• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to a sealing device, in particular for a biological waste processing automaton, comprising a tank (12) having a bottom wall (24) traversed by a shaft (42) bearing in rotation, inside of the tank (12) an annular piece (50) comprising at least a first annular groove (68A) opening towards the wall the bottom wall (24) and housing a first annular seal (96A) bearing axially on an element annular integral (58) of the bottom wall (24) and radially outwardly on a radially outer side annular face (78A) of said annular groove (68A).
    公开号:FR3051686A1
    申请号:FR1654741
    申请日:2016-05-26
    公开日:2017-12-01
    发明作者:Jacques Besnard;Jean Roch;Boguslaw Lorecki
    申请人:Bertin Technologies SA;
    IPC主号:
    专利说明:

    SEALING DEVICE FOR A BANALIZATION AUTOMAT
    WASTE
    The present invention relates in particular to a sealing device intended in particular for sealing the bottom of a tank of a waste treatment machine such as the trivialization of infectious health care waste (called HCW). The invention also relates to such an automaton.
    DASRI waste is generated by health centers such as hospitals, clinics, etc. They include spicy, sharp and / or sharp care materials and materials, blood products for therapeutic use, human anatomical wastes, wastes from teaching, research and industrial production activities in the fields of medicine. human and veterinary, etc. (Article R1335-1 of the Public Health Code of the French Republic).
    These wastes pose an infectious risk because they may contain microorganisms. They therefore follow specific elimination channels, closely supervised by French legislation.
    A waste diversion system of the DASRI type must be able on the one hand to transform the waste to make it unrecognizable (in particular to prevent recognition of its origin or origin) and on the other hand to disinfect it, that is to say to reduce their bacterial and viral population by a factor of at least 5 log10.
    Many banalization systems exist, these systems integrating a grinding function associated with a waste heating function, with a view to disinfecting them.
    The Applicant has already proposed in its application WO2013 / 110900 a waste processor. This automaton is capable of grinding and heating the waste for disinfection, the heating means comprising a microwave generator connected to the tank. The grinding is carried out by a rotating blade inside the tank, this blade being carried by a shaft which passes through a bottom wall of the tank and which is guided in rotation by rolling bearings.
    If this device is particularly effective, a particular point of operation has attracted the attention of the applicant and relates to the sealing of the bottom of the tank. Indeed, it is crucial that the tightness of the bottom of tank is always guaranteed in order to avoid that the waste which is abrasive, sharp and corrosive does not infiltrate in the mechanism of rotation drive, at the level of the interfaces between the fixed and rotating parts.
    The aforementioned document WO2013 / 110900 also describes a vessel comprising a cylindrical side wall provided with an outlet for evacuating gaseous effluents. However, in operation, the waste can obstruct all or part of this opening preventing the evacuation of effluents.
    The present invention is intended to provide a technological solution to the aforementioned problems. To this end, the invention proposes a sealing device, in particular for a biological waste treatment automaton, comprising a vessel whose bottom wall is traversed by a shaft bearing in rotation, inside the one-piece vessel. annular element comprising at least a first annular groove opening towards the bottom wall and housing a first annular seal or annular sealing member bearing in axial direction on an annular element integral with the bottom wall and radially outwardly on one side radially outer side annular of said annular groove.
    According to the invention, the double support of the annular seal or annular seal member on the annular stator element integral with the bottom wall of the vessel and on the radially external lateral annular face of said groove makes it possible to limit the circulation of liquid waste between the annular piece and the stator member. Waste is thus prevented from circulating to elements such as rolling bearings. The operation of a waste processor integrating such a sealing device can therefore be greatly improved.
    According to another characteristic of the invention, resilient support means are interposed axially between an annular bottom wall of said annular groove and said annular seal. In operation, the friction of the annular seal on the annular element leads to a wear thereof which is compensated by the resilient support means. It should be noted that the face of the annular seal in contact with the radially outer side annular face of the groove is not subject to wear because the seal is integral in rotation with the annular piece.
    According to yet another characteristic of the invention, an annular wedge is interposed axially between the resilient support means and the annular seal.
