DE643982C - Device for carrying out the process to prevent the destruction of vaulted and suspended ceilings - Google Patents

Description

Device for carrying out the method for preventing destruction of vaulted and suspended ceilings treated in accordance with patent 618 216 of the present invention a further development of the relieved vault and suspended ceilings according to the main patent 618 216. The essence of the main patent is that the vault when expanding can give way as a result of the warming without increasing the load on the stones Temperature increases, others decrease to the same extent even with increasing temperature, how the softening of the stones increases. Some of the vaulted ceiling designs discussed there have the disadvantage that they are arranged in the vicinity of the yielding abutments refractory bricks may and may not stand out from the wall of the vaulted frame exactly follow the curvature of the vault.

The present invention is intended to avoid these disadvantages and others Show improvements and training. It is shown in Figs: i to 21, namely, FIGS. i to ii and 2o show the application of the invention in several ways Embodiments of vaulted ceilings and Figs. I2 to i9 and 21 the analogous Application to some embodiments on anchors for all kinds of furnaces.

Fig. I shows a cross section to the longitudinal axis of a furnace vault and Fig. 2 shows a section A-B of Fig. i. i is the vault frame which the refractory bricks 2 carries. The stones 2 are in this embodiment in the Longitudinal and transverse direction concave and convex to prevent the Flame is able to take a straight path when penetrating into any joints that are forming. The stones are sanded clean so that they can be without any special binding agents (mortar etc.) can be used seamlessly.

The decreasing load on the vault in some degree depending on the rising temperature is shown in the exemplary embodiment Fig. i in the simplest Way by knee joints 3 and 4, to which the weight 5 is articulated, achieved. The screw 6 serves as the limit point for the joint 3, 4. The pressure segment 7 is hinged to the lever 4 at io. At the same time, the Turn roller 8, which on the curved path 9 rolls, the radius of which has the same center point as the radius of the vault frame i. Through this arrangement there is the great advantage that the refractory bricks now move when they expand iif can move precisely in the arch shape of the vault as a result of the increase in temperature and no longer stand out at the ends from the vaulted frame i.

Fig.3 shows a similar design as Fig. I. In this example the weight 13 'can be made much lighter because of the leverage of the lever 12 is enlarged by lever arms of different sizes. The weight 13 sits on the lever 12, which is hinged at 14, and holds by push rods i i via the knee joint 3, 4 with the mediation of the roller 8 and the pressure segment 7 the refractory bricks 2 together.

Fig.4 shows another embodiment. This is where the weight pulls 13 the knee joint 3, 4 by means of the lever 12 with the intermediary of the pull rod 15 at. The roller 8 rolls in this example on the upper elongated track 16 of the Vaulted frame i. In addition, the weight of the Vault frame i also used to act on stones 2. For this purpose owns the joint 3, 4 another roller 17 which is on one on the masonry of the furnace or unrolls on a special column resting plate 18.

In the example according to Fig. 4 @, the lever 12 and the weight 13 can also be replaced by strong tension springs 103 (dash-dotted line), since the knee joint effect of the knee joints 3, 4 requires significantly less forces and the changing position of the knee joints increases the forces of the Picking up springs as the masonry expands.

In Figure 5, the forces acting on the toggle levers 3, 4 are also applied by springs. You can the springs 30 only on one side of the knee joint 3, 4 or, as Fig. 5 shows, on a double knee joint 3, 4 and 3 ',. attack. The mode of operation of the springs 30 and 31 can be readily seen from Figure 5. You can also embed the springs 30 and 31 in special boxes and cool the springs to keep the inevitable temperatures away from the springs. In Fig. 5, for example, the spring 30 is inserted into a spring box 32, which has a coolant inflow and outflow 33 and 34 and can participate in the spring travel. The springs 31 are cooled by the inflow and outflow 35 and 36. Nothing stands in the way of cooling the knee joints 3, 4 and 3 ', 4' and the rollers 8 at the same time. This can be z. B. by an elastic metal membrane guided around the pressure segment 7 or connected to it and connected to the vault frame i deht. In this case, a special cooling of the springs 3o is no longer necessary. The water drain 36 would then have to be placed at the highest point in this case.

The training possibilities of the invention principle are not herewith exhausted. So show z. B. Fig. 6 and 7 another embodiment. Be here the pressure segment 7, which acts on the stones 2, and that on the curved path 9 running roller 8 by a steep, single or multi-thread, non-self-locking, Screw shaft 38 secured against rotation is influenced. On the worm nut 39 engages a lever 4o and the weight 41 (Fig. 7). By appropriate position of the Lever 40 will also change with the increase in temperature level as a result the lever moment reduces the load on the rows of stones.

