DE440513C - Mold for caliber rolls composed of individual, ring-shaped parts and held together with releasable clamping devices - Google Patents

Description

Composed of individual, ring-shaped parts and with releasable Clamping means held together mold for grooved rolls. The invention relates to a mold for the production of grooved rolls, straightening rolls. Roles or similar calibrated round bodies.

There are molds for this purpose known, which consist of individual, ring-shaped There are parts that interlock - and by claws or the like. During the casting be held in their position, but when the visual curl occurs by lowering the Ring carrier or released by swiveling them out so that they shrink can follow the roller. The mold parts are unlocked from here Hand, so that very often the right moment of unlocking is missed, as a result of which the roller cannot shrink freely and even tear into several parts.

The invention is based on the fact that the visual curl during and immediately after solidification, the cast iron is preceded by expansion by the precipitation of graphite, which has a very low specific weight, an increase in volume takes place. This increase in volume results in a strong increase Buoyancy of the iron, with a slight axial movement of the mold parts itself takes place.

According to the invention, the earlier drawbacks will be eliminated and the latter cited fact used to be the right time for real relaxation to automatically determine the mold or to carry out the relaxation.

The mold also consists in a known manner of individual, one on top of the other, calibrated individual molds, which are centrally positioned by means of inserted or folded rings or bands are held and guided with each other, while perpendicular between two mold parts Clamping devices are housed, the clamping capacity of which can be of different sizes, to enable precise adjustment of the mold parts.

The clamping devices are equipped with devices for a quick and safe solution the mold to prevent the cast body from shrinking, according to the invention, it is triggered during the expansion period due to the associated movement of the mold in a semi-automatic or fully automatic manner Way. By means of the invention, caliber rolls of the greatest accuracy can be reliably achieved produce.

The invention is illustrated by way of example in the drawings.

Fig. I shows a vertical section through a mold according to the Invention.

Fig. 2 shows part of the mold according to .- 'lbb. t with the relaxation device in external view and an electrical alarm device.

Fig.3 shows a vertical section through a clamping bolt of the Clamping device of fig. I and 2.

Figures 4, 5, 6, 7, 8, 9, 1o and 1i show different designs of clamping devices. Fig. 12 shows a view of a mold with an electric-automatic Relaxation device.

Fig. 13 also shows a view of a mold with electromagnetic Relaxation device.

Fig. 14 shows a top view of an electromagnet according to Fig. 13.

Fig. 15 shows, partly in view, partly in section, the arrangement of a hydraulic or pneumatic relaxation device.

Fig. 16 shows part of the mold, partly in view and partly in section with attached mechanical-electrical relaxation device.

Fig. 17 shows a view of several mold parts placed one on top of the other with built-in clamping devices.

Fig. 18 shows, on a larger scale, a vertical section through the clamping device in Fig. 17.

Fig. 1g shows a top view of Fig. 17. Fig. 2o shows in section another version of a clamping device according to the type of Fig. 17.

Fig. 21 shows a view of a mechanical relaxation device Type of electromagnetic relaxation device of Fig. 13.

Ahl). : 22 shows a section through the relaxation device according to FIG the line 22-22 of Fig. 21.

Fig.23 shows a mold with only one single force element, which at the same time solves all mold parts.

Fig. 24 shows a section along the line 24-24 in Fig. 23.

Fig. 25 and 26 show the clamping device of Fig. Z3 in two views. The mold shown in Fig. I consists of the upper pin mold part i, the calibrated hardness mold 2 and the lower tenon mold box 3. The hardness mold 2 is divided several times horizontally and vertically in a known manner in order to avoid the shrinkage movement to be able to follow a freshly cast roller. For this purpose are also known clearances 4 created between the individual parts of the hardening mold. These margins are according to the invention by means of movable clamping means 5, such as Eccentric bolts, wedge screw bolts, clamping wedges, clamping clamps or the like. Manufactured. The clamping means should act between two mold parts in such a way that the lower one Mold part serves as a base for the next one.

