EP0614327B1 - Electroacoustic transducer having a partition wall and a mask wall - Google Patents

Description

The invention relates to an electroacoustic transducer with a membrane that is designed to vibrate parallel to a transducer axis, and with a partition that is opposite the rear side of the membrane and runs essentially transversely to the transducer axis and in which they penetrate partition openings to form a connection between one between the membrane and the one side of the partition wall and a second space on the other side of the partition wall are provided, the partition openings surrounding a central passage in the partition belonging to the first space, and with a mask wall that adjoins one of the two Sides of the partition is arranged adjacent and in which they penetrate mask wall openings are provided to form a connection between the two rooms and by means of an acoustically sealed connection which is closed in the circumferential direction and which is radial from the transducer axis Directions outside the partition openings and the mask wall openings is mechanically fixed to the partition, at least one of the openings in one of the two walls has a small cross-sectional area of at most 0.2 mm ² and one of the provided in the other wall has a larger cross-sectional area and is covered with at least one of the openings having a small cross-sectional area in the one wall to form at least one connection with a small acoustically effective cross-sectional area between the two spaces in the direction of the transducer axis.

Such an electroacoustic transducer known to the applicant according to the genus mentioned in the first paragraph above, the result is a development of a new electroacoustic carried out by the applicant Converters result and is in the pending European patent applications EP-A-0 615 398 and EP-A-0 616 483, both with priority date February 26, 1993.

In the converter known to the applicant, the partition and the mask wall with one lying in a peripheral region of the mask wall Adhesive connection mechanically tight and acoustically tightly connected. The Adhesive connection is only very thin, so that the two meet adjacent walls, i.e. the partition wall and the mask wall of the converter, touch each other practically immediately. The mask wall is through one Flange of a pot of a transducer magnet system is formed, which pot the through the central passage in the partition, the first room of the Transducer in the area of the rear of the converter is completely sealed, so that the partially between the membrane and one side of the partition wall Room and the second room of the known on the other side of the partition Transducer only through the acoustically effective, through the overlapping openings in the partition and the mask wall connections are connected to each other, otherwise they are completely acoustically separated. Here, the two form Rooms each have an acoustic condenser and each is formed by two overlapping ones Openings in the two walls formed an acoustically effective connection acoustic inductance and an acoustic one in series with this inductance Resistance, with each connection opening with the smaller one Cross-sectional area of the essential, the size of the inductance and the size of the Series-determining part of the connection is. The size of the series resistor is due to the cross-sectional area and also in the direction of Transducer axis length of an opening with the smaller cross-sectional area certainly. However, the length of such an opening is relative for reasons of manufacturability limited, so that overall only a relatively small resistance value of such acoustic series resistance is obtained. The two rooms in combination with the acoustically effective connections between the two rooms form two so-called Helmholtz resonators, their resonance behavior and thus their Exaggerated resonance through the capacitance values of those formed by the rooms acoustic capacitors and by the inductance values and the resistance values the acoustic inductances formed by the connections and to the latter in Series lying resistors are determined. In what is known to the applicant Converter has now been shown that as a result of the openings with a small Cross-sectional area achievable only relatively small resistance values of the acoustic Series resistors which have a relatively high quality and the Helmholtz resonators therefore the resonators are only slightly damped, so that their resonance peaks are relative are pronounced, which leads to a wavy frequency response of the converter.

The invention has for its object the above Eliminate difficulties and an electroacoustic transducer in the beginning to effectively improve the genus mentioned in the first paragraph with simple means, to get a converter with a smooth frequency response. For this is the Transducers according to the invention, characterized in that each has a small one Cross-sectional area in one of the two walls between two provided between the two walls, from the central one Passage in the partition essentially each having the same distance Spacer lies and that two spacers together with the two walls one between the two walls define a channel-like gap that leads to the central one Passage in the partition leads and forms an acoustic resistance. By these measures according to the invention are particularly easy for everyone Small cross-sectional area opening, a so-called acoustic bypass resistance realized parallel to that through an opening with a small cross-sectional area formed acoustic impedance is effective so that in the area of each opening With a small cross-sectional area, an overall smaller acoustic impedance is obtained. However, this advantageously results in a reduced quality and therefore a stronger one Attenuation of the Helmholtz resonators formed with the help of the two rooms of the converter achieved what is reflected in a good smooth frequency response of the converter precipitates. It should be mentioned as particularly advantageous that at one transducers according to the invention each acoustically effective channel-like gap of the two spacers between the two walls and the two walls all around is limited and a relatively precisely defined length up to the passage in the Partition has what with regard to a particularly precise definition of Resistance value of the acoustic bypass resistance determined by such a gap is advantageous.

