DE482477C - Machine for closing bottles - Google Patents

Description

Machine for Closing Bottles It is already known to have closures to be attached to milk bottles and the like by placing a paper cap over the mouth the bottle is turned upside down and the downwardly directed flange of the hood against the bottle neck is pressed by the electric current solder o. The like. is heated and thereby the two wire ends, which are placed around the hood flange are fused together.

The machine according to the invention is used to close bottles, which contains a mechanism by which during and after the contraction of the Hood the binder is put in a liquid state to keep the hood in contracted state Secure state. A support for the bottle and the mechanism for Liquefaction of the binder are adjustable with respect to each other, so that bottles different heights on the same support in the same machine can. A mechanism that is also present in the machine pulls the wire or another tension member around the hood, and the one used to liquefy the binder Mechanism liquefies the binding agent at neighboring points of the tension member, so that the machine is characterized by the union of the known electrical Resistance to liquefaction of the binder with the tightening device of the wire around the hood or the like.

The power supply to the binding agent takes place by means of springs pressed against it Contact pins in an insulating holder, and those protruding from the holder The ends of the contact pins are in sliding contact with adjustable contact rails, which are isolated from each other again. If, therefore, when rotating the bottle carrier the contact pins connected to the bottle carrier and rotating with it and their Feathers pass a point where they come into contact with the two arches occur, the electrical connection takes place and the binding agent is heated. .

The drawings illustrate an embodiment of the invention: The bottles i are placed one after the other on a feed table a (Fig. I), and this feed table rises on legs 3 of a lower base plate q .. The Fastening hoods 5 are loosely placed on the bottles and extend to under the beads 6 (Fig. 8) of these bottles.

A guide channel 7 (Fig. 3) leads: the bottles one after the other to a star wheel 8, which pushes the bottles one by one onto a table io which is provided with bottle supports 9 (Fig. 8a). An electric motor ii (Fig: 3) puts the main shaft 12 under - engagement of a change gear 13 in rotation and a worm 14 on the main shaft 12 (section i) drives the vertical shaft 16 on which the table is placed through the gear 15 io is attached and which also near its lower end: the gear 17 firmly carries. The shaft 16 extends (section i) all the way through the machine and has bearings at 161 (section 8a and Fig. I), and these bearings sit on a spoke body 162 which is attached to the post 163 as shown in Fig. I. The gear 17, near the foot end of the wielie 16, is in engagement with another gear 18 on a shaft 19 (Dept. i and 3), on which the latter the star wheel 8 is arranged at the top.

Around the foot of the shaft 16, the lifting track 2o is laid through which the rollers 21 (Fig.8a) are raised and lowered during the movement of the table io will. Each of the bottle supports 9 is seated at the upper end of a sleeve 22 in the lein Piston 23 is slidably arranged. A spring 24 constantly pushes this piston down and lies down with the other end against the floor facing upwards of the sleeve 22. The pistons 23 are connected by links 25 (Section 8a and Fig. i) with angle levers 26 connected, and at the supply ends of this angle lever, the rollers 21 are rotatable arranged. The other arms of the angle lever 26 close to the hanging rod-like Supports 27, which protrude from its circular plate 28 downward, the -on the vertical Shaft 16 is attached in such a way that it rotates with her (Dept. 8a). The circular plate 28 contains bearing stubs 29 for the spring sleeves 22.

The lifting rollers 21 therefore rotate together since the shaft 16 the axis of this shaft. They are alternately lifted and lowered and also lift the bottle supports 9 when they are shifted in the vertical or let them go downstairs. Should be when lifting the bottles for any If there is an excessively great resistance to be overcome, the springs 24 provide after, so that a breakage of the bottles is avoided.

A disk 3o is attached to the Wello 16 above the turntable io (Dept. i and 8). While this disk has to rotate with the shaft 16, it can be moved in the vertical direction because the wedge 31 (Fig. 8) is guided in a long groove in the shaft 16. A bevel gear 32 (section 8, below) is designed as a nut in its hub and runs on the thread of the shaft 16. This bevel gear 32 engages through projections in a circumferential groove of the hub of the disc 30, so that when the Bevel gear 32 on the shaft 16 had the disc 30 and can be lowered. In order to bring about such a rotation, another bevel pinion 35 on a shaft 34 meshes with the bevel gear 32 (Dept. i and 8), and the shaft 34 is seated in a bearing on an angle support 33 which is attached to a stationary bearing part of the shaft 16 is rotatably attached. If this short, square shaft 34 is rotated by a tool or the like, then the scoring 132 is also rotated, and since it is screwed, the disk 30 is adjusted higher or lower. You can therefore handle bottles of different heights depending on the setting of this disk 3o. This also adjusts those chucks 37 in the vertical direction, which are fastened to the turntable 3o according to Figs. 8 and 9, and between these chucks or holders 37 for the upper parts of the bottles and the rotating table io there are guide collars 38 ( Section 9) arranged for the neck of the bottles. The guide collars expand downwards (Fig. 9) and are attached to angle brackets 39, which are screwed to the underside of the table 3o as shown in Fig. 8.

