EP0052292A1 - Process and device for advancing a slidable shuttering - Google Patents

Abstract

The method for driving a sliding formwork with a formwork body (5, 6) extending in the longitudinal direction of a tunnel or tunnel, a front formwork (20) that closes the front, and a supporting structure (7) consists in firstly at least in the ceiling area of the tunnel or tunnel Parts of the formwork body that are to be backfilled with liquid concrete and the parts of the formwork body that are in contact with concrete that has not yet hardened are rigidly supported on the support structure and that after sufficient hardening of the concrete, the formwork body is elastically supported on the support structure becomes. For this purpose, both rigid (11) and elastic (12) transmission links between the formwork body (5, 6) and support structure (7) are arranged to act in parallel to one another, while a switchover device is provided with which either the rigid or the elastic transmission links are put into operation can be.

Description

The invention relates to a method for driving a sliding formwork when expanding a tunnel or tunnel according to the type laid down in the preamble of claim 1, and an apparatus for performing this method.

In the previously known methods of this type, a rigid formwork body consisting of formwork skin and stiffeners is advanced by means of hydraulic presses which are supported against holding devices which are clamped in the past, already switched off concrete lining of the tunnel or tunnel. It is in principle desirable to perform this propulsion of the sliding formwork as continuously as possible with a speed which is adapted to the curing rate of the filled in the annulus between the Ausbruchswandung the tunnel _'and an attached there outer formwork and the formwork facing the sliding formwork and pressed concrete.

The front of the annular space just mentioned is closed with a front formwork which forms part of the slide formwork, which as a rule moves with the slide formwork, but can be moved forward with respect to the rest of the slide formwork alone to introduce reinforcements if necessary.

A continuously advancing sliding formwork must have at least such an axial length that the in-situ concrete coming to the formwork at its rear end has reached sufficient strength to be able to absorb the pressure of the surrounding soil exerted on it from the outside at least for a short time, that is, until it is supported by a support formwork installed behind the sliding formwork, which has been installed for so long remains until the concrete has reached its final resilience.

This means that the sliding formwork to be driven as a quasi-one-piece body must be moved at least in its rear area inside a ring made of in-situ concrete that is already hardened to such an extent that it behaves as an inelastic, rigid body. Since the inner diameter or the clear width of this rigid concrete ring zone is subject to certain manufacturing tolerances, high constraining forces can arise when the sliding formwork is pushed forward, since the concrete can no longer deflect. These forces can lead to cracking and breaking in the in-situ concrete. The same applies to the constraining forces that occur when the sliding formwork, which is relatively long in the axial direction, has to be advanced through a tunnel or tunnel section with a curved longitudinal axis.

These problems, which already arise with the continuous advancement of the sliding formwork, are exacerbated when the forward movement of the sliding formwork comes to a standstill or stops. In these cases, it can happen that the sliding formwork cannot be advanced until the entire concrete in contact with it has hardened to such an extent that when the sliding formwork is restarted it no longer plastically or elastically exerts the forces exerted by it can yield, but on the other hand, at least in its foremost parts, is not yet firm enough to absorb only the forces acting from the outside. Removing the slipform in this state is therefore not permitted and it is necessary to continue the concreting work, the slipform from it given position to start moving again. In addition to the constraining forces that may occur over the entire length of the sliding formwork and thus increased constraining forces, there are also the adhesive stresses that exist between the hardened concrete and the formwork skin, so that in these cases there is a greatly increased risk of cracking or breaking of the in-situ concrete consists.

In contrast, the invention has for its object to provide a method of the type mentioned and an apparatus for performing this method, in which the risk of damage to the concrete lining the tunnel or tunnel due to occurring between these concrete and the sliding formwork when moving the sliding formwork Forces are largely reduced.

To achieve this object, the invention provides the features set out in claim 1 (method) or in claim 7 (device).

These measures ensure that the formwork body wherever it has to be positioned very precisely in order to achieve small manufacturing tolerances, i.e. So in the area where the in-situ concrete is just being poured or is still liquid or only very little hardened, it can be supported in a rigid manner, so that the absorption of very high forces is possible here without a deviation of the position of the formlining from the desired position becomes. Coercive forces between the concrete and the formlining cannot yet occur in these areas, since the concrete can easily give way here.