In order to ensure simple and cheap manufacture of the hardening mold, the surfaces of the subdivisions 4. are perfectly flat. The parts can therefore without Machining can be used as a raw casting. Only the vertical subdivisions of the mold parts are to be smoothed a little using grinding wheels or the like. To the butt joints 4 against To secure penetrating iron, the mold parts with undercuts or Recesses 6 provided, in which a sand seal or most appropriate a Oil core insert 7 is introduced. The recesses 6 are funnel-shaped towards the outside, whereby the core insert 7 is given the possibility of the shrinkage movement Dodge mold members and buckle after the free space 8 or in this to enter. This sand seal or oil core can be used depending on the type of roll calibration very 'wide or very narrow, as they do not put any strain on them exposed through the mold parts.

When setting up the mold, the clamping means 5 are adjusted according to the caliber division. Inequalities can be compensated for by fine adjustments in all clamping devices that are used. The clamping means 5 are held in the given position by special devices. These devices consist of the transmission rods g (Fig. 1, 2, 5, 6, 9, 10, 11, 12, 15, 17, 19 and 21) which are held in position and carried by a lock io. The lock io is expediently attached to the upper tenon mold box i so that it can be used for a large number of hardness molds in which the same tenon shape is used.

The lock can have all possible designs. the Example drawn version consists of one riii "b um the cone shape i laid, freely movable on rollers z i, but otherwise well guided Ring i o. The transmission rods 9 to be held, which ride, rest on the ring io Castors 12 and weights 13 are provided.

If the mold is to be relieved, the locking mechanism (Fig. 2) rotated to the right by means of a Heroel 14, whereupon the transmission rods 9 fall down due to their own weight and the loading weight 13, wohei by transferring levers 15 (fig. 1, 2) or cogwheels 15 (fig. q. to 61 a solution to the. Clamping device takes place. The downward movement of the rods 9 is limited by buffer 16 (Fig. 1, 2). Instead of the loading weight, a Tension or compression spring or a similar aid can be used.

The locking mechanism ensures that the downward movement starts smoothly Drain tongues 17 (Fig. 2), over which the roller 12 of the rods 9 when moving gradually from -, # slides forward.

Abli. 3 to ii show details of variously designed mold parts with clamping means. The clamping means according to Fig. 3 consists of an oval or eccentrically rotated bolt 18 which acts between the mold parts by means of two spaiinsclieil) eii 19.

Ahb..t and 5 show a mold according to the invention, whereby the clamping means consist of conical tensioning screws 2o, «-elche with a cord thread of strong Slope are provided. The two-part spring washers 21- also have a cord thread, but do not sit, as in Fig. 3, in the mold parts themselves, but in one each conical collar 22 and 23. The mold parts 24. are on the two wings also conical, which saves a considerable amount of weight by the adjusting rings are used for similar roll diameters for all molds «-Be able to earth.

The clamping means 2o carry spur gears 1 5, which are brought into rotation by lowering the rod 9 (Fig. 5) and cause the mold parts to relax. Toothed racks and cogs are optimally guided and set up in this way. that they never get out of engagement even with a larger advance of the spam screws. Without changing your basic idea, the spur gears could also carry the thread and the conical part of the bolt could be kept smooth. Here, the spur wheel would act as a nut on your threaded part of the bolt located outside the mold, which, set in rotation, would pull out the smooth bolt between the mold parts. Instead of the round shape, the conical bolt part which carries the mold parts could then also have a square, triangular or other shape.

The mold according to Figs. 6, 7 and 8 has clamping means, which from several wedge pieces are formed. The wedge 26 (Fig.8) lies in your lower one Mold part firmly. The wedge 27 is displaceable with play in the above following mold part used and is by the wedge 28 in its position held. On the wedge piece 28 sits a gearwheel 1 5 with an eccentric bore, in which the transmission rod 9 engages. When the rod 9 is lowered, this becomes Wheel 15 brought into rotation, the wedge piece due to its eccentricity 28 is pulled out. As a result, the = wedge piece 27 is free and can the shrinkage movement evade.

