FI57672B - FARING EQUIPMENT FOR APPLIANCE ELECTRIC CABLE WITH MASS - Google Patents

Description

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Patent- och reglsteratyreiaen '' Aiuöktn utitgd och uti. * KrifMn pubiicured 30.05-80 (32) (33) (31) Pyy * 1 · 11 / «Tuoikuui - B« ftrd prlorltet 21.06.71 USA (US) 155055 (71) Western Electric Company, Incorporated, 195 Broadway, New York,, New York 10007, USA (72) Edward L. Franke, Jr., Baltimore, Maryland, William J. Hyde, Baltimore,

Maryland, Randy G. Schneider, Lambertville, New Jersey, USA (7 ^) Berggren Oy Ah (5 ^ +) Method and apparatus for filling stranded electric cable with mass - Förfarande och apparat för fyllning av en tvinnad elektrisk kabel med ms ss e .

The present invention relates to a method and apparatus for manufacturing a stranded electric cable according to the preamble of claim 1, and more particularly to a method and apparatus for filling the intermediate cores of a cable with a waterproofing mixture and further adding a core wrapper, shield and sheath to the cable core together with a waterproofing agent. a substantially waterproof cable is formed.

In the manufacture of certain types of communication cables, such as those intended for use in underground ducts or as direct excavated telephone connections, private bare conductors are extruded with an insulating material and each insulated conductor is then twisted with another insulated conductor to form a twisted pair. Several twisted pairs of insulated conductors are then twisted together to form a Cable Core. Colored binding tapes are helically wound around the cable core as marker tapes for coding. A thermal barrier tape, called a core wrap, and a metal shield are then wrapped around the cable core and a sheath layer of plastic insulation is pressed over the shield.

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Because this type of cable is intended to be installed underground or excavated in the ground, diffusion of moisture into the inner parts of the cable core is likely, resulting in corrosion and damage to the conductors and a change in capacitance. In addition, moisture in the cable core can result in inefficient and in some cases completely inhibited operation of the telephone lines formed from the conductors. It is also possible that the sheath and shield may break due to external forces, such as movements of boulders in an excavated application or accidental impact on those parts of the cable above ground level, which immediately exposes the cable core to moisture. Therefore, it is highly desirable and necessary to protect the insulated conductors of the cable core by minimizing the ingress of moisture into the cable core.

One technique currently used to provide protection is to use an adhesive-coated metal strip that is wrapped lengthwise around the heart wrap. When a sheath of hot plastic material is extruded onto a metal adhesive coating, the metal becomes bonded to the inner wall of the sheath, thus forming a bonded shield over the cable core. This bonded shield provides a moisture barrier with properties that reduce the ingress of corrosive and damaging moisture to the cable core. In addition, the core of the cable can then be pressurized, which also tends to reduce the possibility of moisture penetrating the core.

Other methods used to minimize the ingress of moisture into the core of the cable include filling the on-rolls of the intermediate structure of the core of the cable with a mixture having properties sufficient to minimize the ingress of moisture into the core. It would be most desirable if the mixture could be placed in all the air spaces and cavities in the core of the cable that form the intermediate space structure of the core.

Because the twisted pairs of the cable core are stranded, it is difficult to ensure that all the cavities of the intermediate structure are filled with the mixture, especially those cavities located in the axial central portions of the core.

In addition, the mixture, i.e., the composition of matter used to fill the cavities of the core structure of the cable, hopefully and substantially replaces all the air in the core of the cable. Therefore, the mixture must have excellent electrical properties so that the cable filled with the mixture retains transmission properties that are at least as good as those of acceptable and tested cables with an inflatable core and other methods of moisture resistance. to combat. In addition, the mixture should have excellent resistance to runoff (runoff) at certain air temperatures due to the fact that parts of the cable must be brought above ground for termination purposes. In addition, the mixture should have the low temperature properties such as adhesion and fracture toughness required when handling the cable in a cold environment. Also, the mixture should not have any toxic effects that would make the handling of the mixture detrimental to installation personnel who may come into close contact with the mixture.