In contrast, in areas in which the concrete has already hardened to such an extent that it cannot yield plastically or elastically from the forces exerted by the sliding formwork during driving, in which there is therefore a risk of cracking or breaking of the concrete, the formwork body is replaced by an appropriate one Support with the help of the elastic instead of the rigid transmission links on the support structure so that it still absorbs the high forces exerted on it by the concrete, which is not yet load-bearing and by the soil surrounding it, but only when due to the occurrence of constraints or adhesive tensions, these forces can exceed a predetermined level, yield in an elastic manner and thus avoid excessive stress on the rigid, fragile concrete.

Particular advantages of the method according to the invention can be seen in the fact that it can be carried out with very little technical effort and that it considerably facilitates driving through tunnel or tunnel sections with a curved longitudinal axis because of the avoidance or substantial reduction in the constraining forces between concrete and sliding formwork .

The method according to the invention can advantageously be used with two fundamentally different types of advance of the sliding formwork, namely both with continuous and with discontinuous advance.

In the first case, the front parts of the formwork body, which constantly migrate with the zone of the still liquid or uncured concrete, are practically constantly rigidly supported, while the rear areas, which are constantly solidified by one Concrete ring are surrounded, continuously rest on the support structure via the elastic transmission links. In theory, one could do without the elastic transmission elements in the front area of the sliding formwork and the rigid transmission elements in the rear area. However, this will generally not be expedient, since it must always be expected that the sliding formwork will come to a standstill for a long time and then have to be started again, which then corresponds to a discontinuous feed operation.

In this second case, the entire sliding formwork can initially be rigidly supported; the transition to elastic support takes place over the entire length of the sliding formwork, either simultaneously or gradually, when the concrete adjacent to the respective areas has achieved sufficient strength.

Advantageously, in areas in which the concrete has already solidified, elastic support is switched to at the latest when the sliding formwork to be set in motion is to be set in motion again.

According to claim 5, a good criterion for switching from rigid to elastic support is given by the time at which the concrete has reached its so-called green stability in the area in question. This is the strength at which the freshly cast vault can not yet take over the existing loads in a self-supporting manner, but is nevertheless so firm that the slip formwork can be temporarily removed and replaced by a subsequent supporting formwork.

At this stage, it is also possible according to the invention, if the formwork body is subdivided into segments lying next to one another in the circumferential direction, for a short time to lift off individual segments from the concrete and to inject them with a lubricant, to further reduce the adhesive stresses between the sliding formwork and the hardened concrete .

Another considerable risk of damage to the cast concrete lining of a tunnel or tunnel arises in the conventional tunneling method for a sliding formwork in that the forces required for advancing the formwork are applied by hydraulic presses which are supported on abutments which are just finished Concrete lining to be clamped. This anchoring is more or less punctiform, so that very high reaction pressures have to be taken up at these points by the concrete lining, which can lead to cracking or similar damage to the concrete.

In order to eliminate this risk in the context of the object on which the invention is based, it is provided according to claim 6 that the sliding formwork is advanced by the pressure of the concrete pressed in behind the front formwork. The entire already hardened concrete lining serves as an abutment, over the circumference of which the reaction forces attack very evenly, so that the local pressure loads remain relatively low. Damage to the already hardened concrete lining is impossible with this procedure.

A particular advantage of this type of jacking can be seen in the fact that they are pressed to a very good and uniform compression of the formwork behind the forehead liquid concrete.

So that the pressure required to generate the driving forces can build up behind the end formwork, a sealing device is provided according to claim 12 between the outer peripheral edge of the end formwork and the excavation wall of the tunnel or tunnel or an outer formwork attached there; which, in order to avoid a pressure loss and excessive wear during the continuous advancement of the sliding formwork according to claim 13, consists of at least two sealing elements arranged one behind the other in the direction of advance, one of which is always pressed against the wall of the excavation and is within its inherent elasticity due to the forward movement of the face formwork deformed, while the or the other sealing elements move freely with the face formwork without deformation. Is the currently the sealing function of exerting sealing element as far deformed so that it at a substantially further relative movement between its integral with the front shuttering radial inner side and its firmly pressed against the Ausbruchswandung radial outside beginni ^g en would entlangzureiben with this outer side of the Ausbruchswandung, then the other or one of the other previously undeformed sealing elements pressed against the breakout wall, so that it takes over the sealing function, while the previously pressed sealing element is withdrawn from the breakout wall, so that it can move back into its undeformed position.