After placing a bottle on a nozzle g through the one shown in Fig.3 Feed device has been pushed on, the table with the support is slightly rotated, before the lifting of this support and bottle is taken care of by the lifting track 2o.

When the bottle is lifted, the latter pushes a piston 4o up into the holder 37 (section 9). The handle 41 of this holder extends through a long sleeve 42 which rotatably rests in the bearings 43 and 44. The bearing 44 is integral with the disc 30, and the bearing 43 is held by a set screw 45 (section 8) on its angle bracket 47, which in turn is attached to the top of the turntable 3o as shown in Figs. If the piston 40 is pushed upwards by lifting the bottle, it pushes a disc 48 upwards in a force-locking manner, and this disc has three alignment pins 49 (sections 8 and 9) which can slide in corresponding bores in an extension 5o of the sleeve 42 . The extension 50 is screwed to the sleeve as shown in Fig. 8, and when the disc 48 is lifted with the pins 49, the pins press against the underside of one. Coupling collar 5 i, which has a circumferential groove. In this circumferential groove, pins 53 of a fork 54 (section 4), which can swing out around the pin 55, are placed in a known manner, and this coupling fork forms part of a mechanism for wrapping a wire or other tension member around the hood. The tang 55, around which the fork swings out according to Fig. 8, is located at the upper end of the upright supports 47, which are attached to the turntable 3o. The Gabe154 carries at the other end at 56 a loaded block against which a pin 57 presses from below, which is enclosed by the spring 58 (section 8). The spring is supported at the bottom against a neck 59 which is slidable on the pin 57. With the upper end it presses against a yoke 6o, which is arranged immovably on the pin 57 and which, on the other hand, is firmly connected to a second rod 61, which in turn is guided in the bearings 62 and 63 of the upright angle brackets 47.

If the piston 40 (section 9) is lifted by the bottle, it is the Gahel54 (dept. 8) swung out in the clockwise direction and it pushes through it the pin 57 downwards, whereby at the same time the rod 61 downwards postponed. will. On the rod 61 there is an adjusting nut 64, which on the arm of an angle lever 65 presses, which is also swingable on the support 47 is stored. This pressure on one arm of the angle lever causes the other 8 released from its engagement on a shoulder 66, the latter is fixedly arranged on the slidable sleeve 59. The bell crank usually holds this sleeve 59 is fixed in its highest position, and as well as it out of its blocking position is swung out by the nut 64, the spring 58 snaps the sleeve 59 downward. The swing of the angle lever 65 from its locked position by the Nut 64 takes place against the tension of a spring 67 indicated in Fig. 8, which has the task of pulling the angle lever back into its original position. For this purpose, one end of the spring is connected to the angle lever, and its other end is attached to the support 47 again.

A fork-like yoke 68 is also attached to the sleeve 59, the pins 69 (section 9) of which penetrate into the circumferential groove of a coupling collar 7o which is connected to the sleeve 42 so that it must rotate with it, but on it in the direction the axis can move. The coupling collar 7o has coupling claws or teeth at each end in order either to come into engagement with a fixed coupling part 71 of the bearing 43 (section 9) or to be brought into engagement with another rotatable coupling part 172. Thus, when the sliding coupling collar 70 is moved upward into the position shown in FIG. 9, it is held in place and the sleeve 42 is thereby also secured against rotation. The engagement of the coupling collar 7o in the fixed. Tei171 takes place at the beginning of the horizontal migration of the. relevant bottle support 9 instead.