In Fig. 8 the pressure effect on the stones 2 is shown by a rack 42 reached, which by a gear 43 through the intermediary of the linkage 44 and of the lever 45 articulated to 47 is influenced by the weight 46. The change the load on the stones 2 when the temperature changes is due to the different Position of the point of attack 48 reached. It goes without saying that the weights 41 and 46 in Figs. 6 and 8 also through corresponding loading by powerful springs can be replaced or charged additionally.

One can also reduce the load on the refractory bricks 2, especially at replace larger furnaces with hydraulic effects. So show z. B. Fig. 9 a part of a furnace vault in section and Fig. io in plan view of an embodiment, in which one or more hydraulically influenced pistons 49, which are located in cylinders Move 5o, act on the knee joints 3, 4 by means of the piston rods 51. the Pistons 49 can be driven by a pump, which always delivers constant pressure, to be influenced. You can also connect the cylinder 5o to a flood tank, Connect the compressed air line or container or the like. Also, for security reasons at the same time several of these known devices are provided which if necessary automatically by means of safety devices known per se connect sequentially if a power donor fails for any reason should. The pressure cylinders 5o can also be each for themselves or all be connected in parallel to a power donor at the same time and directly, that is, without the interposition of a knee joint or the like, act on the stones 2. With this version * the load would be the same at all temperatures. Man but could also in this training, the decrease in the forces when heating the Reach masonry by other means. This could e.g. B. depending on the temperature increase is done by special temperature regulators known per se, which the pressure, for example in pumps, depending on the temperature increase would regulate or the water level in the flood tanks through a the medium draining valve or the like. Influence.

Figs. Rz and 12 show an embodiment of an arch in which the pressure effect is arranged laterally as an extension of the arch. In this example, the pressure effect takes place through springs 5r, but can of course also take place through weight arrangement or also hydraulically in the same way. The springs 51 in Figs. Rz and 12, which can be pretensioned by spring plates 52 by means of screws 53, act through the knee joints 54, 55 on the bar 56 which holds the stones 2 together.

In many cases it can be useful to separate each row of stones to strain, especially when you have cleanly cut stones without using the known ones Binder (mortar, etc.) is used. In these cases the training becomes appropriate Use as shown in Fig. 13. In Fig. 15 the springs 57 act through the mediation of the knee joints 58, 59 and pressure plates 6o on the individual rows of stones 2. On the pressure plates 6o rollers or skids can also be attached, which are located on curved tracks move.

Figs. 14 to 21 show training possibilities of the invention Anchor bolts, which are used for resiliently holding together furnace vaults Find.

In FIG. 14, 66 is the anchor screw which is intended to hold the furnace vault 67 and the furnace walls 68 together in an elastic manner by means of the furnace pillar 69. For this purpose, a double knee joint 70 is provided, which is hinged to the eyes 71 and 72 of the washers 73 and 74, the spacing of which can be changed by the nut 75. This knee joint 70 is held in tension by a bolt 76, spring plate 77 and spring 78. The tension of the coil spring can be regulated by the nut 79. In this exemplary embodiment, a bolt 76 is provided which passes through an elongated hole 8o of the armature 66. However, this weakening of the armature 66 can also be avoided and two bolts 76 can be arranged to the side of the anchor screw and, in this case, two springs 78 can be provided.

In Fig. 15 , the springs 83 are arranged outside the housing 81, which influence a simple knee joint 7o. In the lower half of Fig. 18, a double knee joint 70 with the springs 83, which can be preloaded by the nuts 84, is shown. Any number of these knee joints 70 can be arranged in a star shape around the anchor, as FIG. 17 shows.

In Fig. 16, the joints 70 are provided in the lower half, which are loaded by the springs 82 arranged in the free-floating housing 81. These springs can be built-in as evolute, spiral, plate or friction springs and, depending on the load cases with the knee joints, can be arranged in two or more star shapes in the central direction, as shown in Fig. 17 . As a result of the floating design of the ring 81, the spring 82 is no longer laterally stressed. Of course, the ring 8 1 can also be made floating in the upper version of Fig.i5.

It is also evident that the development of the joints shown in Figs. 12 and 13 can also be applied to the anchors. Sb shows e.g. B. the upper half of Fig. 16, the knee joints 70 and 7o ', which are influenced by the springs 85. In this case, too, the springs 85 can be placed on the spring plate 88 and pretensioned in any way using screws 89. The springs 85 could also be arranged outside the housing 86 in order to be able to observe them at any time. In certain cases the springs can also be replaced by hydraulic forces, as has been shown in Fig. 9 and ro. These are only structural details that do not present any significant difficulties.