    In a particular embodiment of the invention, the annular wedge has an L-shaped section, a branch of which is interposed between a radially inner annular lateral face of said annular groove and said annular seal.
    Advantageously, the radially outer annular face of the first groove extends axially towards the bottom wall until it is arranged in radial relation with a first cylindrical surface of the annular element. This arrangement makes it even more difficult to circulate the waste which must, to penetrate, then circulate radially upwards between the first cylindrical surface of the annular element and the portion of the radially outer side face of the first annular groove.
    According to another possible definition, the annular piece comprises a radially outer annular wall externally defining the first annular groove and extending towards the bottom wall into a first annular recess L of the annular element.
    In case of failure of one of the constituent elements of the sealing device as described above, it may be advantageous to integrate in the annular part a second annular groove formed radially inside said first annular groove, this second groove housing, similarly to what has been described with reference to the first groove, a second annular seal bearing axially on the annular element integral with the bottom wall and radially outwardly on a lateral annular face radially external of said second annular groove.
    Preferably, the radially outer lateral annular face of the second groove extends axially towards the bottom wall until it is arranged in radial relation with a second cylindrical surface of the annular element.
    In a preferred configuration of the invention, the first cylindrical surface and the second cylindrical surface of the annular element are connected to one another by a radial annular bearing surface of the first annular seal, which allows forming a stepped configuration along the tree.
    According to another possible definition, the annular piece comprises an annular wall separating the first annular groove and the second annular groove and extending towards the bottom wall into a second annular recess L of the annular element.
    The first L-shaped recess and the second L-shaped recess are preferably arranged one after the other radially and axially so as to form a stair-step arrangement which makes it possible to limit the introduction of liquid waste. .
    According to another characteristic of the invention, said first annular seal or annular sealing member comprises a first annular portion made of a first material and a plurality of second portions formed by O-rings housed in grooves of the first part, the first material being adapted to provide a dynamic seal between the annular member and the first annular seal and the second material being adapted to provide a static seal between the annular member and the first annular seal.
    This configuration makes it possible to guarantee a tightness in operation and at a standstill, that is to say when the shaft is not rotated. The second annular seal could also be formed in several parts as described in the previous paragraph.
    According to another characteristic of the invention, the annular groove or grooves are of U-shaped section comprising substantially cylindrical lateral faces and perpendicular to a substantially radial bottom annular face, the seal being of rectangular section, preferably square.
    Preferably, said annular seal is made of a cured polymer material capable of being thermally resistant to temperatures of the order of 300 ° C., essentially due to the friction of the rotating shaft inducing a high heat dissipation and mechanically at operating speeds. rotation of the order of 1500 revolutions per minute. The annular element is preferably structurally independent of the bottom wall and is sealingly applied to the inner face of the bottom wall, that is to say the face arranged inside the vessel.
    The device according to the invention can, of course, include means for grinding waste carried by the shaft and mounted opposite the bottom wall relative to the annular piece. The invention also relates to a first type of automated waste treatment, in particular the trivialization of infectious health care waste, comprising at least one sealing device as described above. The invention also relates to a second type of waste processing automaton, in particular for trivialization of infectious health care waste, comprising a tank intended to be fed with waste, a lid mounted to move at the end. upper part of the tank between an open position and a sealed position of the tank, means for heating waste for disinfection thereof comprising at least one microwave generator whose output is connected to an end of a waveguide, the other end of which opens into the tank, in which the lid carries a duct for evacuating gaseous effluents and is in fluidic communication, in the closed position of the lid, with the inside of the tank through cover, this conduit having means for trapping electromagnetic waves to prevent leakage of waves in the conduit.
    According to the design of this second type of automaton, the evacuation of gaseous effluents is facilitated because of their circulation through the lid and no longer through the side wall of the vessel as in the prior art. In addition, the wave leaks are prevented at the level of the conduit.
    Preferably, in the second type of automaton, the trapping means comprise an end portion of the substantially cylindrical conduit connected to the vessel and whose internal diameter and length are determined so as to provide a trap for the fundamental mode of the generator. microwave. The microwave trap is made simply by determining a suitable shape for a portion of the conduit in fluid communication with the vessel.
