WO1998001273A1 - Method and arrangement for producing vapour-hardened building materials - Google Patents

Abstract

The invention concerns a method of producing lightweight building materials, in particular gas or porous concrete, and an arrangement for carrying out this method, the porous concrete pat being subjected to an additional heat treatment after cutting and before vapour-hardening. As a result, the amount of time the porous concrete pats have to remain in the autoclave is reduced and the production cycles increased, such that the arrangement can be of compact construction. The arrangement according to the invention provides for the additional heating of the porous concrete pat in one or a plurality of heating chambers (6a). The operating sections are aligned in a mutually parallel manner with the autoclaves (7a), heating chambers (6a), preheating chambers (5a) and stations in which the porous concrete pats are processed. Transfer devices at the two end regions transfer the moulds from one section to any other section.

Description

 Process and plant for the production of steam-hardened building materials

The invention relates to a system and a method for producing steam-hardened building materials.

Steam-hardened building materials, in particular steam-hardened lightweight building materials, for example porous or gas concrete, are produced using the following process. The ground raw materials sand, lime, cement, sulfate carrier and aluminum powder are dosed in batches together with water in a mixer. After mixing, the material is poured into an oiled mold with a volume between 4 and 9 m ³ . After the casting mold has been filled, it is brought to a fermentation station, where the mass is fermented to its final volume and remains between one and six hours until the binder component has set enough green strength for the sawing. When the green strength is sufficient, the material is removed and then cut using wires in a sawing station. After sawing, the material is either collected at further locations in front of the autoclave until an autoclave filling is available or directly into the autoclave. After autoclaving, the usual autoclaving time is approx. 12 hours, the material is removed from the autoclave, unloaded in an unloading device, packed and transported to the warehouse.

Such a conventional system is described in S. Robert, silicate concrete, VEB Verlag für Bauwesen Berlin, Berlin 1970, and explained below with reference to FIG. 4.

In a casting station 1, the cleaned and oiled molds are filled with an aerated concrete mixture and then moved to fermentation stations 2, where the mass floats and sets in the molds. In a Entfor ungsstation 3, the green firm aerated concrete cakes are tilted by 90 ° and part of the mold removed, while a mold side wall remains as a hard floor. Another possibility provides for the transfer of the cellular concrete cakes to gratings, so that the entire shape is removed. The cellular concrete cakes are then moved to a cutting station 4 and cut there into the desired formats. The molds removed from the cellular concrete cakes are cleaned in a cleaning station 5 and then oiled in an oil station 6.

The hard floors, each with an aerated concrete cake, are now placed with their long sides next to one another or with their broad sides one above the other on autoclave or hardness trolleys 7 and moved into a tunnel 8, which is intended to protect them from cooling, in particular train. When the autoclave wagons are ready for an autoclave filling, the aerated concrete cakes are moved from the tunnel 8 into a free autoclave 9 and subjected to steam hardening there.

After the steam curing is complete, the aerated concrete cakes are moved out of the autoclaves 9 and are then available for post-treatment and / or packaging on a stand area 11. If the aerated concrete cakes are to be equipped with reinforcements, 12 reinforcements can be inserted into the molds in a reinforcement station before pouring. A disadvantage here is that such systems require a considerable amount of space. A lot of space is required for the fermentation areas and for the dividing area in front of the autoclaves, although it is sometimes customary to install heat tunnels in the area of the fermentation areas in order to shorten the fermentation time and thus save space. If the autoclaves are fed individually and not in batches, the space requirement can also be reduced. However, expensive autoclave capacity is blocked for this.

In order to operate such plants economically, production capacities of more than 300,000 m ³ / year are necessary.

Another disadvantage is that with the conventional methods, a very large number of forms must be present, which requires a considerable investment and represents a considerable capital commitment.

Object of the invention is to provide a method and a system that reduces the economic capacity and the space requirements and increases clock speeds ^■ in production.

The object is achieved by a method with the features of claim 1 and a device with the features of claim 5. Advantageous embodiments are characterized in the subclaims.

The method according to the invention and a system according to the invention provide for additional heating of the cellular concrete cakes in one or more heating chambers, the heating step taking place between sawing the cellular concrete cakes and steam curing.

The aerated concrete cakes in the heating chambers are exposed to a temperature that is preferably ≥ 100 ° C. Surprisingly, it has been found that heating the cut cellular concrete cakes before steam curing Process steps of autoclaving, such as rinsing, evacuation and opening, are shortened and certain process steps can even be omitted entirely. This is achieved, inter alia, by the fact that the dry heating of the cellular concrete cake above 100 ° C. means that no further water condenses in the cellular concrete cake and even water is expelled. The heating chambers are indirectly heated with steam from the autoclaves. Particularly advantageous in connection with the heating of the cellular concrete cakes is the provision of a known heat treatment of the freshly filled molds in heating chambers. In this way, the fermentation and setting times can be matched to the cycle times changed by the heating of the cellular concrete cake.