The clamping devices according to Fig. 9 consist of the transmission rods 9, the levers 15, the two double wedge pieces 29 and 30, which are used for fine adjustment serve, as well as the clamping block 31. The latter can be a counterweight for a better effect 32 own. The clamping devices according to Fig. 10 are similar to those in Fig. 9, only that instead of the double wedges here a roller, ball or an eccentric pin 33 for Application comes. In Fig. I i the clamping block 31 is designed with a joint 3.I. In the last three versions, the relaxation is also done by lowering the rod 9, whereupon the clamping means evade and release the mold parts.

The mold parts earth with one another by means of rings 35 inserted (Fig. Io) or by folded, slightly flexible iron strips 36 (Fig. 2 and 16) and centered. These iron bands can be composed of several parts and form a ring. This is how the individual parts of the bands fit all types of molds, whatever their diameter. The bands 36 have Openings 37 (Fig. 16) through which the clamping devices are inserted, as well as Holes 38 for the escape of gases that may be produced during casting. The dwindling movement is not hindered by the bands, while the hardening mold is built up by whose application is very simplified. It is also not necessary to have the tapes the mold parts completely enclose the outside, it is rather sufficient if individual opposite points of the mold are held, z. B. three to four, so that the central structure is guaranteed.

It is also suggested to use simple centering tabs for small and medium-sized molds, possibly also with wedge or screw regulation, or similar means A, (Fig. 2 and 12). Each following mold part is centered on the previous one. This measure, too, represents a significant simplification for the production of the molds and contributes to the same extent to making the rollers cheaper.

To find the right time after the roll casting has been completed the relaxation of the mold must be made for the shrinkage movement, sure To meet, the mold is connected to an electrical bell according to the invention. In Fig. 2, such a system is associated with the mold. In the In practice you will of course have such a signal system next to the casting pit at the Attach a wall or the like to be secured against damage.

According to the invention, this device is used to determine the time to determine for the relaxation of the mold or to carry out the relaxation. So the important work of relaxation should no longer be of the attention the caster depend. For this purpose one connects the upper pin shape z with the Contact 39 of an electrical bell 40 (Fig. 2). When the expansion of the Casting in appearance, the upper one also moves in a corresponding manner Pin shape r and closes by touching the contact piece 39 with one above located, adjustable and resiliently arranged contact flap 41 the circuit, whereupon the bell sounds and indicates that the tensioning means are relieved, so that a solution of the same can take place easily and safely. The solution is made immediately when the bell rings, as described earlier.

Instead of the bell, any other signal, such as steam or Compressed air signals, light signals or possibly a bell signal in conjunction with one Light signal, etc., can be applied.

The expansion of the cast iron and the movement it causes according to the invention, the mold becomes completely automatic relaxation the mold used before the start of the visual curvature. Fig. 12 shows such a mold in view. The relaxation of the hardness mold. 2 is done by electromagnets q2, which are adjustable on a common base plate q.3, and their Arrangement is set up for a range of roller sizes. The magnetic shafts q4. are connected to the transmission rods c) by means of joints q.5. As with the electric The alarm device according to Fig. 2 is also here with the upper pin shape r a contact socket 46 connected. This is when expansion or upward movement occurs a weak current circuit through contact with the contact piece q.7, which is also inserted in a flexible manner closed, whereby in an intermediate relay 48 by the magnet 49 an anchor is tightened like this. The anchor So carries carbon pins 51, which in the Immerse contact sleeves 52 half-filled with mercury. This creates the magnetic circuit closed, and the magnets 42 attract instantly, with the hardening mold is relaxed.

During the downward movement of the magnets, the driver 53 of the Weak circuit interrupted by tearing out the lever switch 54, whereby the magnet 49, de-energized, releases the armature So and thereby also the high-voltage circuit for the magnets 42 is interrupted again. The stroke of the magnets used is sufficient in special cases not off, so between the joints 45 and the magnetic shafts 44 an angle lever transmission is attached, which increases the solenoid stroke by several times can transfer. The contact piece 46 is adjustable in such a way that it is for each stroke movement the mold can be adjusted. This lifting movement is caused by the load Mold limited by weights to a minimum so that no damage to the casting can occur.