According to the invention, in the embodiment according to Fig. 16 pressure cylinder the pressure disc 87 and the housing 86 without the use of knee joints and keep feathers apart. In this case, compared to the known, with springs loaded furnace anchors the advantage that the load on the furnace vault does not grow with the expansion of the masonry. But you can also use the cylinder acting forces by opening a valve or regulating the water level in an elevated tank depends to a certain extent on that in the furnace change the prevailing temperature.

It is also evident that one can in the same way without "-more" the Embodiments shown in Fig. 6 to 8 (worm wheel and nut as well as rack and gearwheel) can be transmitted to the armature.

The development possibilities of the invention principle are not exhausted here either. So z. B. replace one or more inelirere parts of the joint with leaf springs in such a way that special springs (3o and 3l 'in Fig. 7), weights or the like are unnecessary or only used in addition. An example of this type is shown as an anchor in Fig. 18. 89 is the rigid joint and 9o is a flexible joint formed by leaf springs. 9i is the furnace pillar, which is held by the anchor 93 by means of the pressure washer 9.4. The initial tension is determined by the nut 92. The mode of operation can be easily understood from Fig. 18. It goes without saying that the rigid part 89 of the joint in Fig. 18 can also be formed by leaf springs.

This version according to Fig. 18 can also be easily integrated into the Use the embodiment shown in Fig. 5.

You can also choose the lower version of the floating round ring (or in a box-shaped rectangular design) 81 with the springs 82 in Fig. 16 Use analogously in the embodiment of Fig. 5. In this case it will the vault frame i in Fig. 5 relieved in the vertical direction, since now the ring 8i takes over the stress in this direction. It can also be in Fig. 16 avoid the springs 82 in order to make a smaller diameter of the ring 81 to obtain. In this case, the ring 81 itself will expediently be designed to be elastic. This can be achieved, for example, by making this ring made of leaf spring steel Evolutförinig, round or elliptical winds in such a way that he is under load can stretch.

This design is shown, for example, in a round shape in Fig. I 9. An exemplary embodiment on a furnace vault is shown in FIG. 2o. The joint 95, which to achieve a short spring deflection in this example designed with unequal legs is held under tension by the evolutely wound spring ring 96. The joint 95 has the pressure piece 7 and the roller 8 on one side rolls on the curved path 9. On the other side of the joint 95 is a foot 97 hinged, which is used in the approach 98 of the vault frame i. These Execution has the advantage that there is no processing on the vault itself etc. is required.

Another embodiment of compact design is shown in Figure 2i on an embodiment of an anchor. 103 is again the known joint, which is loaded by the pressure ring io.I by means of leaf springs l07. The leaf springs 107 are protected against overload by a corresponding curved design of the recess io8. io5 is the thrust washer that loads the kiln pillar iog. The preload is regulated by the nut i io of the armature iii. The pressure ring io4 is arranged freely floating in Fig. 2i, but can also consist of one piece with the pressure disk 105 or 112. In this case, a roller 113 prevents sliding friction.

Claims (6)

PATENT CLAIMS: i. Device for carrying out the method for preventing the destruction of vaulted and suspended ceilings according to patent 6i8 216, characterized by curved tracks (9) with the same radius of curvature as the arched track of the vault frame, on which the easily movable segments (7 ) under the mediation of rollers or sliding blocks (8) are performed, and through special intermediary links, z. B. single or multiple knee joints (Fig. I5), steep, non-self-locking worm shafts and nuts or toothed racks and wheels, which transfer the forces that become effective through the expansion of the rows of stones to balancing devices with weight-related, resilient or hydraulic effects. 2. Device according to claim i, characterized in that the load on the intermediate means Springs are surrounded by a cooling container. 3. Apparatus according to claim 2, characterized characterized in that the intermediate means by a 'membrane (37) so against the Masonry are complete that they are cooled by a circulating agent can. . 4. Apparatus according to claim i to 3, characterized in that the weight of the vault frame (i) acts on the stones (2) by means of knee joints (Fig. 6). 5. Apparatus according to claim z to q., Characterized in that that the knee joints are unequal and with self-tightening, freely swinging, Evolution-shaped wrapped rings are surrounded. 6. The analogous application of the measures according to claim r, 2, 5 for tension and pressure anchors on stoves, chimneys and other, masonry subject to the heating effect. The concentric arrangement of the knee joints to pressure anchor according to claim 6.