At the lower end of the sleeve 59 because pin 57 is off. Fig. IO lifting bar 591 arranged: which is in engagement with a roller 592 on an arm 593 (section 5), the latter being attached to a toothed wheel disk 594 (see also Figs. 6 and 8). The disk, 594 provided with a toothed ring is covered with a hub 595 (Fig. 8), which loosely surrounds the shaft 16, and under the thus held hub 595 of this toothed disk 594 there is a ball bearing 59s, which is accordingly between the rotating disk 30 and the non-rotating hub 595 is on. A ring 597 (section 8) is screwed onto the end of the hub 595, and an annular disk 598 is on the other hand attached to the rotary disk 3o by screw pins so that the bearing and also the ring 597 are held against displacement in the axial direction of the shaft 16 . Fig. 1 shows that the hub 595 is locked against rotation by a pin 599 which is inserted into the head bearing 161 of the shaft 16 in the manner of a dowel and which slidably passes through a shoulder 5910 of the hub 595.

Due to the arrangement described, the displaceable coupling sleeve 70 and the rotatable coupling part 72 are kept separate from one another with certainty when the horizontal movement of the turntable 30 and the bottle support 9 begins. This separation of the two coupling parts 7o and 72 will be maintained as long as the roller 592 of the arm 593 of the toothed wheel disk 594 engages with the arm 591, which of course is rotated with the disk 3o, and there are just as many such supports 47 on this disk etc. attached than bottle supports g are contained in the table. Only when a bottle is lifted can the two coupling parts 7o, 72 engage with one another. If there is no bottle on a support, the displaceable coupling sleeve 70 remains in engagement with the fixed coupling part 71 (FIG. 9), since the lever 65 rotates out of its position according to FIG.

If, however, the disengagement of the coupling 7o from the fixed coupling part 71 and the engagement in the rotatable coupling half 72 @ e'in initiated by the lifting of the piston 4o by an upwardly moved bottle, the sleeve 42 is also set in rotation in which the Rod 41 of the piston 4o slides. The ratios are chosen so that the rotatable coupling 72 covers one and a half turn when the turntable 3o has rotated only by half of a complete circular movement. A second half rotation of the coupling member 72 only takes place when the turntable 3o passes through the last sixth of its full rotation.

The sleeve 42 (Fig. 9) is used to wrap wire around the hoods of the bottles. The 'wire 73 leads according to Fig. 9 and io through a nozzle 74 at the foot end of the sleeve 421-. This nozzle is rotated around the top of the bottle. The holder 37 has for this purpose an angular mechanism consisting of: a spool 7 5 (Fig- 2) on a vertical wedge 76 which is attached to its end of the yoke 77 which is fixed on the shaft 52, which of . the extension 50 (Fig. 8) goes up. The shaft 52 and the shaft 77, which are firmly connected to it. is, rotate .sich with the sleeve 42. The wire coil 75 sits loosely on the shaft 76. A spring 78 (Fig.'2) presses a washer 79 against a nut 8o of the shaft 76. This spring presses a washer 81 against the Coil 75, so that this coil -an the yoke 77, namely on the flange 82, is pressed. As a result of this spring, the spool cannot rotate faster with bending tension on the shafts 76 and 52 than is caused by the removal of the wire 73. It is slowed down. Depending on the setting of the spring 78, the wire will be more or less tensioned when it is removed from the spool.

The wire goes from the spool over the guide roller shown in Fig. I and 2 83 and 84 on a yoke 85, which can be formed integrally with the yoke 77, and thence through a feed tube 86 which is fixed with respect to the sleeve 42 (Fig. 8, 9). After exiting the feed tube 86, the wire passes over again a guide roller 87 (Fig. 9) and around a guide block 88 attached to the nozzle 74 is. At 89 the wire (Fig. 14) enters the nozzle and is passed through a block 9o pressed against one side of the nozzle (Fig. 14), because the block 9o - under the Influence of a leaf spring 91 is (Fig. 9).