In this way, a pressure-tight seal for the one behind the front formwork between the excavation can always be provided even in the case of a front formwork that moves continuously forward with the entire sliding formwork Wall and the formwork of the slip formwork enclosed ring space are maintained without any sealing elements slide along the excavation wall or the outer formwork.

Advantageously, the sealing elements are formed by hoses extending with their longitudinal axis in the direction of the circumference of the front formwork, which can be pressed against the wall of the excavation by increasing their internal pressure and can be withdrawn from the wall of the excavation by lowering this internal pressure.

In order to ensure a large-area connection of these hoses both to the peripheral edge of the face formwork and to the wall of the excavation, these hoses advantageously have a rectangular profile when viewed in radial section.

It should be expressly pointed out that this type of advance of the sliding formwork can also be carried out when the formwork body of the sliding formwork cannot be supported on the supporting structure in a rigid as well as elastic manner.

• Fig. 1 in schematisierter Weise in ihrer linken Hälfte einen Querschnitt durch einen Tunnel mit kreisförmigem Profil und in ihrer rechten Hälfte einen Querschnitt durch einen Tunnel mit rechteckigem Profil, wobei jeweils im Inneren des Tunnels eine erfindungsgemäße Gleitschalung angeordnet ist,
• Fig. 2 einen Längsschnitt durch einen Stollen bzw. Tunnel mit einer erfindungsgemäßen Gleitschalung,
• Fig. 3 ein Detail aus Fig. 2, wobei ein in der gleichen Richtung verlaufender Schnitt durch eine an der Umfangskante der Stirnschalung angeordnete Dichtvorrichtung gemäß der Erfindung wiedergegeben ist, und
• Fig. 4 eine weitere Möglichkeit der erfindungsgemäßen Ausbildung von starren und elastischen Übertragungsgliedern.

The invention is described below using exemplary embodiments with reference to the drawing; in this shows:

• 1 in a schematic manner in its left half a cross section through a tunnel with a circular profile and in its right half a cross section through a tunnel with a rectangular profile, wherein a sliding formwork according to the invention is arranged in each case inside the tunnel,
• 2 shows a longitudinal section through a tunnel or tunnel with a sliding formwork according to the invention,
• 3 shows a detail from FIG. 2, a section running in the same direction being reproduced by a sealing device according to the invention arranged on the peripheral edge of the end formwork, and
• Fig. 4 shows another possibility of the formation of rigid and elastic transmission members according to the invention.

In the case of the sliding formwork 2 shown in FIG. 1, which is arranged inside a tunnel or gallery 1, the actual formwork body consists of a formlining 5 lying against the concrete 4 and stiffeners or formwork elements 6 which act on the relatively thin formwork facing to accommodate those from the outside Give the required rigidity to the forces.

To support the formwork body formed by the formlining 5 and bracing 6, a support structure 7 is provided in the interior of the tunnel or tunnel, which in the present example is formed from individual annular support elements 8 spaced apart in the longitudinal direction, the shape of which is adapted in the transverse direction to the shape of the tunnel profile is. In the longitudinal direction, these support elements 8 are rigidly connected to one another by guide bars 9, which are designed as hollow profiles with a rectangular inner cross section.

The transmission of the forces exerted on the formwork body 5 consisting of formlining 5 and stiffeners 6 from the outside by the load of the concrete 4 and the soil surrounding them from outside to the support elements 8 are groups of between the stiffeners 6 and the support elements 8 at suitable locations Transfer elements 11 and 12 are arranged, each of these groups comprising at least one transmission element 11 which transmits the forces from the associated stiffening 6 to the respective support element 8 in operation in a rigid manner and in parallel thereto at least one transmission element 12 which transmits these forces in operation in an elastic manner.

In the exemplary embodiment shown in FIGS. 1 and 2, the rigid transmission members 11 are formed by hydraulic pistons or presses which, viewed in the transverse direction of the tunnel, are each arranged between two rubber-silicon blocks forming the elastic transmission members 12. The dimensions of the rubber-silent blocks 12 are such that the hydraulic pistons or presses 11 in the extended state completely support the braces 6 on the support elements 8, so that in this operation condition a rigid power transmission is guaranteed.

However, the hydraulic pistons 11 can be depressurized by a pressure control device (not shown in FIG. 1), so that the rubber-silent blocks 12 arranged next to them elastically transmit the forces exerted by the concrete and the rock on the formwork body to the supporting elements 8.

