EP0911080A1 - Centrifuge with dismountable rotor and a device for the axial locking of the rotor on the drive shaft and rotor for such a centrifuge - Google Patents

Abstract

A centrifuge has a rotating driving head (2) fixed to a rotating shaft (43), a rotor (3) fixed to the driving head, a means (21) of coupling the driving head and the rotor in rotation, and a means of blocking axial movement on the shaft comprising a means of applying an axial force to a surface (9) of the rotor where the force increases with the rotational speed of the driving head. The means of applying an axial force to the rotor has at least two inertial masses (56) mounted on one end of the driving head symmetrically about its axis of rotation (42). Each mass can be moved between a position unblocking the rotor axially, in which the mass is retracted into the driving head, and a position blocking the rotor axially, depending on the speed of rotation of the head. In this position, the pressing part of the mass extends beyond the external radial surface (49) of the driving head and acts with a ramped surface (11) to a receiving opening (7) on the rotor. This ramped surface is inclined towards the inside of the opening and towards the pressing surface (9) of the rotor. The ramp is conical. At least one mass is held elastically from its retracted position to an initial blocking position. The pressing surface (9) and the holding surface (47) are conical and matched. At least one mass is a shock load to produce a resonant signal during the blocking. An Independent claim is included for a rotor for a centrifuge as above with a receiving opening for at least one end of a driving head, with a surface pressing against the holding surface and at least one ramp which acts with part of a mass, inclined towards the inside from the outside and towards the pressing surface.

Description

The present invention relates to a centrifuge of the type comprising a rotational drive head integral a rotation shaft, a rotor that can be mounted removably on the drive head, in a position rotary drive, coupling means in rotation of the drive head and the rotor, and a axial rotor locking device on the head drive comprising application means, on the rotor, of an axial holding force of a bearing surface of the rotor against a retaining surface integral with the head training.

Such centrifuges are, in particular, used in the biological field to centrifuge products contained in containers arranged in housings formed in the rotor.

A drive head of such a centrifuge generally has a vertical axis and extends the upper part a training axis. A corresponding rotor is provided with a lower opening for receiving the head.

When the rotor is rotated by the drive head, the latter is subjected to forces which tend to separate it axially from the head and take it off.

Various axial rotor locking devices on the drive head currently exist.

WO 83/04379 describes a centrifuge of the aforementioned type in which the axial holding force of the rotor is exerted by a helical spring bearing, on the one hand, on an upper shoulder of a closing lid the rotor and, on the other hand, on a lower shoulder an actuating member, a rod of which is intended to be axially retained by snap-fastening in an axial bore of the training head.

A user can manually disconnect the rotor and drive head thanks to the body actuation, by compressing the helical spring.

In this centrifuge, the holding force axial is constant and limited to values allowing manual use of the actuator.

This axial holding force may prove to be insufficient, especially at high rotational speeds, such than those encountered in ultracentrifuges and which can reach 150,000 rpm.

In addition, the centrifuge described in the document WO 83/04379 involves using a cover closing the rotor to be able to lock the rotor axially on the drive head, which complicates assembly / disassembly operations of the rotor on the drive head.

The object of the invention is to solve these problems by providing a centrifuge with a locking device axial is suitable for a wide range of rotational speeds of the drive head, and simplifies operations mounting / dismounting the rotor on the head training.

To this end, the invention relates to a centrifuge of the type comprising a rotary drive head integral with a rotation shaft, a rotor which can be removably mounted on the drive head, in a rotational drive position, means rotating coupling of the drive head and the rotor, and an axial rotor locking device on the drive head comprising application means, on the rotor, of an axial holding force of a surface of the rotor against a retaining surface integral with the drive head, characterized in that the means application of a holding force are means application of an increasing holding force with speed of rotation of the drive head.