The method according to the invention and a plant for carrying out this method are explained by way of example with reference to a drawing. Show it

1 schematically shows a plant for carrying out the method according to the invention,

2 shows an example of an embodiment of a system according to FIG. 1,

3 shows, by way of example, a further embodiment of a system according to FIG. 2,

Fig. 4 shows a known system.

A system 1 (FIG. 1) for the production of steam-hardened building materials has functional sections 2, 3, 4, 5, 6, 7 which are arranged parallel to one another. The functional sections 2 to 7 are aligned parallel to one another and have approximately the same length, the end regions of the functional sections 2 to 7 being at a height so that the base area of the system 1 is approximately rectangular, with two longitudinal outer sides L and two end outer sides S The functional sections 2 to 7 extend here parallel to the longitudinal outer sides L of Appendix 1.

A transverse crane 9a, 9b can each be moved along a crane runway axis 10a, 10b over the end regions of the functional sections 2 to 7 along a crane runway 8a, 8b. The crane runway axes 10a, 10b are oriented parallel to one another and to the outside face S and perpendicular to the functional sections 2 to 7.

In a further advantageous embodiment of a system for carrying out the method according to the invention, instead of the transverse cranes 9a, 9b, sliding platforms are provided in the region of the crane tracks 8a, 8b.

The functional sections 2 to 7 each have a track 11a, 11b, 11c, lld, lle and llf with two rails each, the rails being dimensioned such that aerated concrete molds and autoclave wagons can be moved on them.

The functional section 2 has between the crane tracks 8a, 8b a cleaning station 15 for molds, a pouring buffer section 16, an oil station 17 for molds and in the area of the crane track 8b a casting station 18.

The functional section 3 has a hardness floor buffer section 19 between the crane tracks 8a, 8b, which takes hardness floors from an unloading station 20, which is located on a track 21, and which extends the track III of the functional section 3 beyond the crane track 8b. In the area of the crane runway 8a there is a mold making area 24a in which molds and hard floors are put together.

The functional section 4 has a saw buffer section 22, a sawing station 23a and a stacking station 23b between the crane tracks 8a, 8b, a tilting area 24b being provided in the area of the crane track 8a for tilting and removing the molds from the hardened cellular concrete cake. The functional section 5 has a preheating chamber 5a between the crane tracks 8a, 8b, the longitudinal axis 5b of which is arranged parallel to and between the rails to the track 11a. The preheating chamber 5a has approximately a length which corresponds to the length of the functional section 5 between the crane tracks 8a, 8b.

The functional section 6 has a heating chamber 6a between the crane tracks 8a, 8b, the longitudinal axis 6b of which is arranged parallel to the track 11b between the rails of the track 11b. The heating chamber 6a has approximately a length which corresponds to the length of the functional section 6 between the crane tracks 8a, 8b.

The functional section 7 has an autoclave 7a between the crane tracks 8a, 8b, the longitudinal axis 7b of which is arranged parallel to the track 11c between the rails. The autoclave 7a has approximately a length which corresponds to the length of the functional section 7 between the crane tracks 8a, 8b.

The track 11c of the functional section 7 is extended beyond the crane runway 8b and forms an extension section 25 for hardened floors loaded with hardened aerated concrete products and carried out in batches from the autoclave.

The method according to the invention is explained below (FIG. 1).

A cleaned mold standing on the pouring buffer section 16 is oiled in the oil station 17 and then filled in the pouring station 18. The filled mold is lifted by means of the cross crane 9b, moved along a crane runway axis 10b and placed on the track 11a of the functional section 5 and moved into the heating chamber 5a. The mold passes through the heat chamber 5a, in which it is preferably exposed to temperatures of 40 to 70 ° C., preferably in a time which is sufficient to complete the fermentation process and to achieve a green strength which is sufficient for cutting. The mold leaves the heat chamber 5a the other side and arrives at the crane runway 8a, where it is moved with a transverse crane 9a along a crane runway axis 10a onto the track 11f of the functional section 4 and is moved there onto the saw buffer section 22.

When moving, the shape is tilted in the tilting area 24 of the crane runway 8a and the functional section 4 and, after being set down, is removed from green-hard aerated concrete cake to the hard bottom.

The mold without a hardening base is moved to the mold construction area 24a of the functional section 3 and assembled there with an empty hardening base and from there to the cleaning station 15, these two steps also being able to take place in the reverse order.