"Examining the different types of filler mixtures that could be used for waterproofing in telephone underground cables, it was found that a mixture of petroleum jelly and low density polyethylene in a precise blend ratio satisfies the above requirements. therefore significantly increased the cost of the product and sought to raise concerns as to whether it was economically reasonable to use a precisely blended copper-line-polyethylene blend as a waterproofing blend in telephone landline cables.

The method according to the invention is characterized in that a) the drained parts of the stranded electric cable are first cooled in the first cooling device before being passed through the filling device so that the filling masses sucked into the vacuum chamber from the filling device wherein the portion of the filler mass in contact with the stranded electrical cable is absorbed into the emptied spaces of the cable, and c) the mass-filled cable is passed through another cooling device to gel the filler so that the filler adheres to the cable spacers without further attachment.

According to a preferred embodiment, the drained parts of the cable are heated before being cooled in the first cooling device so that the parts of the filling mass sucked into the vacuum chamber from the filling device after passing through the first cooling device become fluid and drained.

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Accordingly, the apparatus according to the invention is characterized in that it comprises the following parts a) a vacuum chamber for removing air from successive parts of successive parts of stranded electric cable, b) a first cooling device for cooling successive drained parts of electric cable before entering the filling device, c) device for filling stranded electric cable e) a device for conducting poorly flowing filling mass in specified amounts to the filling device, f) a second cooling device for securing the filled mass, and g) a device for drawing the mass-filled cable through the second cooling device.

Other features and advantages of the invention will become apparent from the following detailed description taken in conjunction with the accompanying drawings.

Fig. 1 is a perspective view showing a part of the communication cable.

Figure 2 is a cross-sectional view of a communication cable showing the waterproofing composition disposed in the structural cavities of the cable core as well as other parts of the cable.

Figure 3 is a side view of an apparatus incorporating certain principles of the invention for injecting (injecting) a waterproofing composition into a cable core.

Fig. 4 is a cross-sectional view showing a shrinkage portion intended to facilitate the passage of the cable core through a substantially airtight duct.

Fig. 5 is a sectional view illustrating a vacuum portion for generating a vacuum in the structural cavities of the cable core.

Fig. 6 is a sectional view showing an insulated shrinkage portion.

Fig. 7 is a sectional view showing a cooling section for cooling a cable core passing therethrough.

Fig. 8 is a sectional view showing a mixture addition section in which the waterproofing mixture is added to a cable core passing therethrough.

Figure 9 is a perspective view of the mixture mixing zone and 5,57672 of the mixture addition apparatus illustrated in Figure 3.

Fig. 10 is a sectional view showing a removable cooling section.

Fig. 11 is a sectional view showing the removable cooling portion of Fig. 10 assembled with the shrink portion.

Figure 1 illustrates a portion of a communication cable 21. The cable 21 includes a cable core 22 consisting of a plurality of twisted, insulated conductors 23-23 forming a plurality of twisted pairs. A plurality of colored tie strips 24-24 are wrapped around the stranded conductors 23-23 to form color code information on certain aspects of the cable core 22. The core wrap 26, which is a plastic, heat-sealing and dielectric strip, is longitudinally wrapped around the cable core 22. The corrugated aluminum shield tape 27 is longitudinally wrapped around the core sheath 26 and forms a lightning shield (surge protector) on the cable core 22. The insulating sheath 29 is extruded over the corrugated tape to form a finished cable 21.

As shown in Fig. 2, the insulated conductors 23-23 are arranged in such a way that air cavities are normally formed in the structural intermediate spaces 31 to 31 of the cable core 22. In order to reduce the diffusion and accumulation of moisture in the structural spaces 31-31 of the cable core 22, the air cavities of the spaces are filled with a waterproof gelling mixture consisting of a mixture of petrolatum and polyethylene. An example of a blend zone of a waterproofing composition that successfully provides cable 21 to become waterproof is compositions with about 85% Vaseline and 15% Low Density Polyethylene ... 95% Vaseline and 5% Low Density Polyethylene.

To further improve the moisture protection of the cable 21, a further waterproofing mixture is placed in the space 32 between the core wrap 26 and the corrugated strip 27 and in the space 33 between the corrugated strip and the sheath 29. The filled cable 21 shown in Figure 2 forms a cable which has proven to be substantially impermeable to moisture. Thus, it provides adequate moisture barrier protection for the conductors 23-23 of the cable 21 and, as a result, substantially eliminates all the disadvantages caused by the diffusion of moisture into the cores of the cables used in the communications industry.