It can be mentioned that it is known, for example, from US-A-4,027,116 is known in a converter with a partition provided with openings and with an adjacent to this partition, also provided with openings Mask wall to arrange the two walls at a distance from each other and in the an acoustic damping device in between the two walls Form of a felt ring to provide additional acoustic resistance in the Area of each connection formed by two overlapping openings between two rooms separated from each other by the partition and the mask wall Converter forms. Such additional acoustic resistances formed with felt material but are difficult to control in terms of the size of their resistance value because this size is relatively dependent on the composition, the density and the Fiber texture of the felt material, the moisture of the felt material and is the ambient temperature of the felt material. In contrast, is the resistance value one formed according to the invention by a channel-like gap additional acoustic by-pass resistance, the gap height by exactly measurable spacers and its gap length is also precisely determined in its Size can be determined very precisely because its size can be precisely controlled Gap dimensions is set.

The spacers can protrude radially inwards Spacer flags one that can be inserted between the partition and the mask wall separate spacer ring. However, it has proven to be particularly advantageous if each spacer is integrally formed with one of the two walls is. This is advantageous in terms of a structurally particularly simple design.

It has proven to be particularly advantageous if each spacer part in Direction of the transducer axis has a height between 20 microns and 50 microns. At Studies have shown that such training is particularly good Results are achieved.

It has also proven to be very advantageous if using the openings different cross-sectional areas each opening with a smaller one Cross-sectional area has a circular cross-section and the diameter of each such opening with a circular cross section in its acoustically effective Cross-sectional area is less than 0.3 mm. Such openings or holes with small Diameters are very accurate in compliance with specified dimensions very small tolerances can be produced, so that with such openings precisely defined by the ratio of the acoustically effective cross-sectional area and the length of the opening certain acoustic inductance values and resistance values and thus exactly defined influences of the connections formed with the help of the openings between the both rooms of the transducer can be achieved on the acoustic behavior of the transducer.

It has proven particularly advantageous if the diameter of each such opening with a circular cross section in its acoustically effective Cross-sectional area is equal to 0.2 mm. Research has shown that with such training particularly good results can be achieved.

Furthermore, it has proven to be particularly advantageous if each such Opening with a circular cross section in its axial direction a conical Training. This is in view of a precisely defined definition of the acoustically effective cross-sectional area of such an opening advantageous to the Area of the smallest diameter of the opening is concentrated. Furthermore, this is in the With regard to the good manufacturability of such an opening in a plastic part advantageous, because of the easy demoldability.

The invention is described below with reference to one in the drawings illustrated embodiment described in detail, but not to the invention should be limited. FIG. 1 shows a cross section along the line I-I in FIG. 2 on a larger scale than the natural size, in a somewhat more schematic way An electrodynamic converter according to an embodiment of the invention, which is designed as a hearing or speaking capsule for telephony applications and has a partition with openings and a mask wall with openings, between them, acoustic bypass resistors formed with the help of spacers forming channel-like column are provided. 2 shows in one Section along the line II-II in Fig. 1, the converter according to Fig. 1. Fig. 3 shows in a cross section on a larger scale than FIG. 1 a detail of the Converter according to Figures 1 and 2, the conical in its partition Partition openings.

1 and 2 show an electrodynamic converter 1, which is designed as a hearing or speaking capsule. The converter 1 has an im essentially circular or hollow cylindrical holding device 2. The holding device 2 has an annular outer wall 3, which in its one Front of the transducer 1 facing area is provided with a gradation 4. The step 4 forms a holding zone on which a membrane 5 of the transducer 1 is attached an adhesive connection is attached. The membrane 5 has a central region 6 which is often referred to as the cathedral. Furthermore, the membrane 5 has one peripheral edge region 7, in which hyperbolic beads are provided, which is not recognizable in Fig. 1. With the free end 8 of the edge region 7 the membrane 5 is attached to the step 4 of the holding device 2 by gluing. The Diaphragm 5 can oscillate back and forth parallel to a transducer axis 9 trained and emits audible on the membrane front 10 in operation Useful vibrations.