    According to another characteristic of this second type of automaton, said end portion is connected by a bent portion to another portion of conduit connected to suction means.
    The duct may be carried by a support integral with the lid and be connected downstream to a flexible conduit connecting the suction means.
    In a practical embodiment of the lid of the second type of automaton, the lid comprises a bottom wall and an upper wall defining between them a cavity connecting the inside of the tank to the conduit.
    Preferably, the bottom wall carries a frame comprising at least one annular row of openings communicating with the cavity, said annular row of openings being centered on the axis of the lid. Each opening can also house a solid waste blocking grid. The frame may further comprise a second annular row of openings surrounding the first annular row of openings.
    The microwave generator is preferably a magnetron that operates at a frequency between 1 and 3 GHz, and for example about 2.45 GHz.
    The second type of automaton may optionally include: a sealing device as described above and / or means for grinding the waste carried by a lower bottom wall of the tank. The invention will be better understood and other details, features and advantages of the invention will become apparent on reading the following description given by way of non-limiting example with reference to the accompanying drawings, in which: FIG. 1 is a view schematic perspective of the waste processing machine according to the invention; - Figures 2 and 3 are partial schematic views of the automaton of Figure 1, seen from above and in axial section, respectively; FIG. 4 is another schematic perspective view of the automaton of FIG. 1; FIG. 5A is a diagrammatic view, along a section plane containing the axis of rotation of the grinding means, of the sealing device according to the invention integrated in the automaton of FIG. 1; FIG. 5B is a view on a larger scale of the zone delimited in dashed lines in FIG. 5A; - Figure 5C is an isolated view of an annular seal of the sealing device according to the invention; FIGS. 6 and 7 are diagrammatic perspective views, viewed from below and from above, of a sealing cover for the tank of the automaton of FIG. 1; - Figure 8 is a schematic perspective view in section of the lid of Figures 6 and 7; FIGS. 9 and 10 are diagrammatic perspective views of a mounted dual-port module forming a waveguide connected, in one embodiment, to the inlet of the tank of the automaton of FIG.
    Reference is first made to FIGS. 1 to 4, which represent an exemplary embodiment of the waste treatment automaton 10 according to the invention, this automaton being particularly but not exclusively intended for the trivialization of health care waste. at risk of infection ("DASRI").
    In the example shown, the automaton 10 essentially comprises three elements: a waste treatment tank 12, in which the waste is intended to be ground and heated for the purpose of their treatment, this waste being introduced into the tank with their packaging which is also intended to be ground; a microwave generator 14 for feeding the tank 12 with microwaves intended to heat the waste with a view to disinfecting them; and - computerized control means 16 connected to the tank 12 and the generator 14 for their control as well as for the data entry and recording and the management of the waste treatment process.
    The control means 16 comprise an electrical cabinet which comprises in particular an information display screen 18 and control of the treatment process, as well as information acquisition means. Preferably, the screen 18 is of the touch type and an operator can enter information and make requests directly via this screen 18. The electrical cabinet of the control means 16 is directly placed on the ground.
    The microwave generator 14 is a magnetron that operates at a frequency between 1 and 3 GHz. In a particular embodiment of the invention, the magnetron has the following characteristics: frequency of 2450 MHz, power of 3 kW in multi-mode.
    In a first embodiment, the magnetron 14 is connected to the tank 12 by a waveguide 20 which provides a power coupling between the magnetron 14 and the tank 12. In the example shown, the waveguide 20 comprises a end portion connected to the vessel 12 which is more flexible or more flexible than the rest of the waveguide. This part of greater flexibility or flexibility may be formed by a waveguide portion with corrugated metal walls. The outer surface of this portion may or may not be coated with different protective materials to suit most vibration requirements.