Each end of the wire that entered nozzle 74 is now captured between two clenus pieces 92 and 93 (Fig. 14). The two clamps hold this end of the wire while the nozzle rotates one and a half times around the corresponding head of the bottle. The wire is clamped when the two coupling parts 70 and 72 are separated from one another, that is to say assume the position shown in FIG. 9. Of the two clamping pieces 92, 93, one clamping piece 93 is stationary, and the other clamping piece 92 is attached to a small holder 95 as shown in FIGS The holder has its slot 96, and the ball end of a lever 97 (Fig. Ii) enters into this slot, which has a pivoting pin 98 in bearings 99 and 100 which is attached to the frame 47 above and to the bearing shoulder 39 below (Fig. 9 and 10). On this long pivot pin g.8, which extends vertically next to each frame147, an arm sits below (Fig: 9 and ii). A bolt 102 penetrates the rear end of the lever 97 and the arm ioi and is enclosed by a spring r o3; which rests against the disc 104 and which in this way presses the head of the bolt io2 against the end of the lever 97 (Fig. Ii). -At the other end of the vertical pin 98 for the lever97 is an arm io5 attached to its fre At the end of a roll io6 (Fig. 4) carries. During the rotation of the table 3o and the angle support 47 connected to it, it rides my slot 107 of a lifting disk 108, which is arranged at the top of the fixed hub valley 595. As a result of the arrangement of this round control disk io8 'with its stroke groove 1 07 , the clamping piece 92 is immediately brought into clamping action when the rotation of the disk 30 starts, and this clamping action is maintained until a piece of wire is overlapped by the rotation of the sleeve 42 the other piece of wire has placed and until these two pieces of wire are set with respect to the cap of the bottle. - The clamping effect is also maintained in order to wait for the connecting means to harden. 'The wire will then. cut off at the nozzle 74 before the clamping piece 92 ixt has been brought to the release position. The release position comes about when the roller 106 enters the round part of the lifting groove 107, after it has passed through the round part of this lifting groove. Only after completion of one and a half revolutions on the part of the wrapping sleeve 42 is the device used by which the wire is attached to the hood.

In order - to set the rotatable coupling sleeve 72 in rotation, it has a spiral gear i o9 in engagement with a correspondingly designed gear i io on a shaft i T i, which is mounted in the vertical support 47 according to Fig. 8 .. Hazy support with all others attached to the disk 3o: supports 47 rotates around the axis of the shaft 16 and the spiral gears remain in engagement with the non-rotated gear i 12 (section 6), which is actually just a curved, fixed rack on the Represents the circumference of the disk 594 (Abt. @ 8). A gap remains between this circular rack 112 and the spiral gear wheel iio at the start of the rotary movement, so that the wire feed nozzle 74 does not rotate at the start of this rotary movement of the disk 3o. That is precisely during the time in which the lifting of the bottle is carried out by the lifting bar 2o. The spiral gear i io is inevitably locked against rotation by, according to Fig. 6, a bar 113 from the circumference of the curved rack i 12 penetrates into a slot of this spiral gear i io, as is also shown in Fig. 8. Before the gearwheel parts i 3o, i 12 then come into engagement, the coupling parts 70 and 72 are brought into engagement position by lifting the bottle. If there is currently no bottle on a bottle support g ', this engaging movement of the coupling parts 70, 72 does not occur, and even then there is no rotation of the wire nozzle 74 during the migration of this bottle support 9.

According to Fig. 8 there is between the non-displaceable coupling half 72 and the turntable 3o turned on a ball bearing 114, and another ball bearing i 15 is located between the bearing stub: 44 of the turntable 3o, as shown in Fig. g and the foot part 421 of the rotating sleeve 42. A third ball bearing i 16 (section 9) is located between this foot part 421 and the upper floor of the holder part 37. The ball bearing i 16 prevents the sleeve 42 from causing the holder 37 to rotate, and this also prevents rotation of the bottle gripped by this holder.

The rotation of the wire feed nozzle stops after -the disk 3o half a turn, because then the spiral gear occurs again i i o out of engagement with the arcuate rack i 12 and in engagement with a Locking bar 117 (section 6), similar to that bar i 13, which at the beginning of the rotation of the Washer holding the spiral gear iio in place.

The overlapping parts of the tension member surrounding the bottle neck, which preferably consists of wire, are then firmly connected to one another, e.g. B. by solder as shown at 118 in Fig. 16. The lost melts around the two pieces of wire around, and the fusion is made while the spiral gear iio (Dept. 6) begins to bend around the axis of the shaft 16 on the curved part 117. The cooling of the solder takes place during the course of this movement, and at the end of this movement the tension member is cut off.

It is preferable to use wire that is already coated with tin or the like. has, but this is not absolutely necessary and furthermore not that the soldering is made at the crossing point, or that the ends of the tension member, which hold the hood firmly, overlap at all.

In the present case, wire is pulled tightly around the hood, namely- wrapping takes place by more than a full circumferential length, for example by one and fifth length, so that overlapping barks occur, and here the Soldering done. This results in protruding wire ends that are the solution facilitate this closure by tearing off the wire.