In Fig. 13 the same mold is shown on the left with directly acting electromagnets 55, each of which relaxes a mold part. On the other hand, an electromagnet 56 is drawn on the right-hand side, which relaxes all mold parts at the same time. The tensioning means 57 provided with a hammer head are mounted in a continuous hammer head groove (Fig. 1q.) On the protruding part 58 of the magnetic core so that they can be moved vertically and easily adapt to each mold pitch. The part 57 used for tensioning the mold is designed as a truncated cone or wedge, whereby on the one hand the relaxation is easy and on the other hand sufficient tension is available. The actuation of the electromagnets and relaxation of the mold happens in a similar way to that shown in Fig. 12.

Instead of the automatic, electromagnetic relaxation, it can also take place by means of pressurized water, steam, compressed air or other compressed gases. In Fig. 15 such a device is shown for example. The propellant arriving at 59 enters the lines 6ö and 61 and through the valve 62 into the valve chamber 63. The punch 64 attached to the upper pin shape i presses the punch 64 against the valve rod 65 through d = e expansion movement of the upper pin shape, whereby the valve 66 is lifted from its seat and the propellant flows through the connecting piece 67 to the small cylinder 68. Here the piston 69 is driven upwards, at the same time opening the valve 70 to the main cylinder 71 for the relaxation of the mold parts. The piston in the cylinder 71 is driven downward by the inflowing drive means, thereby causing the movement for the relaxation of the mold parts.

Fig.16 shows a device for an automatic mechanical and a mechanical-electrical relaxation of the mold parts. The one on a pillar 72 constructed clamping and Eiitspaiinungsvorrichtung consists of the housing 73, your slide 74 movable in the housing and the pawl 75. The slide 74 engages with the lever 14 to the lock 1o by means of rotatable bolts 76 (see also Fig. I and 2).

A hand crank is used to bring the device into operating condition the pinion 77 rotated back. then at the same time the slide 74 is pushed back so far until the pawl 75 falls into a recess 78 made on the slide 74. By pushing back the slide, a spring 7 9 is tensioned, which in this Condition against the rear wall of the housing 7 3 and against a seated on the slide Bunch 8o presses. A punch 64 fastened to the upper pin shape i engages with it Play in the housing 73 presses against the pawl as the mold moves upwards 75 and loves this out of the recess 78. This causes the slide 74 free, moves forward under the pressure of the tensioned spring 79 and pushes here the lock 1o in front of you. By moving the lock 1o if the transmission rods g are free, they sink, as described in fig. i and 2, downwards and bring about the relaxation of the mold parts.

About the sinking of the transmission levels and the safe relaxation To ensure the mold in every way can still have electromagnets on each Transmission rods act as shown in Fig. 12. Just need it too two or only a single magnet to act, which has a corresponding. Lever connection is connected to the transmission rods. The circuit of the or the magnet takes place - through at the left end of the slide; .4 and at the gel housing 73 connected power contacts 81 and 82. The power interruption then takes place äh-ilich as in Fig. 12 at 54.

Fig. 17, 18 and 19 show a special version of a clamping device with multiple-acting clamping means. Here, for an entire mold, only a single transmission rod 9 or a single force element 42 or 71 is necessary for the relaxation - "= end. The transmission rod 9 has adjustable Ouerhäup'er 83, which have elongated holes on both sides in which the lever 15 can slide. Fig. 18 shows a section through the clamping device on a larger scale. The clamping bolt 86 is mounted between the two clamping disks 84 and 85. The bolt 86 has recesses 87 and 88 on the lower side, into which wedges 89 (Fig. 18 and 1g) are inserted. These wedges form the clamping device. Is to take place the relaxation, so DER bolt 86 is rotated by means of the lever 1 5, in this case, the cutting circulated go, which is exactly on the central axis of the bolt itself, on the stretcher as a support, whereby the batch 9i of the bolt the wedge the recess pushes out. The clearance 92 located between the tensioning disk and the bolt is thereby released and enables the shrinkage movement. The tension washers are not absolutely necessary, the bolt 86 can also be stored directly between the mold parts.