    In operation, the magnetron 14 may be supplied with water for cooling purposes. In the example shown, the automaton 10 comprises a water cooler 22 (FIG. 1) whose input is connected to one end of a water circuit of the magnetron and an output is connected to another end of this circuit. 'water. The magnetron 14 can be supplied with water at a pressure of 3 bar and at a flow rate of 3L / min. The controller 10 comprises a frame 21 for supporting the tank 10, this frame being directly placed on the ground and, in one embodiment, independent of the support means of the generator 14 to avoid, during the grinding of the waste, the transmission of vibrations by the chassis to the magnetron. In the example shown, the frame 21 has a parallelepipedal shape and is disposed in front of the generator 14, which is itself arranged to the right of the cabinet of the control means 16 (Figure 2).
    In a variant not shown, the generator 14 is mounted on the frame 21 by means of vibration absorption means, such as elastomeric blocks or compression springs.
    As can be seen in FIGS. 1 and 2, the automaton 12 may further comprise a raised stage or platform 23 which is accessible by an operator to visualize and control the display screen of the control means 16 as well as the tank 12. This platform 23 is here located in front of the control means 16 and left of the frame 21 (Figures 1 and 2). An operator can access this platform 21 by steps which are located on the front of the platform. The automaton 10 can furthermore comprise means 25 for weighing the waste before and / or after their treatment (FIGS. 1 and 2), these weighing means being, for example, of the weighing type. These weighing means 25 are located in front of the frame 21 and to the right of the access steps to the platform 23.
    The side wall of the tank 12 of the automaton 10 is made of steel and has a generally cylindrical shape with a vertical longitudinal axis. The tank has a volume of 440L in the example shown. This volume is in particular a function of the quantity of waste to be treated and the maximum volume of packaging in which the waste is conditioned when it is introduced into the tank.
    The tank 12 is closed at its lower end by a bottom 24 (FIG. 5A) and at its upper end by a cover 26 (FIGS. 6 to 8). This lid 26 is pivotally mounted at the upper end of the tank between a closed position of the tank (shown in Figure 4) and an open position thereof (not shown). The structure of the lid will be described in more detail with reference to FIGS. 6 to 8.
    The displacement of the lid 26 between these positions can be carried out manually or by means of a motor or a jack controlled by the control means 16 of the automaton 10. In the case where the automaton 10 comprises one or pneumatic cylinders, these cylinders are connected to a pneumatic supply system which preferably delivers an air flow of the order of 200L / min at a pressure of about 6 bars.
    The tank 12 is further equipped with means 28 for locking its cover 26. These locking means 28 prevent the opening of the tank, in particular when a waste treatment cycle is in progress. These locking means 28 are preferably actuated by the control means 16.
    The bottom 24 of the tank 10 may comprise a hatch (not shown) of passage and discharge of waste after treatment, to a tank 32 for recovery and storage of waste, which is housed in the tank (Figure 4). The passage of waste from the tank 12 to the tank 32 can be achieved simply by gravity. The opening and closing of the hatch are controlled by the control means 16.
    As can be seen in FIG. 4, the tray 32 is housed in a lower recess of the frame 21, this recess being closed by a pivoting door 34 which can be associated with locking means controlled by the means 16.
    Waste grinding means are mounted at the bottom of the tank 12 (FIG. 5A) and comprise a blade 38 rotatably mounted around a vertical axis 42 aligned on the axis of the tank 12 and driven in rotation about this axis 42 by a motor 40 carried by the frame (Figure 3).
    The tank 12 comprises a substantially flat bottom wall 24 traversed by a shaft 42 connected to rotate with the motor 40 and guided in rotation by rolling bearings 44. In the remainder of the description, the term "axial" refers to a direction extending along the axis 46 of the shaft 42 and the term "radial" is to be interpreted in relation to the direction in which the line extends. 46. The shaft 42 comprises an annular rib 48 arranged inside the tank 12 and carrying an annular piece 50 which comprises on its radially inner cylindrical edge an annular groove 54 in which is engaged an annular seal 56 section circularly for making a sealing junction between the annular piece 50 and the shaft 42. The grinding blade 38 is engaged on the shaft 42, above the annular piece 50, that is to say the opposite of the bottom wall 24 with respect to the annular piece 50.
