the other electromagnet is in the open position and allows the mechanical parts to pass. According to a first variant, the filling is unitary. To begin, the downstream electromagnet 15 is in the blocking position while the upstream electromagnet 16 is open and passes a mechanical part.

  Then, the upstream electromagnet 16 goes into the blocking position and prevents other mechanical parts from circulating in the transport tube. In contrast, the downstream electromagnet 15 is placed in the open position which allows the mechanical part to penetrate into the storage tube. This operation is repeated until the storage tube is full. At this point, the control means rotates the ring (s) of the barrel, with the aid of the drive means, to present a new storage tube 25 in front of the filling orifice so as to continue the sequence filling. According to a second variant, the control means performs batch packing. For this variant, the space separating the upstream electromagnet from the downstream electromagnet corresponds to the length of the filler tubes. To begin, the downstream electromagnet 15 is in the blocking position while the upstream electromagnet 16 is open and lets all mechanical parts to enter the filler tube. Then, the upstream electromagnet 16 goes into blocking position and prevents

  the other mechanical parts to circulate in the transport tube. On the other hand, the downstream electromagnet 15 is placed in the open position, which makes it possible to fill the storage tube in a single operation, allowing all the mechanical parts to pass through at once in this storage tube.

  Then, the control means rotates the barrel, with the aid of the drive means, to present a new storage tube in front of the filling port so as to continue the filling sequence.

  Moreover, according to a first and a second embodiment, the device comprises a sorting means preventing the heat treatment of the defective parts detected during step a). According to a first embodiment, the sorting means comprises a waste orifice R1, R2, R3 per ring, represented in FIG. 2, arranged on the upstream face F1 of the heated enclosure 22 between the inlet orifices El, E2, E3 and output S1, S2, S3, the inlet ports E1, E2, E3, output S1, S2, S3 and scrap R1, R2, R3 of a ring being located equidistant from the axis of symmetry AX1. In addition, with reference to FIG. 4, the device comprises an additional injection means 41, 42, 43 per crown, on the downstream face F 2 of the enclosure for expelling a defective part from a storage tube by the waste port.

  This first embodiment is advantageously coupled with the first ginning variant described above. When the control means detects a defective mechanical part, it blocks it just before the inlet orifice of the enclosure and does not penetrate into a first storage tube during filling.

  It then rotates the barrel ring in a first direction to present a second empty storage tube, and injects the defective piece into this tube. As a result, the control means rotates the barrel in a second direction, contrary to the first direction, to put the second storage tube vis-à-vis the waste port and put the first storage tube in process of filling vis-à-vis the filling port. The filling of the first tube can then resume. In parallel, the control means activates the complementary ejection means to move the defective piece out through the waste port. Figure 5 shows a second embodiment. The manufacturing unit 50 sends the mechanical parts to the heated enclosure 22 of the treatment device. The sorting means is then deported and comprises a hose 52 arranged on the conveyance line. If a mechanical part is defective, the control means activates an attracting means, an electromagnet 53 for example, to offset the hose 52 from the conveyance line. The defective mechanical part can not then cross the hose and falls along the arrow F in a receptacle 54 provided for this purpose. Naturally, the present invention is subject to many variations as to its implementation. Although several embodiments have been described, it is clear that it is not conceivable to exhaustively identify all the possible modes. It is of course conceivable to replace a means described by equivalent means without departing from the scope of the present invention.

Claims (16)