The hydraulic pistons or presses 11 each arranged on a support element 8 can be connected to one another by a pressure line (not shown) in such a way that they can be pressurized or depressurized at the same time. Alternatively, it can be provided that the hydraulic presses or cylinders 11 of a support element 8 can be controlled individually or in groups.

The pressure ratios of hydraulic pistons or presses 11 mounted on different support elements 8 can preferably be controlled independently of one another.

As can also be seen from FIG. 1, the formwork body is divided into individual segments 14 in the circumferential direction both in the case of a circular or rounded as well as in the case of an angular tunnel or tunnel cross-sectional profile. This means that, first of all, the formlining 5, seen in the circumferential direction, consists of individual formwork panels 15 which are arranged directly next to one another in the circumferential direction. The joints between these individual formwork panels 15 are bridged by seals 16 made of plastic or rubber, which enables a certain relative mobility of the formwork panels with respect to one another. Furthermore, the stiffeners 6 also consist of individual ones next to one another in the circumferential direction of the tunnel of the arranged stiffening elements 17, which are each assigned to a formwork panel 15.

In the example shown in FIG. 1, each stiffening element 17 is supported on a corresponding support element 8 via two groups of transmission members 11 and 12.

As can be seen in particular from FIG. 2, the annular cavity enclosed between the tunnel or tunnel excavation wall 3 or an outer formwork and the formlining 5 is closed at its front end by a front formwork 20, which consists of the actual formwork elements 21 and one this formwork elements bearing ring structure 22. The end formwork ring 22 is connected via longitudinal beams 23 to the support structure 7 of the sliding formwork 2 consisting of the support elements 8 in that the longitudinal beams 23 are guided in the longitudinal bars 9 of the support structure 7 so as to be displaceable in the longitudinal direction.

In general, the longitudinal beams 23 are rigidly connected to the longitudinal spars 9, so that the entire sliding formwork can be driven like a one-piece body.

Only for those cases in which a section of the tunnel wall to be concreted has to be provided with reinforcements can the rigid connection between the / front formwork 20 and the support structure 7 be released and the front formwork 20 with the help of not shown, between the longitudinal beams 23 and the longitudinal spars 9 acting pneumatic or hydraulic presses are advanced with respect to the support structure 7 alone.

In all cases in which this is not necessary, the face formwork 20 and the support structure 7 remain firmly connected to one another. This makes it possible to advance the entire sliding formwork using the pressure of the liquid concrete, which is pressed by a concrete pump 2'5 via pressure lines 26 from the front end into the annular cavity 31 enclosed between the tunnel inner wall 3 and formlining 5. Essentially, the hardened in-situ concrete 4 that closes this annular space to the rear serves as an abutment.

This type of tunneling is particularly advantageous because it makes it unnecessary to provide any abutments for advancing the sliding formwork 2 within the precast concrete cross-section, thereby avoiding the spatial constriction associated therewith and also the risk of damage to the already finished in-situ concrete. This is also an extremely good. Mation or compression of the freshly poured into the annular cavity 31 between tunnel wall 3 and formwork 5 liquid concrete.

In Fig. 3, the sealing device 27, which is only shown in general in Fig. 2, is shown on an enlarged scale so that its construction according to the invention is clear. The support according to the invention of the formwork shell 5 and stiffeners 6 on the support elements 8 via mutually parallel, optionally operational rigid and elastic transmission members 11 and 12 can be carried out not only regardless of whether the advance of the sliding formwork 2 continuously or discontinuously takes place, but also regardless of whether it is in a known manner is carried out with the help of hydraulic or pneumatic presses, which are supported on the one hand on abutments mounted in the finished tunnel and on the other hand on the support structure 7, or whether the driving forces are generated in the particularly preferred manner according to the invention by the pressure of the liquid concrete pressed in behind the face formwork 20 will.

In the latter case it is important that, as shown in FIG. 3, a good seal is maintained between the excavation wall 3 of the tunnel or tunnel or the outer formwork attached there and the peripheral edge of the end formwork 20. This seal must be strong enough on the one hand to allow the necessary pressure build-up behind the face formwork 20 and on the other hand have the necessary flexibility to allow the sliding formwork 2 to move forward and thereby a balance between the substantially rigid and unchangeable outer edge of the face formwork 20 and the Ensure that the inner contour of the excavation wall 3 or the outer formwork attached there is not completely uniform due to manufacturing or working tolerances.