The twisted structure of the cable core 22 is arranged so that air cavities occur over the entire cross-sectional area of the core. As a result, it is difficult to ensure that the air cavities of the middle compartments 31-31 become as water-filled with the spring mixture as the air cavities of the outer compartments. Therefore, techniques and equipment have been developed that facilitate the placement of the waterproofing composition in the cable core 22 in such a way that substantially all the cavities of the intermediate spaces 31-31 of the core are filled with the composition.

Figure 3 shows a mixture addition apparatus 34 which facilitates the placement of a waterproofing mixture in the intermediate spaces 31-31 of the cable core 22 in accordance with the principles of the present invention. The apparatus 34 includes a support frame 36 mounted on a solid floor 37. The apparatus 34 further includes an inlet tube 35 which forms a pressure gradient inlet to the cable core 22 in the apparatus 34. The apparatus 34 also includes a first shrink portion 33 connected to the rear end of the inlet tube 35.

As shown in Figure 4, the shrink portion 38 includes a pair of spaced apart flange rings 39 and 41 threadedly attached to opposite ends of the sleeve 42 connecting them. A plurality of shrink members 43-43 and a spacer 44 are disposed in the sleeve 42. A pair of locking rings 46 and 47 are threadedly attached to opposite ends of the sleeve 42 to lock the shrink members 43-43 and the spacer properly oriented, as shown in Figure 4. A central opening is formed in each shrink member 43-43. having portions having an inner diameter substantially the same as the 22 core diameter of the cable core. As a result, as the cable core 22 passes through the openings in the shrink members 43-43, a substantially airtight seal is formed at the core entry point into the mixture placement apparatus 34.

Figure 3 further shows a first vacuum portion 48 which forms part of the apparatus 34 and is connected at one end to a shrink portion 38. A vacuum pump (not shown) is connected to the first vacuum portion 48 to develop suction to remove air from intermediate spaces 31-31 of the cable core 22 (Figure 2).

As shown in Figure 5, the vacuum portion 48 includes a sleeve 49 having a pair of flange members 51 and 52 attached to opposite ends. A pair of tubes 53 and 54 form ducts that communicate with an inner chamber 56 formed by the inner wall of the sleeve 49. Tubes 53 and 54 are connected to the respective vacuum pump generated by the vacuum section 48 by a suction which promotes the removal of air from the intermediate spaces 31-31 of the cable core 22.

The outer sleeve 57 is concentrically mounted on the intermediate portion of the sleeve 49 and forms an inner chamber 58 which can be used to release heating medium around the sleeve 49 if necessary.

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As further seen in Figure 3, a second shrink portion 59 identical to the first shrink portion 33 is connected at one end to the end of the vacuum portion 48 remote from the shrink portion 38. The second shrink portion 59 provides a substantially airtight seal to the cable core 22 passage from the vacuum portion 48 to the second vacuum portion 6l. . The second vacuum portion 61 is identical to the first vacuum portion 48 and is also connected to a vacuum pump (not shown) to facilitate the removal of air from the intermediate spaces 31-31 of the cable core 22. The first vacuum portion 48 removes substantially 85% of the air from the intermediate spaces 31-31 of the cable core 22. The second vacuum portion 61 removes substantially another 5% of the air volume in the intermediate spaces of the cable core before it entered the first shrink portion 38.

The second vacuum part 61 is attached at its opposite end * to the insulated shrink part 62.

As shown in Figure 6, the shrink portion 62 includes an inner sleeve 63 and a pair of flange members 64 and 66 threadedly attached to opposite ends of the sleeve. The three shrink members 67-67 are located in the central opening of the sleeve 63 and are separated by two spacers 68-68. A pair of locking rings 69 and 71 are threadedly attached to opposite ends of the sleeve 63 to hold the shrink members 67-67 and spacers 68-68 in the positions shown in Figure 6.

An opening 72 is formed in each of the intermediate members 68-68 to form a passageway which communicates with the opening 73 formed in the intermediate portion of the sleeve 63. An outlet tube 74 is attached to the inner sleeve 63 and a central opening 75 is formed therein, which communicates with the opening 73 of the sleeve.