  1. Device for heat treatment of elongated mechanical parts provided with an oven (20) provided with a cylinder (21) cylindrical arranged in a chamber (22) heated, said cylinder (21) having at least one ring (C1, C2) , C3) rotated about an axial axis of symmetry (AX1) of said barrel (21) by a drive means (23), said ring (C1, C2, C3) having at least one storage tube (25) ) parallel to said axis of symmetry (AX1), said enclosure (22) having an inlet port (E1, E2, E3) and an outlet port (S1, S2, S3) located equidistant from said axis of symmetry (AX1 ) for each ring (C1, C2, C3) of said barrel (21), characterized in that it comprises at least one hollow elongate routing tube (11) of said mechanical parts for guiding them towards a storage tube (25) which can contain at least one mechanical part via said inlet orifice (E1, E2, E3) along a filling axis parallel to said axis of symmetry and in it comprises at least one hollow elongate ejection tube (18) of said mechanical parts for guiding them when said mechanical parts leave the storage tube (25) of said cylinder (21) via said outlet orifice (Si, S2, S3) after a predetermined rotation of this barrel (21), said inlet orifices (E1, E2, E3) and outlet (Si, S2, S3) being arranged on an upstream face (F1) of the enclosure (22). ) heated perpendicular to the axis of symmetry of the barrel.   2. Device according to claim 1, characterized in that said furnace (20) comprising a plurality of coaxial rings (C1, C2, C3), said enclosure (22) is provided with an outlet orifice (Si, S2, S3 ), an inlet port (E1, E2, E3), a conveying tube (11) and an ejection tube (18) per ring (C1, C2, C3) arranged on said upstream face (F1).   3. Device according to any one of the preceding claims, characterized in that it comprises a first air injection means for said air pushing said mechanical parts of a conveying line to said storage tube (25). ).   4. Device according to any one of the preceding claims, characterized in that it comprises a second air injection means (44, 45, 45) for said air pushes said mechanical parts of said storage tubes (25). towards the ejection tube (18) of the corresponding ring (C1, C2, C3), said second air injection means (44, 45, 46) being arranged on a downstream face (F2) of the enclosure (22) opposite said upstream face (F1).   5. Device according to any one of the preceding claims, characterized in that it is provided with a ginning means (10) for sequentially filling said at least one storage tube (25) of a crown (Cl , C2, C3).   6. Device according to claim 5, characterized in that said ginning means (10) comprises two electromagnets (14, 15), arranged on a conveying tube (11), which operate alternately.   7. Device according to any one of the preceding claims, characterized in that it is provided with a sorting means for not thermally treating defective mechanical parts.   8. Device according to claim 7, characterized in that, said sorting means being arranged upstream of said conveying tube (11), said sorting means having a hose (52) coaxial with a conveyance line (51). ) mechanical parts, the sorting means is provided with an attracting means (53) which attracts said hose (52) to offset it from said routing line (51).   9. Device according to claim 7, characterized in that said sorting means comprises a waste orifice (R1, R2, R3) per ring (C1, C2, C3) arranged on said upstream face (F1) between the inlet orifices. (E1, E2, E3) and output (Si, S2, S3) of said ring, said waste orifices (R1, R2, R3), input (E1, E2, E3) and output (Si, S2 , S3) being located equidistant from the axis of symmetry (AX1).   10. Device according to claim 9, characterized in that it is provided with a complementary air injection means (41, 42, 43) for expelling a defective mechanical part by said waste orifice (R1, R2, R3), said complementary air injection means (41, 42, 43) 2, opposite to said upstream face (F1).   11. Device according to any one of claims 9 to characterized in that it comprises a control means for managing and controlling the heat treatment device.   12. Device according to any one of claims 9 to 11, characterized in that it comprises a means for visually detecting defects of a mechanical part upstream of said conveying tube (II).   13. A method of heat treatment of elongated mechanical parts that can be implemented by a device according to any one of claims 1 to 12 provided with an oven (20) having a cylinder (21) arranged in a chamber (22) heated , characterized in that one proceeds successively to the following steps: a) said mechanical parts are inspected visually in order to detect the defective mechanical parts, b) at least one mechanical part having no defect is penetrated into a storage tube (25) of a barrel (21) via an inlet orifice (El, E2, E3) arranged on a downstream face (F1) of said enclosure (22), said storage tube (25) being parallel to an axis of axial symmetry (AX1) of said barrel (21), c) said barrel (21) is rotated in a first direction about its axis of axial symmetry (AX1) so that said at least one mechanical part disposed in said storage tube (25) is heated, and d) said our (20) being provided with an outlet (S1, S2, S3) on said downstream face (F2), said at least one mechanical part contained by said storage tube (25) is ejected from said furnace (20) when said storage tube (25) reaches said outlet port (Si, S2, S3).   14. A method of heat treatment of mechanical parts according to claim 13, characterized in that, prior to step b), said mechanical parts are meshed so as to enter said at least one storage tube (25) according to a predetermined sequence.   15. A method of heat treating mechanical parts according to claim 14, characterized in that said predetermined sequence consists in storing a plurality of mechanical parts one after the other in a conveying tube (11) in front of said inlet port (El, E2, E3), then to fill in a single maneuver the storage tube (25) by sending at once all of said stored mechanical parts.   16. A method of heat treatment of mechanical parts 5 according to any one of claims 13 to 15, characterized in that, said furnace (20) being provided with a waste orifice (R1, R2, R3) arranged on said face downstream (F1) between the inlet (E1, E2, E3) and outlet (Si, S2, S3) ports of said ring (C1, C2, C3), said waste orifices (R1, R2, R3), 10 input (E1, E2, E3) and output (Si, S2, S3) being located equidistant from the axis of symmetry (AX1), if during step a) detects the presence of a piece mechanical defective, when this defective part is in front of said inlet port (E1, E2, E3), said cylinder having a plurality of storage tubes (25), it: -turning said cylinder (21) in said first in order to inject said defective part into the first storage tube which is in front of said inlet port (E1, E2, E3), then, said defective part is injected into said p first storage tube which is in front of said inlet (E1, E2, E3), and - the barrel (21) is rotated in a second direction, contrary to said first sense, until the first tube The storing piece containing the defective piece reaches said derebus port (R1, R2, R3) in order to evacuate this defective piece through this scrap hole (R1, R2, R3).