    As is clearly visible in FIGS. 5A and 5B, an annular element 58 of stator integral with the bottom wall 24 is interposed axially between the bottom wall 24 and the annular part 50. This annular element 58 is made integral with the wall bottom 24 by screws 60. It also comprises an annular groove 62 open towards the bottom wall 24, in which is engaged an annular seal 66 with circular section.
    The annular piece 50 also comprises a first external annular groove 68A and a second radially inner annular groove 68B which open towards the annular stator element 58. The first annular groove 68A is delimited radially by a radially outer annular wall 70 and an intermediate annular wall 72. The second annular groove 68B is delimited radially by the intermediate annular wall 72 and a radially inner annular wall 74. Each of the first annular groove 68A and second annular groove 68B comprises two radially inner lateral annular faces 76A, 76B and outer 78A, 78B forming the flanks of the grooves 68A, 68B and interconnected by an annular bottom wall 80A, 80B. The annular walls 76A, 78A, 76B, 78B form faces of the inner annular walls 74, intermediate 72 and outer 70. In the embodiment shown in Figures 5A and 5B, each of the first groove 68A and second groove 68B has a section U-shaped and the two inner annular side faces 76A, 76A and outer 78A, 78B are substantially cylindrical, the bottom annular wall 80A, 80B of each of the first groove 68A and second groove 68B is substantially radial.
    The radially outer annular wall 70 of the annular piece 50 comprises an outer frustoconical surface 82 with a section decreasing in the direction of the blade 38. This frustoconical surface 82 extends towards the blade 38 by another frustoconical surface 84 which itself is extended by a radial annular wall 86. The frustoconical wall 82 of the radially outer annular wall 70 is less flared than the other frustoconical wall 84. These frustoconical shapes facilitate the circulation of waste in the space between the blade and the annular part.
    The radially outer lateral annular face 78A of the first groove 68A extends to be arranged with a clearance vis-à-vis radial of a first cylindrical surface 88 of the annular element 58. Similarly, the annular face radially outer side 78B of the second groove 68B extends to be arranged with a clearance vis-à-vis radial of a second cylindrical surface 90 of the ring member 58. The first cylindrical surface 88 and the second surface cylindrical 90 are connected to each other by a first radial annular surface 92. The end of the second cylindrical surface 90 is extended, at its end opposite the first radial annular surface 92, by a second radial annular surface 94 The abovementioned games (not shown) correspond to the clearances required to mount the annular piece 50 on the annular element 58 and to guarantee good support of the annular seals. 96A, 96B on the radially outer cylindrical faces 78A, 78B of the annular grooves 68A, 68B and the cylindrical walls 92, 94 of the annular element. As can be seen in FIG. 5B, the cylindrical surface 88 delimits with a radial annular surface 97 of the annular element 58 a first annular recess in which is engaged an end of the annular wall 70. The radial annular surface 97 delimits a slot annular 101 with a radial annular face 99 of the outer annular wall 70 which is vis-à-vis axial. Note that the radial annular surface 99 and the cylindrical annular face 78A are connected to one another. Also, the cylindrical surface 90 and the radial surface 92 of the annular element 58 together define a second annular recess in which extends the intermediate annular wall 72 separating the first groove 68A and the second groove 68B. The first L-shaped recess and the second L-shaped recess are thus arranged one after the other in the radial and axial direction so as to form an arrangement in step of staircase which makes it possible to limit the introductions of liquid waste. Indeed, the second annular recess is arranged radially inside the first annular recess and is arranged axially opposite the bottom wall with respect to the first annular recess.
    In operation, the waste entering the annular slot 101 is prevented from circulating to the bearings 44 by the surface 88 of the annular element.
    More specifically, the seal between the annular piece 50 and the annular element 58 is formed by a first annular seal 96A engaged in the first annular groove 68A and a second annular seal 96B engaged in the second annular groove 68B. An annular shim 98A, 98B is mounted in each of the first and second annular grooves 68A, 68B. Each annular wedge 98A, 98B has an L shape and comprises a first branch 100 and a second branch 102. The first branch 100 of each shim 98A, 98B is interposed between resilient support means 104 and the annular seal 68A, 68B . The second leg 102 of each shim 98A, 98B is interposed between the radially inner lateral annular face 76A, 76B of each of the first and second annular grooves 68A 68B.