According to the invention, a sealing device 27 is used for this purpose, which comprises a first inflatable tube element 28, which extends in the circumferential direction of the front formwork 20 and is rectangular in its cross section shown in FIG. 3, and which is firmly connected to the end formwork 20 in its radially inner region protrudes beyond its radial outer edge in the inflated state to such an extent that its radial outer surface is firmly pressed against the wall 3 of the tunnel.

Now, as the tunnel progresses, the sliding formwork 2 and with it the front formwork 20 in Rich device of the arrow V is advanced, so at least with a continuous advance the hose element 28 must remain pressed against the breakout wall 3 during the forward movement, so that the pressure causing this forward movement is maintained behind the face formwork 20. This initially leads to the deformation of the hose element 28 shown in FIG. 3, so that the radial outer surface of the hose element 28 does not rub along the breakout wall 3 during a further forward movement of the end form 20 in the direction of arrow V, which leads to a pressure loss behind the end form 20 could lead and a very strong wear of the hose element 28 would result, according to the invention, in the axial direction, in addition to the first hose element 28, at least one further hose element 29, which is constructed in principle in the same way, is fastened to the peripheral edge of the face formwork 20. This second hose element 29 remains depressurized as long as it is not in contact with the breakout wall 3 as long as the first hose element 28 is under pressure and assumes the required sealing function. Only when the first hose element 28, which is under pressure and therefore bears against the breakout wall 3, has been deformed to such an extent that the forehead formwork 20 moves forward that it would start to rub against the breakout wall 3 if the forehead formwork continued to move forward, is the second hose element 29 under pressure set so that it bears in a sealing manner against the breakout wall 3. Then the pressure in the first hose element 28 is reduced to such an extent that it shortens in the radial direction and is released from the breakout wall 3. Due to its elasticity, the deformation of the hose element 28 shown in FIG. 3 is reversed and it returns to its starting position, which in FIG. 3 is for the hose element 29 and a third axially behind it Hose element 29 arranged hose element 30 is shown. During the further forward movement of the front formwork 20, the second hose element 29 now resting on the breakout wall 3 is deformed in the manner shown in FIG. 3 for the hose element 28. If this deformation has progressed to such an extent that the outer surface of the hose element 29 could slide against the breakout wall 3 again, the third hose element 30 is pressurized, which now takes over the sealing function, while the hose element 29 is relieved again.

Thus, in the direction of arrow D, i.e. opposite to the direction of advance V, alternating pressurization of the hose elements 28, 29 and 30 attached to the circumferential edge of the face circuit 20, even with continuous advancement of the sliding formwork 2, ensures a continuously sealed closure of the annular space enclosed between the breakout wall 3, front formwork 20 and formwork skin 5 of the sliding formwork 2 Ensure the prevailing jacking pressure is maintained without the sealing device 27 rubbing against the wall 3 of the tunnel or tunnel.

According to the invention, when using this tunneling method, there must also be a pressure-tight connection between the front formwork 20 and the formwork body 5, 6 extending axially from it. According to the invention, the front formwork can also be subdivided into segments to which the concrete is fed separately. In an advantageous manner, a separate pressure control can be provided for the hose elements of each segment in order to achieve a certain richness tion control of the front formwork 20 to enable if it is to be pushed forward, for example in a tunnel or gallery with a curved longitudinal axis.

4 shows a further possibility of the inventive design of the rigid and elastic transmission elements arranged between / formwork bodies 5, 6 and the support elements 8 of the support structure 7.

As can be seen from FIG. 4, the hydraulic press forming a rigid transmission member 11 comprises a double-acting piston 33 which can be pushed back and forth in a cylinder 2 and which, for example, bears a plunger 34 which can be pressed against a stiffener 6 and retractable therefrom, during Cylinder 32 is connected to a base plate 40, which rests, for example, on a support element 8. The interior of the cylinder 32 can either be connected in front of or behind the piston 33 via lines 35 or 36 to a pressure source 37 in order to press the plunger 34 against the stiffener 6 or to pull it back from the stiffener. From the line 35 a branch leads via a shut-off valve 38 to a gas cushion 39 which, in parallel to the hydraulic press 11 instead of or in addition to the rubber-silent blocks 12 shown in FIGS. 1 and 2, acts as an elastic transmission member between the formwork body 5, 6 and the support structure 7 can be arranged. With the help of the shut-off valve 38, it is possible to shut off the line leading from the hydraulic pump 37 to the gas cushion 39 and to build up the hydraulic pressure required for the rigid support of the formwork body 5, 6 in the hydraulic cylinder 32. If the shut-off valve 38 is then opened, the connection to the gas cushion 39 ensures elastic support. By this type order can also be maintained in the case of elastic support the same pressure as in the rigid support, the main difference is that in the elastic support this pressure exceeding forces, which are generated for example between constraints between slipform 2 and 4 hardened concrete , can be absorbed by elastic deformations.