In the transition area 11 between the middle area 6 and the The edge region 7 of the membrane 5 is a voice coil 12 by means of the membrane 5 an adhesive bond connected. The voice coil 12 projects here with its from the Area 14 facing away from membrane rear side 13 into an air gap 15 of a Magnet system 16 of the transducer 1. The magnet system 16 has a magnet 17 and a pole plate 18 and a pot 19, often referred to as an outer pot becomes. Between the peripheral boundary surface 20 of the pole plate 18 and the End region 21 of the hollow cylindrical pot part 22 which through the bottom part 23 of the Pot 19 is completed, the air gap 15, in which the area 14 of the Voice coil 12 is located.

In the present transducer 1, the holding device 2 has an essentially circular partition 24 which projects inwards from the outer wall 3 in radial directions, which in this case is opposite the diaphragm rear side 13 of the diaphragm 5 and extends transversely to the transducer axis 9. The dividing wall 24 is provided with four dividing wall openings 25, 26, 27 and 28, which are arranged at 90 ° to each other and are at an angle to each other and penetrate the dividing wall 24, essentially having a slit-shaped and relatively large cross-sectional area. Furthermore, the partition wall 24 is arranged with four angularly offset from one another by 90 ° and 45 ° from the slot-shaped partition wall openings 25, 26, 27 and 28, likewise penetrating the partition wall 24, a circular and relatively small cross-sectional area of approximately 0.1 mm ² having partition openings 29,30, 31 and 32. The partition openings 25, 26, 27, 28 and 29, 30, 31, 32 are used to form acoustically effective connections between a first space 34 located between the membrane 5 and one side 33 of the partition 24 and one on the other side 35 the partition 24 is provided second space 36. In the case of the electrodynamic converter 1 embodied as a capsule according to FIGS. 1 and 2, the second space 36 is closed off in the region of the rear side of the converter 1, which will be discussed below. For example, the slot-shaped partition openings 25, 26, 27 and 28 can have a length of approximately 6 mm. It has proven to be advantageous if the circular partition openings 29, 30, 31 and 32 with a smaller cross-sectional area have a diameter of less than 0.3 mm and preferably of 0.2 mm. However, the circular partition openings can also have a diameter of, for example, only 50 or 40 μm. In the present converter 1 according to FIGS. 1 and 2, the circular partition openings 29, 30, 31 and 32 have a conical design in their axial direction, as can be seen in FIG. 3 for the partition opening 30. The annular partition wall 24 surrounds a central passage 37 provided in it, which belongs to the first space 34.

The converter 1 also has one on the side 35 of the partition 24 adjacently arranged and in this case with means described below in mask wall 38 held at a small distance from the partition wall 24. The Mask wall 38 is arranged with four, each offset by 90 ° to each other Mask wall 38 penetrating, a slit-shaped and relatively large Cross-sectional area having mask wall openings 39, 40, 41 and 42, to form the acoustically effective connections between the two rooms 34 and 36 are provided. For example, the slit-shaped Mask wall openings 39, 40, 41 and 42 have a length of approximately 5 mm and a width of about 2.2 mm.

To achieve acoustically effective different sizes Cross-sectional areas of the acoustically effective connections between the two Rooms 34 and 36 by covering in the direction of the transducer axis 9 bringable wall openings 25,26,27,28 and 29,30,31,32 and 39,40,41,42 in the partition 24 and are formed in the mask wall 38, the partition 24 and the mask wall 38 is rotated in two with respect to the transducer axis 9 Relative positions can be brought and held in it. With the converter designed as a capsule 1 according to FIGS. 1 and 2, the partition wall 24 and the mask wall 38 are in one brought such relative position to each other and recorded in that the circular partition openings 29,30,31 and 32 with a small cross-sectional area with the slit-shaped mask wall openings 39, 40, 41 and 42 with a cover a larger cross-sectional area. This way is in the range of each two overlapping openings a small acoustically effective cross-sectional area the respective connection between the two rooms 34 and 36 achieved by the cross-sectional area of the circular partition openings 29, 30, 31 and 32 exactly is defined and for the implementation of a transducer designed as a capsule and the frequency characteristic required for such a capsule is required.