• les moyens d'application d'une force de maintien comprennent au moins deux masselottes d'inertie montées, de manière symétrique par rapport à l'axe de rotation de la tête d'entraínement, sur une partie d'extrémité de la tête d'entraínement, mobiles chacune entre une position de déblocage axial du rotor et de la tête d'entraínement, dans laquelle la masselotte est rétractée dans la tête d'entraínement, et une position de blocage axial du rotor sur la tête d'entraínement dépendant de la vitesse de rotation de la tête d'entraínement, dans laquelle une partie de poussée de la masselotte est en saillie par rapport à une surface radialement extérieure de la tête d'entraínement et coopère avec une surface de rampe d'une ouverture de réception de la partie d'extrémité de la tête d'entraínement ménagée dans le rotor, cette surface de rampe étant inclinée vers l'intérieur de l'ouverture et vers la surface d'appui du rotor ;
• la surface de rampe est sensiblement tronconique ;
• au moins une masselotte est rappelée élastiquement depuis sa position rétractée vers une position de blocage axial initial du rotor sur la tête d'entraínement ;
• les masselottes sont montées à rotation sur la partie d'extrémité de la tête d'entraínement et comprennent chacune un appendice de manoeuvre actionnable simultanément par un organe extérieur, lorsque le rotor est en position d'entraínement, pour ramener les masselottes dans leurs positions rétractées de déblocage axial du rotor et de la tête d'entraínement ;
• la surface d'appui du rotor et la surface de retenue de la tête d'entraínement sont sensiblement tronconiques et conjuguées, la surface de retenue formant une surface de centrage du rotor sur la tête d'entraínement ; et
• une masselotte est une masselotte de choc pour provoquer un signal sonore lors du blocage axial du rotor sur la tête d'entraínement.

According to particular embodiments, the centrifuge can include one or more of the following characteristics:

• the means for applying a holding force comprise at least two inertia weights mounted, symmetrically with respect to the axis of rotation of the drive head, on an end portion of the head drive, each movable between an axial unlocking position of the rotor and of the drive head, in which the counterweight is retracted in the drive head, and an axial locking position of the rotor on the drive head dependent on the speed of rotation of the drive head, in which a thrust part of the counterweight projects from a radially outer surface of the drive head and cooperates with a ramp surface of an opening for receiving the end part of the drive head formed in the rotor, this ramp surface being inclined towards the inside of the opening and towards the bearing surface of the rotor;
• the ramp surface is substantially frustoconical;
• at least one counterweight is returned elastically from its retracted position to an initial axial locking position of the rotor on the drive head;
• the weights are rotatably mounted on the end part of the drive head and each comprise a maneuvering appendage actuated simultaneously by an external member, when the rotor is in the drive position, to return the weights to their retracted positions axial release of the rotor and the drive head;
• the bearing surface of the rotor and the retaining surface of the drive head are substantially frustoconical and conjugate, the retaining surface forming a centering surface of the rotor on the drive head; and
• a flyweight is a shock flyweight to cause an audible signal during the axial locking of the rotor on the drive head.

The invention finally relates to a rotor for a centrifuge as defined above, characterized in that it includes a reception opening of at least one end part of a drive head of a centrifuge, said opening having a bearing surface against a retaining surface secured to the head drive, and at least one ramp surface intended for cooperate with a thrust part of a flyweight of the drive head, this ramp surface being inclined towards the inside of the opening and towards the bearing surface.

• la surface de rampe est sensiblement tronconique ; et
• la surface d'appui est sensiblement tronconique. L'invention sera mieux comprise à la lecture de la description qui va suivre, donnée uniquement à titre d'exemple, et faite en se référant aux dessins annexés sur lesquels :
• la figure 1 est une vue latérale en coupe partielle d'une centrifugeuse selon l'invention, la tête d'entraínement étant représentée en vue latérale,
• les figures 2, 3 et 4 sont des vues en coupe de la tête d'entraínement de la centrifugeuse de la figure 1, prises suivant la ligne II-II de la figure 1, et représentant respectivement les masselottes en position de blocage initial, en position de blocage lorsque la tête d'entraínement tourne, et en position de déblocage, et
• la figure 5 est une vue analogue à la figure 1, illustrant l'utilisation d'un rotor sans couvercle.

According to particular embodiments, the rotor can include one or more of the following characteristics:

• the ramp surface is substantially frustoconical; and
• the bearing surface is substantially frustoconical. The invention will be better understood on reading the description which follows, given solely by way of example, and made with reference to the appended drawings in which:
• FIG. 1 is a side view in partial section of a centrifuge according to the invention, the drive head being shown in side view,
• Figures 2, 3 and 4 are sectional views of the drive head of the centrifuge of Figure 1, taken along the line II-II of Figure 1, and respectively representing the weights in the initial locking position, blocking position when the drive head rotates, and in the unlocking position, and
• Figure 5 is a view similar to Figure 1, illustrating the use of a rotor without cover.