The drawings also show a mechanism for heating the connecting part, such as the lobes. According to Fig. 12, two contact pins i ig, 120 protrude from the metallic sleeves 121, 122, as they are pressed by springs 123 in its direction. These metallic sleeves are, however, slidable in insulation sleeves 124 and 1-5 which, as shown in Figs. 1, 7, 8, are carried by the guide 38 through which the mouth of the bottle is urged against the holder 37. A battery 126 supplies power to the metal sleeves 121 and 122 and thereby also to the wire ends. The contacts 118, i2o are pulled from these ends after the solder has melted, so that the solder cools. The cooling takes place during the engagement of the spiral gear iio with the curved piece 117.

According to FIG. 13, two curved rails 127 and 128 are held together by bolts 129 which extend through bores in the rail i28 and through slots i3o in the rail 127. However, the two rails are insulated from one another by the insulation sockets i3i and 132. As a result of the arrangement of the slots, the two arch rails can be displaced and adjusted with respect to one another in the direction of the slots. The bolts 12g also secure another rail 133 on a yoke 134 (sections 12 and 13), on which the conductor rails 127 and 128 are also fastened with the inclusion of the insulating bushes and blocks. The yoke 134 is connected to the rods 1 63 by clamps 13 5, the arrangement of which can be seen from FIG. In this way, the yoke and thus the contact device can be set up in accordance with the adjustment of the upper part of the machine for the treatment of bottles of different heights. The bolts 129 pass through as shown in Fig. 12 and 13 and the insulation disks 136, and the yoke 134 is the lifting bar i37 in direction against a roll 46. In addition to the bolt 129 is fixed to another pin 138 near the free end of the Schirene 133 this rail connects to the yoke 134.

According to Fig. 12, the metal sleeves 121, 122 have turned parts 139 in the insulation sleeves 14o of a transverse head 141. The adjustment of the spring sleeves with respect to the block is carried out by the nuts 42, which are screwed onto thread extensions of the turned parts 139. Contact springs 143 and 144 are in conductive contact with these spring sleeves 121, 122 by means of the nuts 145 just mentioned, and the ends of these springs and contacts slide on the rail 133 or on the rails 127 and 128, as shown in Fig it can be seen .13. the crosshead 41 also carries a roller 146, against which the projection 137 abuts the yoke 134 when the turntable rotates about the shaft 16. if the scroll wheel I io starts engaging. with the arcuate retaining strip 117 to contact (Section 6, 'right),' the Rollei 146 of the relevant cross head will ride on the projection 137 of this yoke, and as a result the cross head will be swung out inwards, and the contact pins will be 19, 12o (Section 13) pressed against the tension member. As a result of this tension member is heated sufficiently to make it liquid at the solder at the point at which the two ends of the wire cross each other. the length of the time period of the power supply depends on the setting of the rails 127, 128 away. When the contact spring 144 leaves the rail 12.7, the circuit is opened. At the same time, the contacts are then also withdrawn by the spring 147 (Abt, 14), since this spring encloses a bolt or pin 148 which is screwed into the guide collar 38 at one end and has a head at the other end. As soon as the roller 146 leaves the projection 137 of the yoke, the spring 147 presses against the crosshead and thereby pulls the contact pins i, i9, i2o away from the wire.

Even after this circuit has been opened, however, the spiral gear wheel i io still remains in locking engagement with: the arched strip 117, and the solder is now cooled during this period. After sufficient cooling, that is to say when the spiral gear wheel i io almost leaves the bow bar 117 , the wire is cut, with a tension on this piece of wire between. the Zü-Euhr nozzle 74 and, the wire clamp 92, 93 is present.

The cutting device for the wire consists of the fixed knife 149 and the pivoting knife i5o (section 18 and i9) - The two knives are carried by a post 151, the position of which in relation to the other parts of the machine. From Fig. " 6 and 7. This post 151 is located on a lever i52 (sections 6 and 7), which sits on an oscillating shaft 153, which rests rotatably in the bearing support 154. The bearing support 154 itself is again attached to a yoke i55 ( Section 6 and 7. The shearing knife 15o forms an arm of an angle lever which swings out around the pin 157 of the post 151. That arm of the angle lever which is opposite the knife 15o can swing back and forth between two stops 158 and 59 . the two end positions are shown in Fig. 1, 8 and 19- shown. These stops i58, 159 are located in, a bracket 16o, which is fixed to the yoke i55. When rotary disk 30 has rotated far enough, so to -nähert the -Anschla g 158 the knife 15ä (Dept. 1 8) and presses the angle lever in such a position that the wire that is just between the two knives is cut. Then: the stop 159 approaches the knife 15 and this knife swings again in the other position, as indicated in Fig. 17 in full lines and in Fig. 18 with dashed lines. The two knives 149 and 150, however, are usually outside the path of the wire and are only used with respect to it. Wire set in cut position when stop 158 approaches the knife. The lifting 1152, on which these two knives sit, is monitored by the cams 161 and i62, which are arranged on the turntable according to Fig. 6 near the circumference. The cam 161 first engages on the hook 162 on the rear part of the lever 15z and thereby swings the two measuring legs in a position in which they take up the wire between them. Only then are the two knives moved with respect to one another in such a way that they cut the wire. .the wire has been cut and the knives are in their final position (section 18), they are moved away from the wire again, for which purpose the common lifting device 1152 is swung out by the cam _162, which is placed on the shoulder 164 (section 6 ) engages the pin 153, on which the lever 152 is also seated.