As can be seen from FIGS. 1 and 2, the converter 1 has the Pot 19 of the magnet system 16 has a flange 38 running transversely to the transducer axis 9 with which the pot 19 for fastening the entire magnet system 16 to the Partition 24 is glued, along a circumferential direction in itself closed, essentially circular, in the outer region of the flange 38 located adhesive connection 43, the inner boundary 44 in Fig. 2 with a dash-dotted line is indicated schematically. Such an adhesive connection 43 in practice, of course, has a limitation 44 which is not exactly such has a circular course. The one with its flange 38 on the adhesive connection 43 the partition 24 attached pot 19 also serves in the converter 1 also for the acoustic completion of the over the central passage 37 in the Partition 24 of the first space 34 of the converter 1.

The flange 38 of the pot 19 of the magnet system 16 not only forms a fastening part for fastening the magnet system 16 to the holding device 2, but also in a particularly simple and very advantageous manner Mask wall 38 of the converter 1. In this way it is achieved that the mask wall 38 of the converter 1 not by a separate component, but by a component an existing component of the converter 1, namely through the flange 38 of the Pot 19 of the magnet system 16 of the transducer 1 is formed. This is regarding lower component costs and especially with regard to as few as possible Assembly steps and the lowest possible assembly costs are an advantage. As small as possible Assembly steps and assembly costs are such in mass production electrodynamic converter 1 of great importance because it makes it easier built assembly line the Auslangen is found. Also be considered by the as Flange of the pot formed mask wall no additional tolerance influences causes what in terms of good reproducibility of acoustic behavior of the converter 1 is advantageous.

As already mentioned above, it is used as a hearing or speaking capsule for telecommunication applications, especially telephony applications, trained transducer 1 according to Figures 1 and 2, the second room 36 on the other side 35 of the partition 24 is completed. To complete the In the second room 36 there is a closing part 45 which is plate-shaped is trained. The end part 45 is provided with an opening 46 which in present case has a circular cross section and with which the End part 45 with an acoustically tight fit on the outer peripheral surface 47 of the Pot 19 of the magnet system 16 is placed. The end part 45 has a Breakthrough 46 surrounding edge area 48 with which the end portion 45 with the Outer wall 3 of the holding device 2 is acoustically sealed and mechanically firmly connected. The holding device 2 or its outer wall 3 thus forms in the present case Transducer 1 a room boundary part for delimiting the second room 36. Die Holding device 2 and the end part 45 consist of the same Plastic material and are mechanically strong thanks to an ultrasonic welding connection connected with each other. In the area of the opening 46, the end part 45 is open particularly simple way only by means of a mechanical press fit with the pot 19 of the Magnet system 16 connected to its outer peripheral surface 47.

In the converter 1 according to the invention, the partition 24 and the mask wall 38 is also in a different position relative to one another than this is shown in Figures 1 and 2. In the converter 1 according to FIGS. 1 and 2 can the partition 24 and the mask wall 38, that is, the flange 38 of the pot 19th of the magnet system 16 are in a position relative to one another in which the slot-shaped partition openings 25, 26, 27 and 28 with the slot-shaped Cover mask wall openings 39, 40, 41 and 42. This way is in the area a large acoustically effective of two overlapping openings Cross-sectional area of the respective acoustically effective connection between the two Spaces 34 and 36 achieved by the cross-sectional area of the mask wall openings 39, 40, 41 and 42 is precisely defined and which for the realization of an as Speakers trained transducer and for such a speaker desired frequency characteristic is required. With such a training Transducer 1 as a speaker, however, the second room 36 is then open, which is achieved by omitting the end part 45.

The converter 1 according to the invention according to FIGS. 1 and 2 is open achieved in a particularly simple manner that the end part 45 of the transducer 1 with respect the transducer axis 9 within the axial level range of the magnet system 16 of the Transducer 1 is, so in the direction of the converter axis 9 no additional space takes up. In this way, the converter has a particularly low overall height 1 in the direction of its transducer axis 9, so that such a transducer 1 Also suitable for installation in particularly flat telecommunications devices.

