DE3600090C2 - - Google Patents

Description

The invention relates to an analytical autoclave in Preamble of claim 1 specified genus and can be used to carry out the analytical material control in the metallurgical industry, in mechanical engineering, in the chemical Industry and geological exploration with complex chemical preparation (dissolution, separation and selective concentration of components) poorly soluble cher materials are used. Furthermore, the inventor for different types of heat and sterile Treatment of substances in medicine, food industry and Like. Find application.

From the work instruction "Autoclave-3", company Perkin-Elmer, 1977, an analytical autoclave is known, the housing contains with a lid in which a shut-off device is housed. There is a reaction in the housing socket with flare and its cover, made of fluoroplastic consist. The lid has a cylindrical part and one Flange with dovetail ring groove. The autoclave has for hermetically sealing the reaction socket a torus-like ring that fits into the ring groove of the Lid engages. You bring one into the reaction socket sample to be examined, add a corresponding one suitable solvent, closes the lid, sets the socket  into the autoclave housing and screw the lid on the shut-off device previously screwed in clockwise on the case. You screw the lid of the autoclave firmly until it stops and screws the shut-off device counterclockwise to the free state. The force from the shut-off device is applied to the cover the reaction socket. Here, the in the Toroidal ring located in the ring groove of the lid Flare the reaction bush pressed in, creating a herme table seal comes about. Then the autoclave placed on an electric heater, except for one Dissolution of the sample required temperature and at the specified temperature during one to complete time required to dissolve the sample. On the autoclave is then removed from the electric heater and cooled. The shut-off device turns clockwise screwed on, unscrewed the lid of the autoclave, the Reaction socket with the cover from the autoclave housing pulled out, the cover removed from the reaction socket and the obtained solution of the sample in the for implementation certain laboratory equipment for analysis.

The reaction bushing is sealed with a cover the toroidal ring along the horizontal axis of the Bör dels of the reaction socket limits the heating  temperature to 160 ° C, since the heat transfer from Electric heater and the autoclave housing to the investigative sample, located on the bottom of the reak tion socket is located over air gaps between the Floor, the walls of the reaction socket and the car slave housing and over the flange of the reaction socket (as the place of the best contact of the reaction socket with the autoclave housing) due to the thermal conductivity of the material of the reaction bushing. Heating temperatures of over 160 ° C lead to overheating of the Flaring the reaction bushing and its sealant, to destroy the seal and the occurrence of (on increasing the softness of fluoroplastic at the Temperature increase attributable) irreversible permanent deformations of the sealing surfaces of the flange the reaction socket, the cover and the torus-like Sealing ring and as a result of this to the impossibility of Reaction socket and cover to be used several times.

The limitation of the operating temperature of the autoclave limited to 160 ° C the circle of analysis objects, sets the determination of the content of foreign matter elements by increasing the sample weights and limits reduces the time of the resolution of analysis objects.

The loss of hermetic sealing at temperatures over 160 ° C under changing temperature conditions (Heating - cooling) and especially for reuse the reaction socket, the cover and the torus-like Ring because of the permanent deformation of their seal surfaces (which are due to the overheating of the hermeticization are to be attributed) leads to the loss of after assigning elements that change during the resolution form volatile compounds. Besides also affect penetrating into the reaction socket from the atmosphere Impurities negatively affect the analysis results.  

As a result, the flare of the reaction bushing during the work of the autoclave with the material of the Autoclave housing contacted and during overmolding the solution of the sample (after the resolution has been carried out) from the reaction socket into the laboratory equipment with which he solution is in contact, it occurs as a result of mentioned contacts for contaminating the solution of the Sample through the material of the autoclave, which additional Results in errors in the analysis results.

Since the cover is the reaction socket outside the autoclave housing is not sealed tightly and cannot be fixed, can fill the reaction sockets with the samples and Solvents to carry out a large series of parallel analyzes in companies of the multi-ton Pro production should not be carried out in advance, even if a sufficient number of reaction sockets with covers is available.

In the dovetail-shaped ring groove on the face of the cover flange remain traces of after the dissolution Reaction components back, their difficult removal contaminate the reaction space and the analysis results influenced by the content of foreign matter elements. The expansion necessary to clean the ring groove can be used for loading damage to the toroidal ring and the cover and consequently for the one-time use of the lid only Guide the reaction sleeve and the toroidal ring.

