DE2905735A1 - Subsidence or sliding bearings differential compensation - involves blockable ducts linking groups of height adjustable support raising blocks - Google Patents

Abstract

The provision is for compensating varying support reactions in bearings, liable to result from subsidence or displacement of rigid structures caused by foundation settlement or uneven sliding surfaces. The settlement or displacement bearings (4) are height-adjustably underpinned by single or grouped hydraulically interconnected lifting locks (3). The groups of these are connected, in a row, with ducts which have blocking devices built into them. These open on a pre-selected differential pressure. This provides automatic compensation for changes in load distribution above max. permissible differential.

Description

Device to compensate for different

Support forces in drop or sliding bearings The invention relates to a device to compensate for different support forces in settling or Sliding bearings, which are used when setting down or moving rigid structures Foundation settlements or uneven sliding surfaces can occur.

Hit the change in the altitude of individual support points by multiple supported structures, e.g. B. as a result of subsidence, there also changes Load in such a way that the load is transferred to the other support points to compensate for this he follows.

These load transfers must be permitted in order to protect the structure Limits are kept. This is a constant control of the load distribution the support points required. To maintain the permissible load distribution, you must changes identified, for example through the provision of support, by readjusting by means of z. B. hydraulic jacks are compensated.

Such load transfers can inter alia. when inserting very stiff bridge superstructures, which are therefore very sensitive to twisting and bending as a result of deviations in the sliding surfaces from the nominal position of the supports. To avoid this as much as possible is z. B. for the well-known incremental launch method, previously unknown in in-situ concrete bridge construction, but also not required there, a very high degree of accuracy is required in the manufacture of the bridge structure. In particular, must those to be produced with very low tolerances Sliding surfaces of the bridge superstructures to be moved at any time during the movement with the nominal position of the surfaces, of the sliding bearings with tolerances of + 1 µm, to match. Even minor deviations in the sliding surface of the superstructure or the The surface of the relocator from the target position results in load transfers, with im Extreme case when a sliding track lifts off its sliding bearing a hundred percent The load is transferred from this point to other support points. This can to overuse or even damage, both with the supportive as well as lead to the supported components. For example, one experiences as a result of such Load transfers on one-sided superstructure have such a strong twist that he is damaged in the process. It is an object of the present invention to avoid this disadvantage the task of providing a device with which the load transfers described type a permissible that can not exceed. The task will be solved by the fact that the settling or sliding bearings of one or a group hydraulically interconnected lifting jacks are supported in a height-adjustable manner and that the jack groups are connected in a row with pipes. in the a shut-off device that opens to a preselectable differential pressure is built in. Particularly advantageous designs of the shut-off device required for this are described in claims 2-4.

The device according to the invention gave the advantage that thus changes in the load distribution on the support points of a structure above a maximum permissible difference was immediately automatically compensated, n. first cannot arise at all and so that the structure is protected from damage, a having to make an uneconomical P mg for extreme loads.

Embodiments of the @@@@ training are shown in the drawing and are described below using an application example described in more detail.

They show: FIG. 1 The side view of a building with built-in Device according to the invention, Fig. 2 A section along the line A-A in Fig. 1, Fig. 3-5 Schematic representations of three variants of the device according to the invention.

FIGS. 1 and L pertain, for example, to the application of the invention Device when inserting a box-shaped bridge superstructure 1 over several Pillar tables 2, on each of which two supported by means of hydraulic jacks 3 Sliding bearings 4 support the skids 5 of the superstructure 1.

The printing areas of the bebebocks, each arranged on a pillar table 2 3 are through-a line o, in which a shut-off device 7 is switched on, connected with each other.

This shut-off device 7 blocks the line 6 as long as the pressure difference in the two jacks a pre-wound, adjustable on the shut-off device 7 Does not exceed dimension. Only above this permissible pressure difference does the Shut-off device 7 so that in the jacks 3 via the now free line 6 immediately hydraulic pressure equalization and thus equalization of the loads placed there takes place until the preselected permissible pressure difference is reached again, whereupon the shut-off device 7 shuts off the line 6 again. The permissible pressure difference covers all external forces acting on the superstructure, which are also later in operation the finished bridge must be absorbed such as wind pressure, traffic loads, uneven Weight distribution of the superstructure itself etc.

The resulting load transfers are permissible therefore not balanced.

The shut-off device shown in Fig. 3 consists of two parallel turned on to each other with opposite flow directions in the line o Pressure relief or pre-load valves 8. The closing pressure on these valves is effected by a spring that can be adjusted in terms of its compressive force. Becomes the admissible Differential pressure between the two jacks connected to the shut-off device 7 3 is exceeded, the higher pressure overcomes the set closing pressure of a of the two pressure relief or pre-load valves 8. Via the now open line 6 there is almost instantaneous pressure equalization up to the permissible pressure difference, whereupon the previously open pressure relief or preload valve 8 of the closing pressure on him is closed again.

The shut-off device 7 shown in Fig. 4 consists of two adjustable Pressure switches 9, each of which is hydraulically connected to a lifting jack 3 and their switching device when the permissible differential pressure is exceeded between these lifting jacks 3 open a switching valve 10 that shuts off the line 6 causes. Immediately after the pressure equalization, the switching valve 10 closes the line 6 again.

Fig. 5 shows a further possible design of the shut-off device 7. Here are at the ends of the line 6, the return from the connected jacks 3 blocking, expandable check valves 11 connected. The control line 12 for tensioning such a check valve 11 is connected to the pressure chamber of the connected to him with locked Iiebebocks. Because the pressure to relax a check valve 11, due to the design, must be higher than the pressure shut off from in, must be in the control line 12 a pressure converter 13 can be switched on, which is dimensioned in this way is, when the maximum permissible pressure is reached in a jack 3, that is relevant relaxable back - @@ l @@@ ent 11 opens.

As shown in FIGS. 3-5 for two and three lifting jacks 3, can the inventive device also to compensate for the bridge between any many hydraulically supported support points, e.g. B. on a bridge that too can be arranged on several pillar tables. The hydraulic Support of the support points can each consist of one jack 3 or more consist of hydraulically connected hetebucks.

L e r s e i t e

Claims (4)

Claims device to compensate for different bearing forces store in set-down or shifters, which are stiff when set down or shifted Structures can arise from foundation settlements or uneven sliding surfaces, d a d u r c h g e k e n n n z e i c h n e t that the settling or sliding bearing (4) of one or a group of hydraulically interconnected lifting jacks (3) are height-adjustable and that the jack groups (3) in a row with lines (6) are connected, in each of which one to a preselectable differential pressure opening shut-off device (7) is installed. 2. Apparatus according to claim 1, d a d u r c h g e k e n n -z e i c h n e t that the shut-off device (7) consists of two spring-loaded adjustable There is pressure relief or preload valves (8) that are parallel to each other with mutually opposite flow direction in the line (6) for connection the pressure chambers of two adjacent groups of jacks (3) are switched on. 3. Apparatus according to claim 1, d a d u r c h g e k e n n -z e i c h n e t that the shut-off device (7) is hydraulic or electro-hydraulic controlled switching valve (9), whose control part with the pressure chambers of the two connected lifting jack groups (3). 4. Apparatus according to claim 1, d a d u r c h g e k e n n -z e i c h n e t that at each end of the connecting line (6) a return from the connected lifting jack groups (3) blocking, releasable non-return valve (11) is arranged, the control part of which via a pressure converter (13) with the bridge chamber is connected to the jack group (3) blocked by it.