In the converter 1 according to the invention according to FIGS. 1, 2 and 3 is - seen in the direction of the transducer axis 9 - each a small cross-sectional area having partition opening 29,30,31,32 in the partition 24 between two provided between the partition 24 and the mask wall 38, from the central Passage 37 in the partition 24 is essentially the same distance apart Spacers 49.50 or 51.52 or 53.54 or 55.56, which the partition 24 and keep the mask wall 38 a short distance apart. Two spacers each 49.50 or 51.52 or 53.54 or 55.56 limit one between the partition 24 and the mask wall 38 lying around, limited to the passage 37 in the partition wall 24 leading, forming an acoustic resistance channel-like gap 57,58,59, 60. Each of the spacers 49,50,51,52,53,54,55,56 is with the Partition 24 formed in one piece. The spacers are used in the manufacture of the Holding device 2, of which the partition 24 forms an integral part get simple and practical without additional measures, namely in the to manufacture the holding device 2 injection molding process. Everyone who Spacers 49 to 56 have in the present converter 1 according to FIGS. 1 to 3 in the direction of the transducer axis 9 to a height of about 50 microns. It should be mentioned that in Fig. 3, the height of the spacer 58 is shown larger than in relation to the other illustrated parts correspond to its actual natural size to the To increase the clarity of the drawing. In plan view of the spacers 49 to 56 in In the direction of the converter axis 9, the spacer parts 49 to 56 have a rectangular shape Cross section on. As can be seen from Fig. 2, the spacers 49 to 56 are each in Area of one end of a slit-shaped mask wall opening 39,40,41,42 what it is advantageous in this way that the spacers 49 to 56 additionally Form barriers for the adhesive with which the mask wall 38 with the partition wall 24 is mechanically and acoustically tightly connected along the adhesive connection 43.

By providing the spacers 49 that belong together in pairs, 50 or 51, 52 or 53, 54 or 55, 56, with a top view of the converter 1 in Direction of the converter axis 9 between each pair of spacers 49 to 56 one Partition opening 29, 30, 31, 32 with a small cross-sectional area is on achieved in a particularly simple manner that each has a small cross-sectional area having opening 29, 30, 31, 32 a so-called acoustic bypass resistance is realized, namely by the respective of two spacer parts 49, 50 and 51, 52 or 53, 54 or 55, 56 and the partition 24 and the mask wall 38 delimited channel-like gap 57, 58, 59, 60, which is in addition and parallel to that through an opening 29, 30, 31, 32 effective acoustic impedance formed with a small cross-sectional area is, so that in the region of each opening 29, 30, 31, 32 with a small cross-sectional area overall smaller acoustic impedance is preserved. This will, however advantageously a reduced quality and therefore a stronger damping of the With the help of the two rooms 34 and 36 of the transducer 1 formed Helmholtz resonators obtained, whereby a good smooth frequency response of the converter 1 is achieved. As It is particularly advantageous to mention that the realization of the acoustic Bypass resistors effective channel-like column 57, 58, 59, 60 on particular simple manner by utilizing the walls 24 arranged adjacent to each other and 38 and is only solved by additional provision of the spacers 49 to 56. Furthermore, it should be mentioned as particularly advantageous that in the converter 1 everyone acoustically effective channel-like gap 57, 58, 59, 60 of two each between the two Spacers 49, 50 and 51, 52 and 53, 54 and 55, 56 and the two walls 24 and 38 all around in a particularly precise manner is and a relatively precisely defined length up to the central passage 37 in the Partition 24 has what with regard to a particularly precise definition of Resistance value of the gap 57, 58, 59, 60 through such a channel certain acoustic bypass resistance is advantageous.

In a converter according to the embodiment described above can each have a spacer and an opening with a small cross-sectional area be provided several times alternately in succession. The spacers 49 to 56 can in plan view in Direction of the converter axis 9 also deviates from a rectangular shape Have cross-sectional shape and, for example, trapezoidal, triangular, oval-shaped or be designed differently. The height of the spacers 49 to 56 can also be have a value other than 50 μm in the direction of the converter axis 9, for example, the spacers 49 to 56 can also be only 20 µm, but also 100 µm be highly trained. With such a converter 1, more than four pairs can also be used of spacers may be provided, also between each pair of spacers a partition opening with a small cross-sectional area is provided. In such a converter 1, the spacers 49 to 56 can also be up to the Reach passage 37 in the partition 24.