In addition, the construction of the reaction ensures bushing and the cover of the prototype no bushing the vapor-gas dissolution of samples to be examined, no coupling of the steps of the sample resolution with the distillation of the solvent by producing a Temperature gradient along the vertical axis of the autoclave,  no separation of the matrix element and the foreign matter elements and obtaining an analytical Concentrate of the latter. In addition, the known one allows Autoclave does not, the operations of dissolving and opening with the matrix element and the foreign substance elements the extraction of analytical concentrates from the latter for multiple samples instead of one in one reaction to connect the socket.

From the magazine Z. Anal. Chem. 260 (3), 1972, pp. 207-209 an analytical autoclave of the specified type is known, that of a housing with a lid, one a closing force generating shut-off device and from one by one Lockable reaction socket made of Teflon consists. The upper edge of the reaction socket is covered by a radially inner and a radially outer conical ring surface limited and engages in an annular groove of three square cross section under the pressure of the plastic cover axially acting closing forces of the shut-off device tion. One especially after repeated use reliable hermetic seal between the plastic cover and the reaction socket can also be used with this known autoclaves can not be ensured.

The object of the invention is a generic analyte to create a senautoclave with a reliable seal tion of the reaction socket even after repeated use is guaranteed and at which the dissolution temperature the samples can be increased to over 160 ° C.

This object is achieved by the characterizing Features of claim 1 solved.  

This execution of the reaction bushing and the formation of a Sealant to hermeticize the bushing her neck and the conical surface that are in contact with each other and stand with the end face of the cover flange, ge provide a reliable in the autoclave according to the invention Hermeticization along the vertical axis of the autoclave without using a seal, what by mutual Work in along the contact line of the neck and the cone area of the reaction socket with the end face of the cover flanges if the reaction socket is used several times and the lid happens. An essential condition the guaranteed function of the hermeticizing agent the presence of contact between the neck of the Reaction sleeve and the cylindrical part of the cover. In addition, the Reak tion socket with cover the temperature of the dissolution of samples to be examined above 160 ° C (up to 230 ° C) thanks to direct heat transfer from the heater to the floor of the autoclave housing directly on the entire surface the thin bottom of the reaction socket on which the sample to be examined is increased without overheating along the line of contact of the forehead surface of the cover flange and the neck and the cone surface surface of the socket along which the hermeticization comes happens.

The geometry of the shape of the reaction bushing according to the invention and the lid, which has no hard-to-wash pockets points, improves the conditions of preparation of the Reaction socket and the cover for subsequent analyzes of materials to be examined by adding a higher purity guaranteed and thereby the limits of the determination  allowed to reduce the content of admixtures. There a neck that can be fixed in the cover on the reaction socket and an extended cylindrical part of the lid is available are, which protrudes tightly into the reaction socket (which ensures a reliable fixation of the lid when Close the reaction socket outside of the divided Autoclave housing is ensured), the samples and components simultaneously in several reaction sockets be brought in advance, which is more rational planning the experimenter's working hours, and contact of the neck with the Material of the housing excludes what the avoidance contamination of the sample solution by the Material of the autoclave when pouring the solution out of the Reaction socket guaranteed in the laboratory devices.

The contact of the neck and the conical surface with each other and with the end face of the cover flange is through the coupling of the side surface of the neck of the reaction sleeve ensured with their conical surface, the neck so engages in the annular groove that the end face of the flange the side surface of the neck and the cone surface along the Coupling line of the latter touches. Such a contact offers the possibility of sealing (hermeticization) along the vertical axis of the autoclave without use a sealing insert due to the mutual Incorporation of the material of the reaction bushing and the To bring the lid material, the sealing surface reduce and thereby the force of the shut-off device, those for guaranteed hermeticization of the reaction socket through the lid is necessary to decrease.  

The contact of the neck with the cylindrical cover part is by the engagement of the cylindrical cover part in the reaction bushing by engaging the side surface of the cylindrical part reached at least on the neck. Thereby can deform the walls of the reaction socket, which the force of the shut-off device at Hermetisation in the interior of the reaction socket lengthways the circle of the seal, prevents and a reliable fixation of the lid when closing reached the reaction socket outside the autoclave housing will.  