After moving the two knives so out of your path of the wire have been, the turntable goes on, and now the spiral gear leaves i io the arched strip l 17 and engages the toothing 165 that is attached to the stationary Disc 594 comprises an arcuate portion and which is of course in the same plane like the curved rack ii2 described above. During this intervention of the Spiral gear i i o on the rack 165 thereby becomes the wire feed nozzle turned half a turn around the end of the wire that protrudes from the nozzle, insert between the clamping pieces 92, 93 (Fig. i i and 12). This piece of wire is then detected by the clamping pieces, namely the detection takes place when the next full cycle of machine operation begins. Between. both Operations, namely cutting the wire and clamping the end of the wire, but the support 9, on which the bottle rests, descends, and when this support is brought back into the plane of the table i o, the bottle can be removed will. The bottle is ejected by the fingers 166 of a wheel that is attached to the rotating table io (Fig.3 and 8a). These fingers push the One after the other, take the bottle down from the table and place it in the duct 167, from which the bottles slide themselves out by being lined up, so that they can be removed by the worker.

In the machine shown, the bottle support rotates with reference to a point in space to order the bottles in sequence the different To supply places where various work is carried out on it. the The main thing is that the bottles move with respect to those places where These different processes take place, whether they are doing it with reference to a particular one Point in space. or whether they. just with reference to the mechanism a Perform movement.

Claims (1)

PATENT CLAIMS: i. Machine for closing bottles, in which a cap covering the bottle mouth is pulled together around this bottle mouth, characterized in that during and after the contraction of the cap contact pins (zig, i2o) put a binding agent in a liquid state in order to close the cap in the contracted state secure, with a support (9) receiving the bottle and the contact pins (i I9, i2o) for liquefying the binding agent adjustable with respect to one another to @ Aus; management of this liquefaction work. z. Machine according to claim i, characterized in that a clamping device (42, 74 92, 93) tightens a tension member (73) around the hood so that the hood is drawn together, and that the heating device (119, 12o) serving to liquefy the binding agent this binding agent liquefies and attaches it to adjacent points of the tension member (72) so that in this way the hood is held in the contracted state by the tension member. 3. Machine according to claim 2, characterized in that the clamping device for uniting the tension member (73) with the hood comprises a rotating nozzle (42i, 74) through which the tension member is wound around the hood. 4. Machine according to claim i to 3, characterized in that contact pins (1l9, 120) are connected to sliding springs (i43, 44) and move past curved pieces (i33, 128) with the bottle on the support (9), which the latter are isolated from each other and connected to a power source in order to send the current through the contact pins (ii 9, i 2o) through the contact of the sliding springs (143, 144) with the arc pieces, the latter resting on the traction means (73) and thereby with Heat the binding agent connected to the traction mechanism. 5. Machine according to claim 4, characterized in that the contact pins (i 19, i 2 o) are fastened in a carrier (141) which is usually urged in a direction in which contact of the pins (i i9, i2o) does not take place with the traction means or the bottle cap, but is pushed onto the traction means in the pressure position when the bottle moves past a lifting yoke (134). 6. Machine according to claim i to 5, characterized in that the train means (73) of a coil (75) is continuously removed, and that a knife set (149, 150) is set in motion by the machine to the Separate hood wound piece of the tension member (73) from the part of the tension member connected to the coil. 7. Machine according to claim i to 6, characterized in that the supply, clamping and winding devices for pulling around the hood by the pulling means for liquefying the binding agent, for separating the pulling member, etc. are at a distance from each other, whereby the bottle support ( 9) is movably arranged with respect to these devices. B. machine after. Claim 7, characterized in that the bottle support (9) is raised and lowered during its movement with respect to the devices for `` wrapping the hood with the binding agent and for liquefying the binding agent, the movement from job to job being essentially horizontal Level.