The outer sleeve 76 is located concentrically with the sleeve 63 and is held in the position shown in Figure 6 between the flange members 64 and 66. A pair of tubes 77 and 78 are attached to the sleeve 76 and form ducts which communicate with a chamber 79 formed between the outer wall of the inner sleeve 63 and the inner wall of the outer sleeve 76. The insulating composition 81 is placed on the outer surface of the sleeve 76 to promote heat retention in the shrink portion 62 to which heat is transferred from the medium, e.g., steam, which is circulated through the chamber 79.

The smaller inner diameter portions of the shrink members 67-67 are substantially the same diameter as the outer diameter of the cable core 22. This feature provides a seal between the subsequent mixture addition devices and the vacuum parts 48 and 6l, which seal substantially prevents the water-resistant mixture from being sucked into the vacuum parts and consequently into the vacuum pump.

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It can be seen from Figure 3 that the opposite end of the shrink section 62 is connected to one end of the insulated cooling section 82.

As shown in Fig. 7, the insulated cooling portion 82 includes a sleeve 83 having flange members 84 and 86 attached to opposite ends. The center axis of the center passage 88 of the sleeve 83 is parallel to the axis of the center openings 89 and 91 formed in the flange members 85 and 86. A chamber 92 is formed within the sleeve 83 to allow a circulating coolant, for example water, to circulate therethrough. An inlet line 93 and an outlet line 94 are attached to the sleeve 83 to allow continuous circulation of coolant through the chamber 92. The insulator composition 95 is positioned over the sleeve 83 to maintain the coolant temperature at a constant level.

Flanges 97 and 98 are formed at opposite ends of the removable sleeve 96 and can be inserted into the central channel 88 of the sleeve 83. The removable sleeve 96 is held in place in the central duct 88 of the sleeve 83 by two locking rings 99 and 101 which can be threadedly attached to opposite ends of the inner sleeve, as shown in Figure 7.

The flanges 97 and 98 and the locking rings 99 and 101 seal the sleeve 96 to the chamber 92. Thus, coolant can be circulated around the sleeve 96 to cool the central duct 102 of the sleeve and the cable core 22 which can pass therethrough.

A sufficiently large central opening 102 is formed in the removable sleeve 96 so that the cable core 22 can pass axially therethrough. Since cable cores 22-22 of different sizes require a waterproofing composition to be placed therein, the removable sleeve 96 must be replaced at the desired times to accommodate cable cores of different sizes. For example, the cable core 22 may include 25, 50, 100, or 200 twisted pairs of conductors 23-23 (Figure 1); however, the flanges 97 and 98 of each removable sleeve 96-96 have the same diameter so that any removable sleeve fits into the center passage 88 of the sleeve 83.

It can be seen from Figure 3 that the opposite end of the cooling section 82 is connected to one end of the shrinkage section 103, which shrinkage section is identical in structure to the shrinkage section 38. The opposite end of the shrink portion 103 is connected to the mixture portion 104.

As seen in Fig. 8, the mixture addition portion 104 includes an inner sleeve 105 having opposite ends attached to the end plates 106 and 107. The center aperture of the sleeve 105 is axially aligned with the apertures 108 and 109 formed in the end plates 106 and 107. The outer sleeve 111 is located concentric with the inner sleeve 105 intermediate portion 9. 57672 and is spaced from the inner sleeve 105 to form a chamber 112 between the sleeves. The ends of the outer sleeve 111 are closed to close the chamber 112 except for the inlet pipe 113 and the outlet pipe 112! allowing steam to circulate through the chamber around the intermediate portion of the inner sleeve 105. The inlet pipe 116 is connected to the inner sleeve 105 to allow low pressure movement of the waterproofing mixture into the sleeve 105. The purpose of the outlet pipe 117 with valve is to allow the mixture to be cleaned from inside the sleeve 105 when the mixture addition section 102 is not used. Otherwise, the valve of the tube 117 is closed in order to keep the mixture inside the sleeve 105 under low pressure.