The autoclave expediently contains an open container with holes forming in the socket Gaps between the walls and the bottom of the Socket and the container is arranged coaxially. A Heat exchanger is located mainly below the bottom of the reaction socket. This construction ge allows to investigate a vapor-gas dissolution of perform the samples and by generating a optional temperature gradient the operations of the on solution of the samples of an object to be analyzed, the Separation of the matrix element and the foreign substance elements and obtaining an analytical concentrate from Foreign matter on a fixed collector or in a mini paint volume to couple the solution.

To carry out the distillation of the solvent you can exchange the autoclave with another heat provided on the cover of the reaction socket is appropriate.

It is appropriate to use the cylindrical part of the lid execute with a cavity that has holes with the reaction socket is connected and a zylin has a head start in the reaction socket protrudes and with a flange having holes is provided with a trich with its narrow part ter is coaxially attached, and between the flange and a ring with holes in the wide part of the funnel to use, with all bores coaxial leads, and it is also expedient, one To provide heat exchangers, which essentially is arranged under the bottom of the reaction socket. This enables a directed flow of the vapors of the Solvent on the bottom of the reaction socket is heated, via the axial bore in the cylindrical Protrusion into the cavity and out of this via holes  on the in the holes of the ring and the flange used container to analyze the samples of to create the objects. This in turn ensures a selective dissolution of the components of the sample and in combination with the heat exchanger, the essentially under the bottom of the reaction socket is ordered, a separation of the matrix element and the Doping elements and the extraction of analytical Concentrates of foreign substances for several at the same time Samples in a reaction socket.

In the following the invention based on execution examples explained with reference to the drawing. It shows

Figure 1 shows the overall view of an analytical autoclave in longitudinal section.

Figure 2 is a Analysenautoklav with an open container in the reaction receptacle and with a heat exchanger in longitudinal section.

Figure 3 is a Analysenautoklav having mounted on the lid of the reaction female heat exchanger in longitudinal section.

Fig. 4 shows an analytical autoclave with a funnel in longitudinal section.

The analytical autoclave shown in Fig. 1 is intended for liquid phase dissolution of samples at heating temperatures up to 250 ° C.

The autoclave contains a cylindrical housing 1 with a cylindrical cover 2 , which is attached to the housing 1 by means of a thread 3 in the upper part. In the housing 1 there are a fluoroplastic reaction bushing 4 of cylindrical shape and its fluoroplastic cover 5 , which has a central cylindrical part 6 with a conical surface 7 pointing inside the bushing 4 and a flange 8 with an annular groove 9 . The socket 4 is placed with its base 10 on an insert 11 which is accommodated in the bore in the base 12 of the housing 1 and has a bore 13 .

The cover 2 fixes the reaction socket 4 and its cover 5 in the housing 1 and has an opening in which a profiled ring 14 can be fixed by means of a cross screw 15 . A transverse bore 16 serves to reduce the pressure in the autoclave in the event of a leak in the reaction bushing 4 .

The autoclave has a means 17 for the hermeticization of the reaction bushing 4 and contains in the cover 2 a shut-off device 18 for generating a reliable hermeticization of the reaction bushing 4 by the cover 5 , to compensate for the temperature-related changes in length of the housing 1 , the cover 2 and the reaction bushing 4 with the cover 5 to ensure reliable hermeticization at variable temperatures and to fulfill the function of a safety device (a valve) to reduce the pressure in the reaction bushing 4 that exceeds the normative. The device 18 is housed in the cover 2 and contains a movable T-shaped rod 19 with a thread 20 in the upper part, on which a clamping nut 21 is screwed on over the ring 14 . On the outside of the rod 19 , a package 22 disc springs 23 is arranged coaxially. The clamping nut 21 is for compressing the package 22 of the springs 23 be true, the force on the T-shaped rod 19 , which contacts the cover 5 of the socket 4 , the Hermeti guaranteed. On the cylindrical part of the rod 19 , a keyway 24 is incorporated into which a pin 25 fastened in the ring 14 protrudes, which prevents rotation of the rod 19 when the nut 21 is tightened and loosened. In the nut 21 bores 26 are made for inserting (not shown) fasteners. A disc 27 is arranged between the ring 14 and the nut 21 , which facilitates the tightening and loosening of the nut 21 .