Fig. 2o shows a similar clamping device for a mold according to Fig. 17 to i9. The relaxation is done by means of two wedges 93, which by a Screw spindle 94, which has right-hand and left-hand threads, is shifted.

A special mechanical relaxation device is also shown in Figures 21 and 22. The basic idea here is exactly the same as shown in Fig. 13 and 14 under 56. Instead of electromagnetic relaxation, a mechanical one should take place here. The clamping means 57 are likewise conical or trapezoidal clamping bolts which are inserted with a hammer head into a corresponding groove of the V-shaped slide 95 . The slide 95 takes the place of the electromagnet and is guided in elongated holes 96 of the carrier 97. The outward movement to relax the mold parts is brought about by the wedge pieces 9g attached to the tie rod 98, in that the wedge pieces 99 press against the rollers located on the slide 95 during the downward movement. Corresponding to the downward movement of the pull rod 98 , the slide moves laterally and relaxes the mold members. The pull rod 98 is supported against the carrier 97.

Fig. 23 and 24 show a mold with a relaxation device according to the type of Fig. 13. Here only the relaxation elements are attached to the lower pin mold box 3. The tendons ioi consist of clamps with heavily sloping wings 57, as shown in Fig. 13. The inevitable removal of the tendons is done by levers io2, which are articulated to the tendons ioi: The levers io2 are adjustable on the transmission rods 9 so that they can be adapted to any mold pitch as desired. The mold is relaxed by a force element such as an electromagnet, compressed air cylinder, compressed water cylinder or the like, in the manner described in Fig. 12, 13, 15 or 16. The force element 103 acts with the drive rod 104 on a transmission element io5, which is connected to a multi-part ring io6 that is well guided around the pin shape 3. Tooth segments 107, which are in engagement with the toothed wheel 15, are fastened on the ring io6. The lifting movement of the drive rod 104 causes the ring loh to rotate, the toothed wheels 15 seated on the transmission rods 9 causing the rods 9 to rotate. As a result, the clamping means connected to the levers in a red movable manner are pulled out between the mold parts. The mold is released and can follow the shrinking movement unhindered.

Instead of the transmission by means of tooth segments io7 to the gear wheels 15 lever transfers or other means can also be used.

A lever io8 placed on the transmission rod 9, in Fig. 23 dotted top right, indicates that the relaxation is also done by hand can be accomplished, the transmission to all by means of the ring IO6 Rods 9 takes place. This arrangement is a valuable addition to the automatic Relaxation by, in the event of a sudden absence of the power means, e.g. B. of the electric current, despite the fact that the relaxation can be carried out. Of course can, without changing anything in the invention, also each individual transmission rod 9 obtained a lever io8 or similar means, so that the relaxation by several People can take place at the same time.

To the clamping means ioi slightly out of their positions when relaxing to remove, these are strongly conical, for example as truncated wedges, the mold parts 2 also have the same bevel as the clamping means. This bevel can be over the entire circumference of the mold part or only on Parts of the scope be made. Instead of beveling the clamping device on both sides, it would also suffice if these were beveled on one side, with the straight Side slides on the lower part of the mold when pulling it out. The strongly conical Clamping devices also have the purpose of a certain fine adjustment of the mold parts to ensure each other.

All drawn and described clamping devices are between the mold members installed themselves. Of course, you let yourself be without the idea of the present invention to change something, just as well outside attach the mold parts if z. B. approaches or projections on the mold parts be attached, be it by casting or artificial fastening, between which then the clamping devices are introduced.