The invention is based on the transducer as described above Embodiment not limited. For example, it can be used as a mask wall provided flange of the pot as in the converter described provided core pot magnet system also on the side facing the membrane abut a partition of such a holding device. Another can also Magnet system as a pot core magnet system in a transducer according to the invention are used, for example a toroidal magnet system. Can too for example, in the partition more than two different types of Partition openings can be provided, for example, with more than one type of Mask wall openings in a mask wall formed by a flange in different relative positions of the partition and the mask wall to each other to cover are feasible. Also, instead of only one area in a partition Partition opening with a circular cross-section with a small diameter to provide two or more such openings with a circular cross section even smaller diameters may be provided, each between two Spacers. Such openings can also be circular Cross-section in the axial direction instead of a conical design also a have cylindrical shape. They can also be used to form one acoustic Effective connection provided openings with a smaller cross-sectional area in a mask wall of a converter and the openings with these in the mask wall coverable, also to form an acoustically effective Connection provided openings with a larger cross-sectional area in a partition wall a transducer can be provided with the help of spacers at a short distance is held by the mask wall. The measures according to the invention are also at applicable to a converter in which the partition and the mask wall only in one Relative to each other brought and held in it.

Claims (6)

1. An electroacoustic transducer (1) having a diaphragm (5) constructed to be capable of vibration parallel to a transducer axis (9), which transducer has a partition wall (24) facing the back (13) of the diaphragm, which partition wall substantially extends transversely to the transducer axis (9) and is traversed by partition openings (25, 26, 27, 28, 29, 30, 31, 32) to form a passage between a first space (34) situated between the diaphragm (5) and one side (33) of the partition wall (24) and a second space (36) situated at the other side (35) of the partition wall (36), the partition wall openings surrounding a central passage (37) in the partition wall (24), which central passage belongs to the first space (34), and has a mask wall (38) arranged adjacent one of the two sides (33, 35) of the partition wall (24) and traversed by mask-wall openings (39, 40, 41, 42) to form a passage between the two spaces (34, 36), which mask wall is connected in a mechanically rigid manner to the partition wall (24) by means of a circumferentially closed acoustically sealed joint (43) which, viewed from the transducer axis (9), is situated radially beyond the partition openings (25, 26, 27, 28, 29, 30, 31, 32) and the mask openings (39, 40, 41, 42), at least one of the openings (29, 30, 31, 32) in one (24) of the two walls (24, 28) having a small cross-sectional area of at the most 0.2 mm² and one of the openings (39, 40, 41, 42) in the other wall (38) having a larger cross-sectional area and being coincident with at least one of the openings (29, 30, 31, 32) of small cross-sectional area in the one wall (24) to form at least one passage having a small acoustically active cross-sectional area between the two spaces (34, 36) in the direction of the transducer axis (9), characterized in that each opening (29, 30, 31, 32) of small cross-sectional area in one of the two walls (24, 38) is situated between two spacer elements (49, 50, 51, 52, 53, 54, 55, 56) arranged between the two walls (24, 38) and having substantially the same distance from the central passage (37) in the partition wall (24), and each time two spacer elements (49, 50; 51, 52; 52,53; 54, 55) together with the two walls (24, 38) bound a duct-like gap (57, 58, 59, 60) situated between the two walls (24, 38) and leading to the central passage (37) in the partition wall (24) to form an acoustic resistance.
2. A transducer (1) as claimed in Claim 1, characterized in that each spacer element (49, 50, 51, 52, 53, 54, 55, 56) is integral with one (24) of the two walls (24, 38).
3. A transducer (1) as claimed in Claim 1 or 2, characterized in that each spacer element (49, 50, 51, 52, 53, 54, 55, 56) has a height of between 20 µm and 50 µm in the direction of the transducer axis (9).
4. A transducer (1) as claimed in Claim 1, 2 or 3, characterized in that each opening (29, 30, 31, 32) having a small cross-sectional area is of circular cross-section, and the diameter of each such opening (29, 30, 31, 32) of circular cross-section is smaller than 0.3 mm in its acoustically active cross-sectional area.
5. A transducer (1) as claimed in Claim 4, characterized in that the diameter of each such opening (29, 30, 31, 32) of circular cross-section is 0.2 mm in its acoustically active cross-sectional area.
6. A transducer (1) as claimed in Claim 4 or 5, characterized in that each such opening (29, 30, 31, 32) of circular cross-section has a conical shape in its axial direction.

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