A gap is left between the cylindrical part of the housing 1 and the lower end face of its cover 2 , which gap can be changed depending on the decrease in the height of the bushing 4 and its cover 5 , which allows the "path" of the packet 22 of springs 23 and consequently to reduce the height of the shut-off device 18 and the cover 2 .

The reaction bushing 4 has a neck 29 and a conical surface 30 which contact each other and with the end face 31 of the flange 8 of the cover 5 by forming a means 17 for hermetically sealing the bushing 4 through the cover 5 .

The geometry of the design of the socket 4 , the cover 5 and the hermetic means 17 makes it possible to vary the working volume of the socket 4 by changing the length of the cylindrical part 6 of the cover 5 , prevents the deformation of the walls 32 of the socket 4 , which the Force the shut-off device 18 during the measurement and ensure a fixation of the cover 5 when closing the socket 4 after the entry of reaction components outside the housing 1 of the autoclave in the preparation of samples to be examined for the operation of the autoclave solution.

The cylindrical part 6 of the cover 5 has a conical end face, which, however, can also be designed differently depending on the task to be solved. A gap 33 determines the distance by which the lid 5 when working with the end face 31 of Fansches 8 on the cone surface 30 of the reaction socket 4 can lower.

The autoclave works in the following way: one brings into the reaction socket 4 a a to be examined sample, the bushing 4 filled with an appropriate solvent, 4 closes the socket with the cover 5 and brings it by being supported with the movable insert 11, in Autoklavgehäuse 1 under. You turn the nut 21 on the cover 2 of the autoclave housing 1 clockwise and press the package 22 of the plate springs 23 together. The cover 2 is screwed onto the housing 1 of the autoclave with the previously compressed package 22 of the plate springs 23 of the shut-off device 18 as far as it will go. By holding the autoclave cover 2 (to avoid loosening it) and unscrewing the nut 21 by turning it counterclockwise until it is free, the package 22 of the plate springs 23 is released , which act on the cover 5 of the reaction socket 4 with considerable force . Here, along the contact line of the neck 29, the conical surface 30 is the socket 4 and the end face 31 of the flange 8 of the cover 5 due to their mutual Einar Beitens a hermetic sealing of the reaction socket 4 by the cover 5 instead. The autoclave is placed on an electric heater (not shown), heated to a temperature required to dissolve the sample to be analyzed and maintained at the predetermined temperature for a time required for the dissolution of the sample or for the selective dissolution of its components. You take the car klav from the electric heater and cool, whereupon you shut the locking device 18 by turning the nut 21 clockwise and unscrewed the lid 2 of the autoclave. With the help of the movable insert 11 is drawn, the reaction socket 4 with the lid 5 from the Autoklavgehäuse 1 out takes the lid 5 of the reaction bush 4, and subjecting the obtained solution in the socket 4 of the analysis to the sample to a Ana on the content of the Components and additives using a complex of chemical and physico-chemical analytical methodologies.

The analytical autoclave shown in Fig. 2 is for steam-gas dissolution of samples and for coupling the operations of dissolving samples, separating the matrix element and the foreign matter elements, obtaining an analytical concentrate of the foreign matter on a solid collector or in a minimal volume the solution determines and contains according to the invention in addition to the embodiment shown in Fig. 1, an open container 34 , the holes 35 and 36 for the entry of solvent vapors in the container 34 and in the socket 4 to form spaces 37 between the Socket 4 and the container 34 is arranged axially ko. The container 34 is intended for receiving samples to be examined. Moreover, ent, the autoclave holds a heat exchanger 38, which is substantially below the bottom 10 of the hub 4 for He generation of an optional temperature gradient along the axis of the reaction bush 4 arranged. The container 34 is designed in the form of a hollow cylinder with a bottom 39 and a flange 40 , with which it is supported on a projection 41 made on the inner surfaces of the walls 32 of the socket 4 . Before and the holes 35 and 36 in the container can be different depending on the task to be solved. The heat exchanger 38 ent holds a housing 42 with a channel 43 for a refrigerant and nozzle 44 for the supply of the refrigerant from a main line.

The analytical autoclave according to FIG. 2 works similarly to the autoclave shown in FIG. 1, with the exception that the sample is introduced into the container 34 , which is hung in the socket 4 on the projection 41 with its flange 40 . After heating the autoclave on an electric heater (not shown), the autoclave is placed on the heat exchanger 38 and held there for a period of time required to produce an optional temperature gradient. After the autoclave treatment of the sample to be examined has been completed, the container 34 is removed from the socket 4 and its contents are analyzed (concentrated solution of the sample or analytical concentrate of admixtures).