Mixture addition section 102! the end plate 107 is connected to one end of the shrinking portion 118, as seen in Fig. 3. The shrinking portion 118 is identical in construction to the shrinking portion 38. The opposite end of the shrink portion 118 is connected to one end of the temperature gradient portion 119, which portion is similar to the mixture addition portion 102 but does not include inlet and outlet tubes 116 and 117. The temperature gradient portion 119 is intended to allow the cable core 22 to which the waterproofing mixture was just added to pass through the region. , which is not heated. This procedure contributes to the gradual lowering of the temperature of the hot waterproofing mixture in successive portions of the cable core 22. As the cable core 22 passes through the temperature gradient portion 119, the mixture becomes less fluid and tends to solidify as it approaches the jolt-like state.

The opposite end of the temperature gradient portion 119 is connected to a shrink portion 121 which is identical in structure to the shrink portion 38. The opposite end of the shrink section 121 is connected to one end of the cooling section 122. The cooling section 122 is similar to the cooling section 82 except that the cooling section 122 does not include a removable sleeve 96 and does not have an insulator 95 as was around the sleeve 83 in the cooling section 82. As successive portions of the cable core 22 pass through the cooling section 122, a waterproofing mixture -31, in successive parts of the heart, cooled and somewhat solidified to such an extent that the mixture is no longer in a free-flowing state, but has now assumed a jelly-like state. The cooling procedure allows the mixture to remain in the intermediate spaces 31-31 of the cable core 22 as the core exits the other end of the cooling section 122 to a normal atmosphere.

The Cable Core 22 containing the waterproofing composition is then passed through a plurality of operating stations where the core wrapper 10 5 7672 26 (Figure 2) is wrapped lengthwise around the cable core. Additional amounts of waterproofing mixture are injected into the cable core 22 at the same time as a longitudinal seam is then formed in the core wrap 26. The tape is then wound helically around the heart wrap 26. The corrugated aluminum protective tape 27 (Figure 2) is then wrapped lengthwise around the core wrap 26.

When the corrugated aluminum sheath 27 is formed for subsequent longitudinal wrapping over the cable core 22 and core wrap 26, the cable core and core wrap is passed through a perforator where additional amounts of waterproofing mixture are injected immediately before the aluminum sheath is longitudinally wrapped around the core.

Thereafter, a cable core 22 having a core wrapper 26 and a corrugated aluminum shield strip 27 is passed through a bath (not shown) of a waterproofing mixture so that the mixture substantially fills the corrugation valleys of the aluminum shield strip 27. A cable core 22 having a core wrap 26 and an aluminum shield strip 27 is then passed through an extrusion head where a polyethylene sheath 28 (Figure 2) is placed over the corrugated aluminum shield strip. The sheathed product is then passed through a cooling tray (not shown) and a receiving coil (not shown).

Figure 9 illustrates a mixture preparation area 123 that includes a heating tank 124 located on the floor 37. Commercially available Vaseline is pumped from a barrel 126 via line 127 to a heating tank 124. The petrolatum is heated to about 55 ° C in a tank 124 and recycled through a collection tank 128. Selected amounts of heated petrolatum is passed through line 129 from a collector tank 128 to a metering pump 131 and then through a heat exchanger 132 where the temperature of the petrolatum is raised to approximately 130 ° C. The heated Vaseline is then pumped from the heat exchanger 132 to the mixing vessel 133.

Extruder 134 heats the low density polyethylene to a temperature of about 130 ° C and discharges the heated polyethylene into a mixing vessel 133 where the low density polyethylene is mixed with petrolatum to form a waterproofing mixture. The metering pump 131 allows for substantially accurate mixing of the petrolatum with the polyethylene in the mixing vessel 133. An acceptable mixture could include e.g.

94% petrolatum and 6% low density polyethylene.

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The purpose of the pump 156 is to pump the prepared waterproofing mixture from the mixing vessel 133 to various points on the production line where the mixture is placed in the cable. For example, as seen in Figure 9, the line 137 serves to transfer the water-resistant mixture from the mixing vessel 133 to the mixture addition section 104.