Figure 1 partially shows a centrifuge 1 essentially comprising a drive head 2, a rotor 3 mounted in the drive position on the head 2, a removable cover 4 closing the rotor 3, and an actuating member 5 secured to the cover 4.

The rotor 3 is of generally frustoconical shape converging towards an upper face 6 (in FIG. 1) of the rotor 3, and it is made, for example, of aluminum. A bore stepped 7, coaxial with the rotor 3, crosses the latter.

This bore 7 is delimited successively from a lower face 8 of the rotor 3, by a bearing surface frustoconical 9 converging towards the upper surface 6, by a cylindrical surface 10, by a frustoconical surface of ramp 11 diverging towards the upper surface 6, then by two successive cylindrical surfaces 12 and 13, respectively larger diameter and smaller diameter, connected by a shoulder 14 substantially orthogonal to the axis rotor 3.

The ramp surface 11 is inclined towards inside the bore 7 and towards the bearing surface 9.

The ramp surface 11, the cylindrical surface 12 and the shoulder 14 define an annular groove 15.

The angle of convergence of the bearing surface 9 by relative to the axis of the rotor 3 is approximately 30 °.

The angle of divergence of the ramp surface 11 relative to the axis of the rotor 3 is approximately 75 °.

The upper surface 6 has a peripheral rim annular 16 projecting axially from the surface 6.

The rotor 3 comprises housings 100 (one of which only is shown in Figure 1), opening into the surface 6, for ampoules or other containers intended for contain products to be centrifuged.

A cap 17, of generally cylindrical stepped shape, is fixed by a flange 18 on the upper surface 6 of the rotor 3, coaxially with the latter. A lower part cylindrical 19 of the cap 17 is received at low clearance in the part of bore 7 delimited by the surface cylindrical 13. The cap 17 closes the bore 7.

The lower surface 20, substantially orthogonal to the axis of the rotor 3, of the part 19 of this cap 17, is provided with two pins 21 for rotating coupling, in axial projection relative to the surface 20, and diametrically opposite to each other with respect to the axis of the rotor 3.

The cap 17 is crossed by a stepped bore central 22 comprising an upper cylindrical part 23 (in Figure 1) of larger diameter and threaded, and a lower cylindrical part 24 of smaller diameter.

The cover 4 has a generally frustoconical shape, and it is provided on its lower surface 25 (in the figure 1) a peripheral rim 26 projecting axially from this surface 25.

The cover 4 is crossed by a central opening circular 27.

The cover 4 is removably attached and watertight on the rotor 3, as described below. The ledge 26 of the cover 4 is fitted inside the flange 16 of the rotor 3 and the cover 4 is coaxial with the rotor 3.

The actuator 5, shown in position rest in Figure 1, includes a cylindrical body 28 crossed by a central bore 29, a sliding rod 30 in the bore 29, and a handle 31 secured to the cylindrical body 28.

The lower part of the body 28 is externally threaded.

The upper end of the rod 30 is extended by a knob 32, coaxial with the rod 30. The knob 32 is connected to the rod 30 via a lower face 33 of the knob 32, substantially orthogonal to the axis of the rod 30, and of diameter greater than that of rod 30.

The rod 30 is provided on its outer surface a transverse groove in which an elastic ring 34 is received.

The lower end 35 of the rod 30 is tapered.

A spring 36 is threaded on the rod 30 and takes support, on the one hand, on an upper surface 37 of the body 28 and, on the other hand, on the lower surface 33 of the pommel 32.

The handle 31 is a generally cylindrical piece stepped, crossed by a central bore 39, in which an upper part of the body 28, the spring 36 and a lower part of the knob 32 is received. The body 28 is fixed to the handle 31 coaxially. Spring 36 and the lower part of the knob 32 can slide in bore 39.

The upper part of larger diameter 40 of the handle 31 is knurled.

The actuator 5 is symmetrical with respect to to a longitudinal axis.

The body 28 passes through the opening 27 and it is fixed on the cover 4 by sealingly sealing this opening 27.

The rotor 3, the cover 4 and the member actuation 5 are coaxial.

The lower part of the body 28 is screwed into the part 23 of the bore 22 of the cap 17, thus ensuring fixing the cover 4 to the rotor 3.