Likewise, without changing anything in the invention, those described can also be used Instead of working completely automatically, devices are also operated in this way, that z. B. when the alarm bell sounds by hand, the electromagnetic, hydraulic or pneumatic relaxation is activated. The Details of the various facilities described in a different combination use. So z. B. the valve 7o of Fig. 15 instead of steam, compressed water, compressed air o. The like. Are operated by electromagnets.

Claims (3)

P.ITEIGTA \ PROVERBS: i. Assembled from individual, ring-shaped parts and mold for caliber rolls held together with releasable clamping means, thereby characterized in that by the forces of the buoyant at the onset of solidification Iron masses and the resulting movement of the mold elements in Activity are offset, which in the vertical direction between each two mold parts introduced clamping devices of different clamping capacities for the purpose of the possibility of shrinkage solve in a semi or fully automatic manner or initiate the solution, whereby the calibrated mold parts by means of inserted or folded rings, bands, centering tabs or similar means are held and managed centrally among one another. 2. Mold for caliber rolls according to claim i x, characterized in that the mold parts at the subdivision joints (q.) undercuts or recess part (-) have, which run out to the outside in a trich: Erförinige expansion (8) in such a way, that a seal (,;) inserted into the recess (6) when the shrinkage movement occurs buckle and move into the funnel-shaped expansion (S). 3. Mold for caliber rolls according to claims i and 2, characterized in that the clamping means consist of oval or eccentrically rotated bolts (18) which are movably seated in split clamping disks (i9). 4 .. Mold for caliber rolls according to claims i and 2, characterized in that the clamping means consist of conical screws (2o) which are screwed into the screw-shaped, threaded clamping disks (21), the clamping disks between two rings (22 and 23) sit, the surfaces of which carry the mold parts. 5. Mold according to claims i and 2, characterized in that the clamping means consist of conical or wedge-shaped pins or bolts which carry thread on the part protruding outside the mold, on which a toothed wheel designed as a threaded nut (15) sits, which , set in rotation, pulls out the pin or bolt between the mold parts. 6. Mold for Kaliberwalzeu according to claims i and 2, characterized in that the clamping means consist of several wedges (26, 27 and 28), such that the wedge (27) is held or released in its position by the wedge (28) The solution takes place by means of toothed wheels (15) seated eccentrically on the wedge (28) and by lowering the toothed rack (9). 7. Mold for caliber rolls according to Claims i and a, characterized in that the clamping means consist of clamping blocks (3i) which can have a counterweight (32) for better action and with means for fine adjustment and for easier loosening, such as wedges (29 , 30), rollers, balls or eccentric bolts (33), joints (34) or the like., Are provided. G:. Mold for caliber rolls according to Claims 1 to 7, characterized. that the mold has a lock (io) for the semi or fully automatic release of all clamping means, which, full of rollers (ii) .boben, is guided in a ring around the upper pin shape (i) and provided with sliding tabs (17) for the transmission rods (9) is, whereby by shifting or turning, ler locking all of her locked transmission rods (9) become free at the same time and sink down with the help of a weight (13), a tension or compression spring or other means of force and thereby by moving the clamping means bring about relaxation of the mold. 9. Mold for haliberwalzen according to claims i to 8, characterized in that the correct moment for the relaxation = tension of the mold is determined in that an upper part of the mold is connected to the contact of an alarm device in such a way that at the beginning of the expansion or buoyancy period of the iron due to the movement of the mold an electric bell or other signaling device comes into operation. ok Chill mold for caliber rolls according to claims i to 9, characterized in that the chill mold is relieved by means of electromagnets (42) built on a common base plate (43) by opening the magnetic circuit during the iron's buoyancy period through a relay (48) the contact (46) attached to the upper pin mold part (i) is closed, whereby when the magnets (42) are attracted, the transmission rods (9), which are articulated to the magnet shafts and are connected to increase the stroke by means of angle levers, are moved downwards and the mold is relaxed while at the same time during the downward movement the circuit is interrupted again by tearing out the switching lever (54) or similar suitable means. i i. Mold for Kaliberwalzeli according to claims i to io, characterized in that the relaxation of the mold takes place by laterally front-mounted electromagnets (55 or 56) in such a way that the clamping means (57) are removed from their positions individually or jointly by the magnets. 