Activities

As shown in Figures 3 and 9, the cable core 22 is moved axially from the feed station (not shown) and the elements of the Epi mixture addition apparatus 34 in line. Successive portions of the cable core 22 pass through and through the pressure gradient inlet tube 35 to the shrink portion 38. Due to the substantially narrow openings of the shrink members 43-43 (Figure 4), the shrink portion 38 provides a substantially airtight inlet to the alloy addition apparatus 34 to the cable core 22. Thereafter, successive portions of the cable core 22 pass through successive vacuum portions 48 and 61 with substantially all air core in intermediate spaces 31-31 (Fig. 2), will be removed from the cable core. It should be noted that although two vacuum sections 48 and 61 have been described in the mixture addition apparatus 34, sufficient air can be removed from the intermediate spaces 31-31 of the cable core 22 by using one vacuum section.

The successive, air-evacuated portions of the cable core 22 are then passed through a heated shrink portion 62 and an insulated cooling portion 82, and then through a mixture addition portion 104. The waterproofing mixture is fed to the section 104 through the inlet pipe 116 and is kept under low pressure in this section. In this way, the waterproofing mixture is drawn from the air to the evacuated compartments 31-31, so that the mixture substantially fills the entire volume of the structural space of the cable core 22.

Although the shrink portions 62 and 103 are located between the mixture addition portion 104 and the vacuum portions 48 and 6l, it is possible that the waterproofing composition may undesirably be drawn from the mixture addition portion into the vacuum portions by suction generated by the vacuum pump. However, when the water-resistant mixture is drawn into the insulated cooling section 82, the mixture tends to solidify into a gelatinous state and become less fluid. When the cooled mixture enters the heated shrink portion 62, the mixture becomes reheated and flows through the openings 72-72 and tube 74 illustrated in Figure 6. In this way, any waterproofing mixture that tends to approach the vacuum portions 48 and 61 is inverted in the heated shrink portion. 61 and thus prevented from entering the vacuum sections and the vacuum generation system.

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As already described above, successive portions of the cable core 22 exiting the mixture addition portion 104 are passed through a temperature gradient portion 119 which allows a controlled reduction in the temperature of the waterproofing mixture contained in the cable core spaces 31-31. Further, successive portions of the cable core 22 are then passed through a cooling section 122 to finally prepare the mixture for the cable core to exit the atmosphere. The cooled mixture assumes a jelly-like space, does not run and remains in the intermediate spaces of the cable core 22, providing a cable core in which substantially the entire structural space of the core is filled with a waterproofing mixture.

It is particularly important to note that the gel-like mixture in the intermediate spaces 31-31 of the cable core 22 is rapidly cooled before it exits the cooling section 122 and into the atmosphere. This effect results in a mixture in the interstices 31-31 which itself remains inside the heart and does not require an external cover.

The subsequent addition of the waterproofing mixture when the core wrapper 26 is added and before the aluminum shielding strip 27 is formed around the core wrapper, as described above, further enhances the water resistance of the cable 21 to be manufactured. In addition, placing the waterproofing mixture on the corrugated aluminum shield strip 27 prior to forming the polyethylene sheath 29 further improves the waterproof quality of the final cable 21.

Although not shown in the figures, wiping tools may be used at various locations after the mixture addition apparatus 34 and waterproofing mixture is added to the cable core 22 together with the removal equipment associated with these tools to remove any excess mixture wiped from the moving cable core 22. before the heart enters the mixture addition section 104.

Figure 10 illustrates an embodiment of a cooling section 138, which is an alternative embodiment and may be used in place of the cooling section 82. The cooling section 138 includes a sleeve 139 attached between the end plates 141 and 142. Central openings are formed in the end plates 141 and 142 with chamfered surfaces 143 and 144. Rubber rings 146 and 147 are disposed in grooves formed in the chamfered surfaces 143 and 144. A circular protrusion 148 having a threaded circumferential surface 149 is formed in the end plate 14l.

The removable sleeve 151 is attached to the circular flange members 152 and 153 at their opposite ends. The circumferences 154 and 156 of the flange members 152 and 153 57672 are chamfered as shown in Figure 10 to correspond to the chamfered surfaces 143 and 144 of the end plates 141 and 142. The removable sleeve 151 can be inserted into the sleeve 159 as shown in Figure 10 at a position where the chamfered perimeter 156 becomes in contact with the rubber ring 147 to form a seal at the right end of the cooling member 133. The chamfered periphery 154 of the flange member 152 contacts the rubber ring 146 to form a seal at the left end of the cooling portion 138, thereby sealing the chamber 157 formed between the sleeves 139 and 151. The detachability of the sleeve 151 allows different diameter sleeves to be exchanged for different diameter cable cores 22-22. In addition, the flange members 152 and 155 of all sleeves 151-151 are the same size.