In the rest position of the organ actuator 5 shown in Figure 1, an upper part knob 32 is located projecting from an upper surface 41 of the handle 31 and the end tapered 35 of the rod 30 is projecting axially below the surface lower 20 of the cap 17, the rod 30 passing through bore 29 and bore 22. The elastic ring 34 is in support against the lower surface of the body 28 and the spring 36 is slightly compressed.

As illustrated in Figures 1 and 2, the head drive is symmetrical about an axis 42 and it is attached to the upper end of a rotation shaft 43 vertical of centrifuge 1, coaxially to the latter. The axis of rotation of the rotation shaft 43 and of the drive head 2 is coincident with the axis 42, and it is shown in phantom in Figure 1.

The drive head 2 successively comprises a cylindrical part 44 for connection to the shaft drive 43, a frusto-conical part 45, converging towards an upper surface 46 of the head 2 and delimited by a retaining surface 47, and an upper end portion 48 of generally cylindrical shape, delimited above by the surface 46 which is substantially orthogonal to axis 42.

The diameter of the cylindrical part 44 is less the largest diameter of the frustoconical part 45, and the radially outer surface 49 of the part 48 extends the retaining surface 47.

The angle of convergence of the retaining surface 47 with respect to the axis 42 is approximately 30 ° and corresponds to the angle of convergence of the bearing surface 9 of the rotor 3.

Two identical recesses 51 are provided in the cylindrical part 48, substantially equal distance from the edge upper of the retaining surface 47 and of the surface 46, and symmetrically with respect to a plane 52 (Figure 2) passing through the axis 42 and orthogonal to the plane of Figure 1. These recesses 51 are cylindrical in shape, with a parallel axis at axis 42, and at base in circular segment.

These recesses 51 define between them a wall central 53 vertical. This wall 53 is crossed by a transverse recess 54, of axis orthogonal to the plane 52, and of rectangular base.

A vertical blind bore 55, coaxial to the head 2, and opening into the surface 46, passes through the wall 43 of the cylindrical part 48. This bore extends into the wall 53 below the recess 54. The diameter of this bore 55 corresponds substantially to the outside diameter of the rod 30 of the actuating member 5.

The drive head 2 includes two weights identical 56. These flyweights 56 each include a body 57 of shape corresponding to that of the recesses 51, and an actuating tail 58 extending the corresponding body 57 at the level of an upper part of its lateral face plane 59. The counterweights 56 are produced, by example, bronze or stainless steel.

The weights 56 are each mounted to rotate on the drive head 2, in a recess 51, by means pegs 61 with axes parallel to axis 42 and traversing each one of the recesses 51.

Weights 56 are mounted symmetrically relative to axis 42.

The pins 61 are offset from the plane 62 (plane of FIG. 1) orthogonal to plane 52 and passing by axis 42.

The tails 58 are received in the recess 54 of the wall 53.

Coil return springs 63 are arranged away from the pins 61 between each counterweight 56 and the wall 53.

Weights 56 have lateral surfaces curved thrust 64 whose upper edge 65 is chamfered (Figure 1) and whose lower edge 66 is rounded.

The surface 46 of the head 2 is provided with two nipples 67 coupling in rotation, projecting axially from this surface 46, and diametrically opposite to each other relative to axis 42.

The flyweights 56 are movable in rotation around pins 61 each between an unlocking position axial of the rotor 3 and of the drive head 2, and a position axial locking of the rotor 3 on the dependent head 2 the speed of rotation of the drive head as explained below.

When the flyweights 56 are in the unlocking position axial (Figure 4) the push surfaces 64 extend the outer surface 49 of part 48, the weights 56 then being retracted into the head 2. The tails 58 weights 56 are tangent to the cylindrical surface delimiting the bore 55. The springs 63 are then compressed.

When the flyweights 56 are in the position of axial locking (Figures 2 and 3) the push surfaces 64 weights 56 protrude from the surface 49 of part 48. The tails 58 of the flyweights 56 are located inside the cylindrical surface delimiting bore 55.

There is a position of initial axial locking weights 56 (Figure 2) when the rotor 3 is mounted on head 2 and that the latter is at rest.