The embodiment shown in Fig. 3 is for the distillation of the solvent and for coupling the operations of dissolving the samples, for separating the matrix element and the foreign matter elements, for obtaining an analytical concentrate of the foreign matter in a solid collector or in a minimal volume Solution determined. According to the invention, the auto klav contains, in addition to the embodiment shown in FIG. 2, another heat exchanger 45 , which is mounted on the cover 5 of the reaction socket 4 and is accommodated within the T-shaped rod 19 of the shut-off device 18 . This heat exchanger 45 is for generating an additional localized cooling zone on the cover 5 of the socket 4 for the purpose of optionally changing temperatures both on the cover 5 of the socket 4 and (with the aid of the heat exchanger 38 arranged essentially under the base 10 of the socket 4 ) determined on the bottom 10 of the socket 4 . The heat exchanger 45 has a cavity 46 which communicates with a central axial tube 47 for introducing the refrigerant and with an annular channel 48 for discharging the refrigerant. In addition, the heat exchanger shear 45 contains a disk distributor 49 with holes 50 , which is placed in the cavity 46 to form gaps 51 . On the tube 47 and the ring channel 48 are coaxially arranged pipe sockets 52 and 53 for introducing or discharging the refrigerant into the heat exchanger 45 , which are fastened in the upper part of the T-shaped rod 19 with the aid of a nut 54 screwed onto the thread 20 . The pipe socket 52 and 53 be a seal 55 and socket 56th The accommodation of the heat exchanger 45 within the T-shaped rod 19 of the shut-off device 18 ensures an absolute and constant contact of the end face 57 of the heat exchanger 45 with the cover 5 of the socket 4 with a force required to hermetically seal the high pressure in the socket 4 is, and the fulfillment of the function of a safety device by the heat exchanger 45 in order to reduce the pressure exceeding the norm tiv in the socket 4th The cavity 46 with the disk distributor 49 is used for uniform distribution of the refrigerant flow over the entire ge surface of the cover 5 and for generating a minimum temperature at the tip of the cone surface 7 of the cylindrical part 6 of the cover 5 of the socket 4 , which tip of the car housing 1 to be warmed is farthest away.

The Analysenautoklav of Fig. 3 operates similar to the autoclave shown in Figs. 1 and 2, with the exception that the same exchangers 45 have with the positioning of the autoclave to an electric heater to heat from a refrigerant to produce a selective temperature gradient and supply for the distillation cleaning of the solvent in the socket 4 is supplied. The autoclave is heated to the boiling point of the solvent, the condensation of solvent vapors and the dripping of the solvent purified by distillation taking place in the container 34 on the conical surface 7 of the cylindrical part 6 of the cover 5 . The working time of the heat exchanger 45 is selected in such a way that a sufficient amount of the distilled solvent is collected in the container 34 to dissolve the sample to be examined. After this, the supply of the refrigerant to the heat exchanger 45 is switched off, the refrigerant is removed from the heat exchanger 45 completely and the car is warmed up to a temperature which is necessary to dissolve the sample to be examined. After the autoclave treatment of the sample has ended, the concentrate obtained or the solution of the sample is subjected to an analysis.