The plug 158, through which a central passageway 159 is axially formed and further internally threaded portion 161 is threadedly projected 148 and rests on the outer surface of the flange member 152, locking the detachable sleeve 151 to the sleeve 139 · Wires 162 and 163 are attached to the sleeve 139 to allow cooling continuous circulation of cooled water through the chamber 157 and the removable sleeve 151.

A pair of air cylinders 164 and 166 are attached to the outer surface of the sleeve 139 and provided with piston rods 167 and 168. The movement of the piston rod 167 controls a circular slide 169 formed with a plurality of keyways 171-171 to direct the movement of the slide over a plurality of wedges radially outward from the outer surface of the sleeve 139. The slide 169 also moves over a rubber ring 175 mounted in a groove formed in the periphery of the end plate 141.

The movement of the piston rod 168 monitors the circular slide 174 at the opposite end of the cooling section 138 by allowing the Liu movement of the keyways 176-176 formed in the slide and moving over the keyways 177-177 radially formed on the outer surface of the sleeve 139. A rubber ring 178 is positioned in a groove formed in the periphery of the end plate 142 to further form a rolling surface on the slide 174.

Although not shown in Fig. 10, the cooling section 138 may include insulation disposed on the outer surface of the sleeve 139 to insulate the cooling section so that the cooling properties of the section are maintained at the desired level.

The cooling member 138 may be attached to a pivoting support (not shown) directed perpendicular to the axis of the cooling member and the support pivotable some distance from the shaft axis. For example, the cooling section 138 could replace the cooling section 111 57672 82 shown in Fig. 3. The pivoting support of the cooling section 138 would extend downwardly and be attached to a fixed member (not shown) whose axis is parallel to the axis of the in-line components 34.

When it is desired to replace the detachable sleeve 151 with a sleeve having a different diameter in the central duct to allow passage of a different sized cable core 22, the cooling section 133 is pivoted out of position in the apparatus 34. The plug 158 is removed and the detachable sleeves 151-151 are interchanged. Since the size of all the flange members 152 and 153 of the detachable sleeves 151-151 is the same, the new, inserted detachable sleeve again forms a seal with the rubber rings 146 and 147. The plug 158 is then re-threaded into the protrusion 148 to lock the new sleeve 151 into the sleeve 139. · The cooling member 138 is then pivoted back to a position aligned with the axes of the other aligned components of the apparatus 34.

It can be seen from Figure 11 that after the cooling member 138 is returned to an axially aligned position with the in-line components of the apparatus 34, the air cylinder 164 is controlled to move the piston rod 167 to the left so that the surface 179 of the slider 169 moves toward the insulated shrink portion 62. A circular protrusion 182 is formed on the surface 179 of the slide 169 and moves into a circular groove 183 formed on the surface adjacent to the flange ring 179.

It can be seen from Figure 10 that the air cylinder 166 is controlled to move the slide 174 into similar contact with the flange ring adjacent the shrink portion 103 (Figure 3), causing the cooling portion 138 to be axially locked to the other components of the mixture addition apparatus 34.

Using the cooling section 138 as described above allows the detachable sleeves 151-151 to be replaced without interfering with any insulation installed around the sleeve 139 and allows for a relatively quick and convenient replacement of the detachable sleeves.

Figure 11 illustrates a shrink portion 62 open at the top 184. The open top portion 184 illustrates another embodiment of the shrink portions 38, 59, 62, 103, 118 and 121, in which the hinged portion (not shown) is movable relative to the rest of the shrink member and intermediate members. uncovering. For example, shrink members 136-186 and spacers 187-187 are shown in Figure 11. When a hinged top is used in the shrink portions of the apparatus 34, the shrink members can be quickly replaced to allow handling of cable cores 22-22 of various sizes.