When head 2 turns, as shown by a arrow, the centrifugal force tends to rotate the weights 56 around the ankles 61 clockwise on figure 2 and tends to get them out of head 2 to reach a blocking position depending on the speed of rotation of the head 2 (figure 3). The push surfaces 64 are all the more protruding from the surface 49 of part 48 that the speed of rotation of the head 2 is high.

To use centrifuge 1, a user proceed, for example, as described below.

First, the user places containers containing products to be centrifuged in the housings 100, then fix the cover 4 on the rotor 3, using the handle 31, by screwing the body 28 of the organ 5. Knurling of part 40 of the handle 31 ensures good grip of the handle 31.

Then, the user comes to place the rotor 3 closed by the cover 4 on the drive head 2 as shown in figure 1.

Weights 56 are initially in a position intermediate between the positions represented on Figures 2 and 3, the springs 63 not being compressed.

When inserting head 2 into the bore 7 of the rotor 3, the bearing support surface 9 of the rotor 3 cooperates with the upper edge 65 of the pushing surfaces 64 weights 56 and push the weights 56 towards their unlocking positions (Figure 4) by compressing the springs 63.

Release positions are reached simultaneously by the flyweights 56 when the thrust surfaces 64 are in contact with the cylindrical surface 10 of the bore 7 of the rotor 3.

The retaining surface 47 of the drive head 2 allows the rotor 3 to be centered on the head 2.

When the rotor 3 continues to descend in plugging into the drive head 2, the flyweights 56 no longer cooperate with the cylindrical part 10, and the springs 63 push the latter radially towards outside to their initial blocking positions (Figures 1 and 2). In these positions, the bottom edges 66 of the pushing surfaces 64 are supported on the surface ramp 11 of rotor 3 under the action of springs 63.

This automatic passage to the initial blocking position is accompanied by an audible signal produced by the shock of bottom edges of the counterweights 56 against the surface of ramp 11, thus confirming that the axial locking is ensured between rotor 3 and head 2.

The rotor 3 is then mounted on the head drive 2 in drive position as shown in Figure 1. The rotor 3 and the drive head 2 are then coaxial.

After an idle stroke, the rotating coupling of the drive head 2 and the rotor 3 is ensured by the nipples 21 of the cap 17 and the nipples 67 of the head 2 which are supported on each other.

Axial locking of rotor 3 on the head drive 2 is provided, on the one hand, by support of the bearing surface 9 of the rotor 3 on the retaining surface 47 of the drive head 2 and, on the other hand, by the effect of the gravity applying to rotor 3 and by the force of axial support exerted by the springs 63 on the rotor 3 through the lower edges 66 of the weights 56 and the inclined ramp surface 11.

This axial blocking is sufficient to be able to start to drive the rotor 3 rotating safely.

When the head rotation speed 2 increases, the centrifugal force being exerted on the flyweights 56 cause them to pivot around the pegs 61 as described above.

So when the speed of rotation of the head 2 increases, the thrust surfaces 44 progressively advance radially outward projecting from the surface 49 of part 48. By cam effect, the weights 56 push the rotor 3 down by exerting a increasing axial holding force with rotation speed of the drive head 2.

Thus the axial holding force exerted by the weights 56 on the rotor 3 is adapted to the different rotational speeds of the drive head 2.

To remove the rotor 3 from the drive head 2, the user presses on the knob 32 so to fully retract it into bore 39 by compressing the spring 36. The tapered end 35 of the rod 30 penetrates simultaneously in the bore 55. The tails 58 of the counterweights 56 are supported on the lateral surface of the rod 30 which gradually spreads simultaneously radially towards outside the tails 58 of the flyweights 56, until these resume their axial release positions (figure 4).

The user can then remove the rotor 3 from the drive head 2 by lifting the latter, in particular by using the handle 31 of the actuating member 5.

The angle of convergence of the frustoconical surfaces 9 and 47 makes it possible to avoid the fitting of the rotor 3 on the head drive 2 and thus facilitates disassembly of the rotor 3, all the more so as the increasing holding force of the rotor 3 on the head 2 substantially compensates for the lifting force acting on the rotor 3 during its rotation.

More generally, the angle of convergence frustoconical surfaces 9 and 47 conjugate can be between 25 and 45 °.

The angle of divergence of the ramp surface 11 can be between 70 and 80 °.

The axial locking device of the centrifuge of figure 1 is completely arranged in the head 2 and thus has the advantage of allowing the use of a rotor 1 without its cover as illustrated by figure 4.