12. Mold for caliber rolls according to claims i to ii, characterized in that the relaxation of the mold is carried out by means of steam, press water, compressed air or similar force means by means of steam, press water, press air or similar force means built on a common base plate or by laterally pre-built force elements During the buoyancy period of the iron, a pressure ram (64) built on the upper pin shape presses against the cone of a gate valve (66) and opens it, whereby the power medium flows under the piston of a small cylinder (68), the piston of which lifts and thereby the inlet valve (70 ) opens for the power medium, which flows to the main cylinder (71), drives the piston down or forward and relaxes the mold. 13. Mold for caliber rolls according to claims ii and 12, characterized in that the clamping means for the laterally built-in force organs (Figs continuous vertical grooves (58) of the force elements (56) are inserted displaceably. 14. Mold for caliber rolls according to the claims. i to 13, characterized in that the semi or fully automatic relaxation of the mold takes place only by a single force element with the application of a corresponding lever connection, '-, almost all of the tendons are connected to one another. 15. Mold for caliber rolls according to claims i to 9, characterized in that the mold is relaxed by an automatic, mechanical device (Fig. 16) by a stamp (64) attached to the mold against a pawl during the buoyancy period (75) and lifts it out of its position, a slide (74) under spring pressure in a housing is moved forward and shifts the lock (io), as a result of which the transmission rods (9) are free and the relaxation takes place. 16. Mold for Kaliberwalzen'nach.den claims io and 14,. Characterized in that the slide (74) and the housing (73) each carry an electrical contact (81 and 82) which against the end stroke of the slide .ein circuit for - Close actuation of electromagnets, which serve as an aid and as a safeguard for complete relaxation of the mold. 17. Mold for caliber rolls according to claims i, 2, 8, 9, 10, 12; 14 and 15, characterized in that the tensioning or final tensioning of the mold is carried out by multi-acting tensioning means (Figs. 17 to 20), which are actuated simultaneously by means of only a single transmission rod (83) provided with adjustable heads (83) or similar means ( 9) happens. 18. Mold for caliber rolls according to claim 16, characterized in that; that the multi-acting clamping means consist of round bolts (86), each of which has two recesses (87) into which clamping wedges (89) are inserted in such a way that the bolts rest on the clamping wedges and the wedges when the mold is relaxed by rotating the bolts by means of the shoulders (9i) delimiting the recesses (87) are pushed out of their position, thereby releasing a clearance (22) located between the bolt and the clamping disk and enabling the shrinkage movement. i9. Mold for caliber rolls according to claims r, 2, 3, 9, 1o, 11, 13, -14 and i 5, characterized in that levers (io2) adjustable on the transmission rods (9) to relax the mold the tendons (ioi) are articulated, the solution of which takes place by means of a .Kraftorgans (1o3), which is provided with toothed segments (1o7); centrally guided ring-shaped part (lös; io6) 'engages by tightening the drive rod (1o4) the part (raw) executes a movement, -which by means of toothed segment (1o7) and gears (15) or similar means on the transmission rods (9) is guided, whereby the clamping means (ioi) are pulled out of their positions by the levers (io2) and thus release the mold parts. 2o. Chill mold for caliber rolls according to claims i to i9, characterized in that the chill mold has an emergency release so that the clamping means when the power means, e.g. B. the electric current, by lever (io8) or similar means of Ha-id can be released, the levers (tob) being connected to the transmission rods (9). 21. Mold for caliber rolls according to claim i9 and 2o, characterized in that the mold parts at least on one side on the bearing surfaces or the seat (io9) of the clamping means (ioi) are strongly beveled, the bevel (io9) over the entire circumference the mold or only on parts of the circumference, whereby every desired fine adjustment is achieved and an easy .Llös- der clamping device is achieved.