    Thus, the resilient support means makes it possible to axially constrain the first seal 96A and the second seal 96B, respectively, on the first radial annular face 92 and the second radial annular face 94 of the annular element 58 to guarantee a good contact during the rotation of the annular piece 50. The second legs 102 of the shims 98A, 98B are dimensioned so that the radially outer annular face of each seal 68A, 68B bears on the radially outer side face 78A, 78B of the groove 68A, 68B.
    The resilient support means may comprise an elastically deformable blade, for example.
    In order to guarantee a tightness in operation and also to stop the rotation of the shaft 42, it is advantageous to make the seals 96A, 96B in several parts. Thus, each seal 96A, 96B may comprise a first annular portion 104 made of a first material and a plurality of second portions 106 formed by O-rings made of a second material different from the first material. These O-rings are housed in annular grooves of the first portion 104 of each of the first and second seals 96A, 96B and are intended to come, simultaneously with the first part, in contact with the first and second radial annular faces 92, 94 of the annular element 58 and with the radially outer lateral annular faces 78A, 78B of the first and second grooves 68A, 68B.
    The first portion 104 of the first and second seals 68A, 68B is preferably made of cured polymer and the second portions 106 are made of polymer.
    In the embodiment shown in FIGS. 5A, 5B and 5C, the first and second annular seals 96A, 96B have a rectangular, preferably square section.
    If the invention described with reference to the figures has the stator annular element 58 or static as a part independent of the bottom wall 24, it is understood that the annular element could be formed in one piece with the annular bottom wall. 24 so that no annular sealing means interposed between the annular element and the annular wall would then be provided.
    Figures 6 to 8 show a particular embodiment of a cover 108 can be used on a tank 12 as described above but also on any other type of tank.
    Thus, the cover 108 comprises a circular bottom wall 110 intended to come into contact with the biological waste and a circular upper wall 112 arranged at a distance from the bottom wall 110. To limit the leakage of waves, they are trapped by means such as quarter-wave traps, traps with absorbent materials and / or joints formed of metal braids. An electromagnetic shielding seal 111, in metallic braids, can also be mounted on the inner peripheral edge of the cover 108 and is intended to be clamped between this edge and the upper peripheral edge of the tank in the closed position of that -this.
    The bottom wall 110 and the upper wall 112 are connected to each other by an outer peripheral edge 114 and define between them three sealed cavities 116A, 116B, 116C arranged side by side and delimited by spacers or partition walls 118 lower wall 110 and upper 112. The bottom wall 110 comprises a central opening whose perimeter carries a frame 120 made of metallic material (Figures 6 and 8). The armature 120 comprises two radially inner and outer annular rows of openings 122 each housing a solid waste blocking grid. These openings 122 have a shape of angular sector and make it possible to put in fluidic communication, in the closed position of the cover 108, the central cavity 116B of the cover 108 and the inside of the tank 12. The upper wall 112 carries an articulated arm 124 in rotation for the displacement of the cover 108. The upstream end of a duct 126 passes through the arm 124 and opens through the upper wall 112 into the central cavity 116B of the cover 108. Thus, the gaseous effluents can be discharged into the leads 126.
    The conduit 126 which is rigid can be connected by a flexible conduit to suction means equipped with a filter, for example of the activated carbon type, for retaining toxic molecules, harmful or unpleasant for humans. The integration of the outlet of the effluents on the cover 108 makes it possible to greatly reduce the blocking of the outlet relative to a positioning of the outlet on the cylindrical wall of the tank 12.
    To prevent leakage of waves in the conduit 126, the latter comprises means for trapping electromagnetic waves. For this, the duct 126 comprises a substantially cylindrical end portion 126A connected to the tank 12 and whose internal diameter and length are determined so as to provide a trap of the fundamental mode of the microwave generator. This proximal end portion 126A is connected to a distal portion 126C also cylindrical by a bent portion 126B. The proximal end portion 126A has a diameter of 70 mm and a length of 140 mm to realize a trap of the electrical transverse fundamental mode 1,1 (TE11) at the frequency of 2450 MHz. Of course, these values are only illustrative of the particular embodiment described.