The centrifuge 1 of FIG. 5 is distinguished from that of FIG. 1 in that the cover 4 has been removed from the rotor 3 and in that the rod 30 and the handle 31 of the member actuation 5, came integrally with the body 28. The handle 31 is crossed by a transverse bar facilitating his seizure.

Assembly, rotation drive and blocking axial of the rotor 3 on the drive head 2 are similar to those described with reference to FIG. 1.

For the dismantling operation of the rotor 3 of the drive head 2, the user screws the body 28 of the operating member 5 in the bore 22 of the cap 17, thereby causing penetration of the tapered end 35 of the rod 30 in the bore 55 of the head 2, which causes, analogously to the case of FIG. 1, by thrust on the tails 58, the movement of the flyweights 56 towards their axial unlocking positions of the rotor 3 and the drive head 2.

The user can then disassemble the rotor 3 of the drive head 2, for example using the handle 31 of the actuating member 5 for lifting the rotor 3.

This feature simplifies the rotor 3 mounting / dismounting operations on the head 2, especially for users who want centrifuge sealed tubes at low speed.

In addition, the axial release operation is very simple and allows the user to have both hands free to extract the rotor 3 from the drive head 2.

Claims (10)

Centrifuge (1) of the type comprising a head (2) rotational drive integral with a rotation shaft (43), a rotor (3) which can be removably mounted on the drive head (2), in a position rotary drive, means (21, 67) rotational coupling of the drive head (3) and of the rotor (2), and a device for axially locking the rotor (3) on the drive head (2) comprising means (56) applying, on the rotor (3), a holding force axial of a bearing surface (9) of the rotor against a surface retainer (47) integral with the drive head, characterized in that the means (56) for applying a force holding are means of applying a force of increasing hold with the speed of rotation of the head training. Centrifuge according to claim 1, characterized in that the means of applying a force of hold include at least two flywheels (56) mounted symmetrically with respect to the axis of rotation (42) of the drive head (2), on a part end (48) of the drive head, each movable between an axial release position of the rotor and the head drive, in which the counterweight (56) is retracted in the drive head (2), and a locking position axial of the rotor (3) on the drive head (2) dependent the speed of rotation of the drive head (2), in which a thrust part (64) of the counterweight (54) protrudes from a radially surface outside (49) of the drive head (2) and cooperates with a ramp surface (11) of an opening (7) of receiving the end portion (48) of the head drive formed in the rotor (3), this surface of ramp (11) being inclined towards the inside of the opening (7) and towards the bearing surface (9) of the rotor. Centrifuge according to claim 2, characterized in that the ramp surface (11) is substantially tapered. Centrifuge according to claim 2 or 3, characterized in that at least one counterweight (56) is recalled elastically from its retracted position towards a initial axial locking position of the rotor (3) on the head drive (2). Centrifuge according to any one of the claims 2 to 4, characterized in that the weights (56) are rotatably mounted on the end portion (48) of the drive head (2) and each include an appendage maneuver (58) actuable simultaneously by a member outside (5), when the rotor (3) is in position drive, to bring the weights (56) back into their retracted axial release positions of the rotor (3) and the drive head (2). Centrifuge according to any one of the claims 2 to 5, characterized in that the bearing surface (9) of the rotor and the retaining surface (47) of the head are substantially frustoconical and conjugate, the retaining surface (47) forming a centering surface of the rotor (3) on the drive head (2). Centrifuge according to any one of the claims 2 to 6, characterized in that at least one counterweight (56) is a shock weight to cause a signal audible during axial locking of the rotor (3) on the head drive (2). Rotor for a centrifuge according to any one of claims 2 to 7, characterized in that it comprises an opening (7) for receiving at least part end (48) of a drive head (2) of a centrifuge (1), said opening having a surface (9) bearing against a retaining surface (47) integral with the drive head (2), and at least one ramp surface (11) intended to cooperate with a pushing part (64) a flyweight (56) of the drive head (2), this ramp surface (11) being inclined towards the inside of the opening (7) and towards the bearing surface (9). Rotor according to claim 8, characterized in that the ramp surface (11) is substantially frustoconical. Rotor according to claim 8 or 9, characterized in that the bearing surface (9) is substantially frustoconical.

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