Claims (11)

1. A method of driving a sliding formwork when a tunnel or tunnel is being constructed, which has a formwork body extending in the longitudinal direction of the tunnel or tunnel and essentially parallel to the wall of the excavation, and the front of the formwork between the tunnel or tunnel excavation wall or an external formwork attached there and the formwork enclosing the annular space enclosing end formwork and a support structure supporting at least the formwork body, characterized in that at least in the ceiling area of the gallery or tunnel, the parts of the formwork body that are to be backfilled with liquid concrete and the parts of the formwork body that are not yet Apply hardened concrete, be rigidly supported on the support structure and that after sufficient hardening of the concrete, elastic support of the formwork body on the support structure is started. 2. The method according to claim 1, wherein the sliding formwork is continuously driven at a speed adapted to the hardening speed of the concrete, characterized. that the front parts of the formwork body are rigid in the area of the still liquid or not yet sufficiently hardened concrete and the rear parts of the formwork body in the area of the sufficiently hardened concrete are supported elastically on the support structure. 3. The method according to claim 1, in which the sliding formwork is driven discontinuously, characterized in that for the initially rigidly supported parts of the formwork body, after sufficient hardening of the concrete lying against them, an elastic support is adopted. 4. The method according to claim 3, characterized in that the transition to elastic support takes place at the latest before restarting a temporarily stationary sliding formwork. 5. A method of driving a sliding formwork when a tunnel or tunnel is being built, which includes a formwork body extending in the longitudinal direction of the tunnel or tunnel and essentially parallel to the wall of the excavation, and the front of the formwork enclosed between the wall of the excavation or an external formwork attached there and the formwork body End formwork that closes the annular space and a support structure that supports at least the formwork body, in particular according to one or more of claims 1 to 4, characterized in that the sliding formwork is moved forward with the help of the pressure of the concrete pressed into the part of the annular space located behind the end formwork. 6. Device for carrying out the method according to one or more of the preceding claims, characterized in that for supporting at least parts of the formwork body (5,6) on the support structure (7) both rigid (11) and elastic (12) transmission members between Formwork body (5,6) and support structure (7) are arranged to act parallel to each other and that a switchover device is provided which enables either the rigid (11) or the elastic (12) transmission elements to be put into operation. 7. Apparatus according to claim 6, characterized in that the rigid Ubertra ^g of ungsglie- are formed by hydraulic presses (11) and that the resilient transfer members comprise rubber mounting blocks (12) or pneumatically or hydraulically pressable cushion (39). 8. Device according to one of the preceding claims, characterized in that the formwork body (5, 6) is divided into individual segments (14) lying next to one another in the circumferential direction, the joints of which by a certain relative movement of the individual segments (14) permitting sealing elements (16) are bridged. 9. Device according to one of the preceding claims, characterized in that a sealing device (27) is arranged between the outer edge of the end formwork (20) and the outbreak wall (3) of the tunnel or tunnel or an outer formwork attached there. 10. The device according to claim 9, characterized in that the sealing device (27) from at least two arranged in the driving direction one behind the other, extending in the circumferential direction of the end formwork (20), in the non-inflated state against the excavation wall (3) or against the outer formwork , when inflated firmly on the Outbreak wall (3) or the outer formwork hoses (28, 29, 30), and that these hoses (28, 29, 30) can be individually inflated or deflated. 11. The device according to claim 9 or 10, characterized in that the end formwork (20) is divided into segments, to which the liquid concrete can be fed separately, and that the hoses (28, 29, 30) of each segment of the end formwork (20th ) for controlling the direction of the sliding formwork (2) independently of the hoses (28, 29, 30) of all other segments of the face formwork (20) can be pressurized or vented.

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