Claims (15)

Thus, in the method and apparatus for adding a waterproofing composition to a cable core, a relatively airtight axially aligned line assembly is used to remove air from the core spaces 31-31 »to add the mixture from the air to the evacuated spaces and bring the mixture into a gel-like structure so that the mixture remains that an external cover is needed to hold the mixture in the heart. In addition, the cooling properties 11a of the apparatus 3a provide a relatively clean vacuum operation, where substantially no parts of the mixture are drawn into the vacuum parts of the apparatus. Further, "the interchangeability of the cooling section 138 further enhances the rapid exchange of parts of different sizes within the apparatus when a cable core having a size different from that of the previous cable core has to be passed through the apparatus. A method for filling a stranded electric cable with mass, wherein the inflatable intermediate spaces of the stranded cable are first emptied in at least one vacuum chamber and then filled with mass in a filling device, characterized in that a) the drained parts of the stranded electric cable are first cooled in a first cooling device before being passed through the parts of the filling mass sucked into the vacuum chamber from the filling device before they penetrate the vacuum chamber gel and thus prevent their further penetration, b) supply poorly flowing filling mass to the filling device, through to make the filling mass gelatinous so that the filling mass adheres to the intermediate spaces of the cable without other fixing measures. A method according to claim 1, characterized in that the drained parts of the cable are heated before being cooled in the first cooling device so that the parts of the filling mass sucked into the vacuum chamber from the filling device after passing through the first cooling device become fluid and drained. Method according to Claim 1 or 2, characterized in that the mass-filled cable is drawn through a third cooling device with temperature drops before being passed through the second cooling device. 16 57672 Method according to one of Claims 1 to 3, characterized in that a dimensioned pressure is maintained in the filling device in such a way that the suction effect of the emptied intermediate spaces in the filling mass is strengthened. Method according to one of Claims 1 to 4, characterized in that the filling mass consists of a precise mixture which is pumped into the filling device in a pre-mixed state. Method according to one of the preceding claims, characterized in that the filling mass consists of a mixture of petrolatum and polyethylene preheated to a predetermined temperature. Process according to Claim 6, characterized in that the mixture contains 85 to 95% by weight of petrolatum and 15 to 5% by weight of polyethylene. Process according to Claim 6 or 7, characterized in that the preheating temperature of the mixture is about 130 ° C. Apparatus for carrying out the method according to claim 1, characterized in that it comprises the following parts a) a vacuum chamber (48, 61) for removing air from successive parts of successive parts of the stranded electric cable (22), b) a first cooling device (82) for successively drained parts of electric cable (22) (c) a device for filling the stranded electric cable (22) with pulp, d) a device for passing successive emptied parts of the cable (22) through the filling device (104), e) a device (I36, 137) for conducting a poorly flowing filling mass in certain in quantities to the filling device (104), f) a second cooling device (122) for securing the filled mass, and g) a device for pulling the mass-filled cable (22) through the second cooling device (122). Apparatus according to claim 9, characterized by a device (62) for heating successive discharged parts of the twisted electric cable (22) before cooling these parts in the first cooling device (82). Apparatus according to claim 9 or 10, characterized by a device (131, 133) for pre-mixing the filling mass of the various components in a certain mixing ratio and a device (136) for pumping the precisely mixed filling mass to the filling device (104). 17 57672 Apparatus according to one of Claims 9 to 12, characterized by a device for maintaining the pressure in the filling device (10 * 1). Apparatus according to one of Claims 9 to 12, characterized in that the first cooling device (82) comprises the following parts: a) an outer sleeve (83), b) an inner sleeve (96) arranged inside the outer sleeve (83), which allows a stranded electrical cable (22) passing successive portions, c) a sealed chamber (92) disposed between the outer sleeve (83) and the inner sleeve (96), and d) a device (93, 9 * 0 for circulating the cooling medium through the chamber (92). " Apparatus according to claim 13, characterized in that the inner sleeve (96) is made removable to allow switching between inner sleeves of different sizes, the sizes of the inner sleeves being selected to correspond to the diameters of the twisted electrical cables (22). Apparatus according to claim 13 or 14, characterized in that the support (84, 86) for holding the cooling device (82) is aligned with the filling device (104), the support (84, 86) being arranged to move so as to allow an outer sleeve (83) to facilitate movement of the inner sleeve (96).