    In another embodiment, the magnetron 14 may be mounted directly on the tank 12, with or without a vibration damping device. In this configuration, the waveguide 128 connecting the magnetron 14 to the tank 12 is formed by a tubular module 128 having a substantially rectangular shape (Figures 9 and 10). Each end of the conduit 130 of the module 128 includes a window 132, 134 or window through which the microwaves are intended to pass. The first window 132 is intended to be fixed in an opening of the side wall of the tank 12. This first porthole 132 is made of a suitable material transparent to the microwaves generated by the magnetron 14, which is for example a dielectric polymer material such as Teflon®, PP, PEEK, etc. The window 132 provides mechanical protection of the waveguide 128 during the grinding phase. The second window or porthole 134 may have the same technical characteristics as the first window 132 and makes it possible to protect the magnetron 14 from infiltration of moisture through the first porthole 132 which could cause an electric arc which would damage the magnetron 14.
    The module 128 may comprise impedance matching means which are here of the element type (screw, piston, rod, stubs, etc.) immersed in the conduit 130 of the module 128. Each element 136 passing through a wall of the conduit 130 and being engaged or depressed in the conduit 130 in a controlled manner so that the recessed portion in the conduit forms an obstacle to the electromagnetic waves passing through the conduit 130 and thus causes partial reflections of the electromagnetic waves. The impedance adapter makes it possible to optimize the operating parameters of the magnetron 14, by optimally adjusting the depth of penetration of the above-mentioned plunging elements 136 in the conduit 130 of the waveguide, which makes it possible in particular to limit reflection. electromagnetic waves by the waste. The combination of several of these reflective elements 136 and their depression in the conduit 130 of the waveguide thus makes it possible to adapt the impedances, seen by the magnetron, of the constituent charges of the complete circuit (in order to obtain maximum efficiency absorption of energy by the waste in the tank).
    权利要求:
    Claims (14)
    [1" id="c-fr-0001]
    1. Sealing device, in particular for biological waste treatment automaton, comprising a tank (12) having a bottom wall (24) traversed by a shaft (42) bearing in rotation, inside the tank (12) an annular piece (50) comprising at least a first annular groove (68A) opening towards the bottom wall (24) and housing a first annular seal (96A) bearing axially on a fixed annular element (58) the bottom wall (24) and radially outwardly on a radially outer side annular face (78A) of said annular groove (68A).
    [2" id="c-fr-0002]
    2. Device according to claim 1, wherein resilient bearing means (104) are interposed axially between an annular bottom wall (80A) of said annular groove (68A) and said annular seal (96A).
    [3" id="c-fr-0003]
    3. Device according to claim 2, wherein an annular shim (98A) is interposed axially between the resilient support means (104) and the annular seal (96A).
    [4" id="c-fr-0004]
    4. Device according to claim 3, wherein the annular wedge (98A) has an L-shaped section, a branch (102) is interposed between a radially inner annular side face (76A) of said annular groove (68A) and said annular seal (68A).
    [5" id="c-fr-0005]
    5. Device according to one of claims 1 to 4, wherein the radially outer annular surface (78A) of the first groove (68A) extends axially towards the bottom wall (24) until it is arranged vis-à-vis. radial view of a first cylindrical surface (88) of the annular element (58).
    [6" id="c-fr-0006]
    6. Device according to one of the preceding claims, wherein said annular piece (50) comprises a second annular groove (68B) formed radially inside said first annular groove (68A) and housing a second annular seal (96B). in axial bearing on the integral annular element (58) of the bottom wall (24) and radially outwardly on a radially outer lateral annular face (78B) of said second annular groove (96B).
    [7" id="c-fr-0007]
    7. Device according to claim 6, wherein the radially outer lateral annular face (78B) of the second groove (68B) extends axially towards the bottom wall (24) until it is arranged facing the radial axis. a second cylindrical surface (90) of the annular element (58).