The analytical autoclave shown in FIG. 4 is intended for the dissolution and selective separation of the components of a sample and ensures the separation of the matrix element and the foreign matter elements as well as the extraction of analytical concentrates of the foreign matter simultaneously for several samples in a reaction bushing 4 . According to the invention, the analysis autoclave contains, in addition to the embodiment shown in FIG. 1, the heat exchanger 38 shown in FIGS . 2 and 3, which is arranged essentially under the bottom 10 of the socket 4 . The cylindrical part 6 of the lid 5 is out with a cavity 58 and with bores 59 leads. In addition, the cylindrical part 6 is provided with a cylindrical projection 60 which has in the reac tion socket 4 and has a flange 61 with holes 62 . A funnel 64 is fastened coaxially to the flange 61 with its narrow part 63 , and a ring 66 with bores 67 is inserted between the flange 61 and the wide part 65 of the funnel 64 . In the cylindrical part 6 of the cover 5 there is an axial bore 68 . The bores 59, 62 and 67 are designed as coaxial bores. The cylindrical projection 60 , the flange 61 , the ring 66 and the wide part 65 of the funnel 64 are in the reaction socket 4 with gaps 69 between the walls 32 and the bottom 10 of the reaction socket 4 . Such a construction offers the possibility of a directed stream of solvent vapors from the bottom 10 of the socket 4 via the axial bore 68 into the cavity 58 and via the holes 59 on the samples to be analyzed in containers 70 which are in the holes 62 of the flange 61st and are accommodated in the bores 67 of the ring 66 . In addition, the wide part 65 of the funnel 64 present in the autoclave, which is immersed in the solvent up to the bottom 10 of the socket 4, ensures that the pure solvent within the wide part 65 of the funnel 64 is separated from the reaction products which are found in the columns 69 collect between the walls 32 of the socket 4 and the wide part 65 . In addition, the narrow part 63 of the funnel 64 , which is fastened to the cylindrical projection 60 by means of a thread 71, fixes the ring 66 with the containers 70 previously placed in its bores 67 on the cover 5 of the bushing 4 .

The analytical autoclave according to FIG. 4 works similarly to the autoclave shown in FIG. 1, the samples being introduced into the containers 70 which are inserted into the bores 67 of the ring 66 . Thereafter, the ring 66 is fastened with the contents mentioned between the flange 61 of the cylindrical projection 60 of the cover 5 and the wide part 65 of the funnel 64 . To generate a temperature gradient, the heat exchanger 38 is used in an operating state which is similar to the operating state of the autoclave shown in FIGS. 2 and 3. After the autoclave treatment of the samples has ended, the concentrates obtained or the solutions of the samples are subjected to analysis.

Claims (4)

1. Analysis autoclave, consisting
from a cylindrical housing ( 1 ) with a screw cover ( 2 ),
a reaction bushing ( 4 ) made of fluoroplastic arranged in the housing ( 1 ), which has on its neck ( 29 ) a conical neck part ( 30 ) widening radially outwards towards its base,
from a in the housing ( 1 ) arranged lid made of fluorine plastic, which has a cylindrical annular groove ( 9 ) between its central part ( 6 ) and an outer ring flange ( 8 ), and
from a screw-in cover ( 2 ) arranged Absperrvor direction ( 18 ) which exerts an axial closing force on the plastic cover ( 5 ) and the neck ( 29 ) of the reaction bush in tight engagement in the annular groove ( 9 ) of the plastic cover ( 5 ), characterized,
that adjoins the conical neck part ( 30 ) radially inward into the cylindrical annular groove ( 9 ) of the plastic cover ( 5 ) engaging cylindrical neck part ( 29 ) which is tight on the cylindrical outer surface of the middle part ( 6 ) of the plastic cover ( 5 ) is present, and
that the flange ( 8 ) with its radially inner edge contacts the neck ( 29 ) at the transition between its conical neck part ( 30 ) and its cylindrical part under the action of the shut-off device ( 22 ). 2. Autoclave according to claim 1, characterized in that an open at the top with holes ( 35, 36 ) provided container ( 34 ) coaxially in the reaction bushing ( 4 ) with the formation of gaps ( 37 ) between the walls ( 32 ) and the bottom ( 10 ) the reaction bushing ( 4 ) and the container ( 34 ) is arranged, and that a heat exchanger ( 38 ) is arranged substantially under the bottom ( 10 ) of the reaction bushing ( 4 ). 3. Autoclave according to claim 2, characterized in that a second heat exchanger ( 45 ) on the plastic cover ( 5 ) of the reaction bushing ( 4 ) is attached. 4. Autoclave according to one of claims 1 to 3, characterized in that the cylindrical central part ( 6 ) of the plastic cover ( 5 ) contains a closed cavity ( 58 ) which has bores ( 59, 68 ) with the inside of the reaction socket ( 4th ) is connected, and has a tube extension ( 60 ) which projects into the reaction bushing ( 4 ) and is seen with a flange ( 61 ) and axial bores ( 62 ), on which a funnel ( 64 ) with its narrow part ( 63 ) is coaxially fastened that between the flange ( 61 ) and the wide part ( 65 ) of the funnel ( 64 ) a ring ( 66 ) with axial bores ( 67 ) is inserted, the bores ( 59, 62 and 67 ) being made coaxially.