    [8" id="c-fr-0008]
    8. Device according to claim 5 and claim 7, wherein the first cylindrical surface (88) and the second cylindrical surface (90) of the annular element (58) are connected to each other by an annular surface radial (92) of support of the first annular seal (96A).
    [9" id="c-fr-0009]
    The apparatus according to one of claims 1 to 8, wherein said first annular seal (96A) comprises a first annular portion (104) made of a first material and a plurality of second portions (106) formed by housed O-rings. in grooves of the first part, the first material being adapted to provide a dynamic seal between the annular element and the first annular seal and the second material being adapted to provide a static seal between the annular element and the first annular seal.
    [10" id="c-fr-0010]
    10. Device according to one of the preceding claims, wherein the annular groove or grooves (68A, 68B) are U-section including side faces (76A, 78A, 76B, 78B) substantially cylindrical and perpendicular to an annular face of bottom (80A, 80B) substantially radial, the seal (96A, 96B) being rectangular in section.
    [11" id="c-fr-0011]
    11. Device according to one of the preceding claims, wherein said annular seal (96A, 96B) is made of a cured polymeric material.
    [12" id="c-fr-0012]
    12. Device according to one of the preceding claims, wherein the annular element (58) is independent of the bottom wall (24) and is applied sealingly on the inner face of the bottom wall (24).
    [13" id="c-fr-0013]
    13. Device according to one of the preceding claims, characterized in that it comprises grinding means waste (38) carried by the shaft and mounted opposite the bottom wall (24) relative to the annular piece (50).
    [14" id="c-fr-0014]
    14. An automated waste treatment, in particular the trivialization of waste care activities at risk of infection, comprising at least one sealing device according to one of the preceding claims.
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    同族专利:
    公开号 | 公开日
    EP3463672A1|2019-04-10|
    CN109562389A|2019-04-02|
    WO2017203172A1|2017-11-30|
    PH12018502567A1|2019-10-28|
    CN206083380U|2017-04-12|
    FR3051686B1|2018-08-31|
    CN205949444U|2017-02-15|
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    FR3051686B1|2016-05-26|2018-08-31|Bertin Technologies|SEALING DEVICE FOR A WASTE BANALIZATION AUTOMATE|FR3051686B1|2016-05-26|2018-08-31|Bertin Technologies|SEALING DEVICE FOR A WASTE BANALIZATION AUTOMATE|
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    法律状态:
    2017-05-30| PLFP| Fee payment|Year of fee payment: 2 |
    2017-12-01| PLSC| Search report ready|Effective date: 20171201 |
    2018-05-28| PLFP| Fee payment|Year of fee payment: 3 |
    2019-05-31| PLFP| Fee payment|Year of fee payment: 4 |
    2020-05-30| PLFP| Fee payment|Year of fee payment: 5 |
    2021-05-31| PLFP| Fee payment|Year of fee payment: 6 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1654741A|FR3051686B1|2016-05-26|2016-05-26|SEALING DEVICE FOR A WASTE BANALIZATION AUTOMATE|
    FR1654741|2016-05-26|FR1654741A| FR3051686B1|2016-05-26|2016-05-26|SEALING DEVICE FOR A WASTE BANALIZATION AUTOMATE|
    CN201620537230.6U| CN206083380U|2016-05-26|2016-06-03|Sealing device and waste disposal automatic device|
    CN201620537179.9U| CN205949444U|2016-05-26|2016-06-03|Waste disposal automatic device|
    EP17732974.5A| EP3463672A1|2016-05-26|2017-05-24|Sealing device for a waste processing machine|
    PCT/FR2017/051289| WO2017203172A1|2016-05-26|2017-05-24|Sealing device for a waste processing machine|
    CN201780046541.XA| CN109562389A|2016-05-26|2017-05-24|For making the water-tight equipment of the machine of waste safety|
    PH12018502567A| PH12018502567A1|2016-05-26|2018-12-06|Sealing device for a waste processing machine|
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