From the saw buffer section 22, the hardened floor with aerated concrete cake reaches the sawing station 23a, where the aerated concrete cake is cut into the desired formats. In a downstream station 23b, three hardening trays with cellular concrete cakes are always placed on a hardening trolley. The cut cellular concrete cake is moved into the area of the crane runway 8b and moved with the transverse crane 9b onto the track 11b of the functional section 6 and from there it is moved into the heating chamber 6a. In the heating chamber 6a, the hardening carts are fed continuously until an autoclave batch is ready in the heating chamber, whereby the heating chamber 6a also takes over the function of a buffer or collecting section in front of the autoclave. The cellular concrete cake is preferably exposed to a temperature ≥ 100 ° C in the heating chamber. At the end of the heating chamber, the hardening car arrives in the area of the crane runway 8a, where it is placed by the cross crane 9a on the track 11c of the functional section 7 and from there it is moved into the autoclave. The heating chamber 6a can, for example, be filled and emptied in batches, so that an autoclave batch is first completely heated, then it is moved out of the heating chamber 6a in batches en bloc and inserted into the autoclave 7a en bloc. The hardening wagons are moved on the other side of the autoclave 7a to an extension section 25 of the functional section 7 in order to clear the autoclave 7a for new batches as quickly as possible. From the extension section 25, the hardening wagons reach the area of the crane runway 8b, from where they are moved with the transverse crane 9b onto the track lle of the functional section 3 and driven into the unloading station 20. The aerated concrete cakes are unloaded from the hardening wagons and the hardening floors and the hardening wagons are pushed into the hardening floor magazine 19, where the hardening floors are collected and preferably stacked. The hardening wagons are then suitably moved or transported to a transfer station.

When using transfer platforms as transfer devices instead of cross cranes, the hardening wagons are pushed from the tracks onto the transfer platforms. The transfer platforms move the hardening car along the crane / transfer platform axes 10a, 10b to the desired track, where the curing car is pushed from the transfer table onto the track. However, the basic procedure is the same.

Another embodiment (FIG. 2) of a system for carrying out the method according to the invention has two heating chambers 5a before cutting, which are passed through by a mold one after the other. After the molds have been heated in a heating chamber 6a, two autoclaves 7a can optionally be charged. Due to the fact that the tracks are arranged parallel to each other, at the same length and at the same height, a compact design of the system is also achieved here. It is not necessary to move the molds between the casting station 18 and a first heating chamber 5a, since the casting station 18 is located on an extension of the track of the heating chamber.

A further possible embodiment of a system for carrying out the method according to the invention (FIG. 3) has a long autoclave 7a instead of two short ones, which is indeed via Crane runway 8b extends, but the end of which is at the level of the casting station 18, so that a compact design is nevertheless achieved.

In a further possible embodiment of the installation for carrying out the method according to the invention, the entire installation is erected on flat foundation plates and the heating chamber is arranged above the heating chamber. If the sawing station is also at the level of the heating chamber, this results in a particularly advantageous design of the system with a small footprint. In addition, with such a system, no expensive foundation pits for e.g. Sludge collection container. The above-described cross cranes also serve here as transfer devices for transferring the hardening wagons from the lower level to the upper level on which the saw and the heating chamber are arranged.

By providing a heating chamber, the residence times of the cellular concrete cakes in the autoclave can advantageously be reduced from approximately 12 hours to approximately 8 hours. As a result, an autoclave can now be filled three times a day instead of twice as before, which can help to reduce the cycle times and increase the cycle rates in production or to reduce the number of autoclaves.

By combining the heating of the aerated concrete cake with the heating of the molds during the proofing and setting times, the proofing and setting times can be shortened and adapted to the higher cycle rates. The number of shapes can be kept low.

The design and arrangement of the functional paths according to the invention and the possible reduction in the number of autoclaves permits a compact construction of the system, thereby saving space. The high cycle rates and high throughput of the overall cost-effective system allow the system to be operated economically and efficiently with an autoclave at 70,000 to 80,000 m ³ / year.

Claims

Expectations

Process for producing lightweight building materials, in particular gas or aerated concrete, wherein an aerated concrete mass is filled into molds in which the mass floats and stiffens or sets by suitable means and the aerated concrete cake thus obtained is then first cut into the desired formats and then one Steam curing in an autoclave, characterized in that the aerated concrete cakes are subjected to a previous additional heat treatment after cutting and before steam curing.

The method of 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 aerated concrete cake during the heat treatment

90 to 120 ° C, especially above 100 ° C to be heated.

A method according to claim 1 and / or 2, characterized in that the additional heat treatment is carried out in at least one heating chamber, the heating chamber being continuously filled with several aerated concrete cakes until an autoclave batch is present which, after the heat treatment has ended, is transferred en bloc to the autoclave \ 2, one or more heating chambers being used as a buffer section for at least one autoclave.

4. The method according to one or more of the preceding claims 1 to 3, d a d u r c h g e k e n n z e i c h n e t that waste heat, in particular exhaust steam, from one or more autoclaves is used for the additional heat treatment.

5. The method according to one or more of the preceding claims 1 to 4, d a d u r c h g e k e n n z e i c h n e t that an indirect heating is used for additional heat treatment.

6. The method according to one or more of the preceding claims 1 to 5, d a d u r c h g e k e n n z e i c h n e t that the aerated concrete mass is stored heated before cutting.

7. The method according to claim 6, d a d u r c h g e k e n n z e i c h n e t that waste heat, in particular exhaust steam, from one or more autoclaves and / or one or more heating chambers is used for the heated storage.

8. The method according to one or more of the preceding claims 6 and / or 7, d a d u r c h g e k e n n z e i c h n e t that an indirect for the heated storage of the molds

Heating is used.

9. The method according to one or more of the preceding claims 6 to 8, characterized in that the filled molds are stored at 40 to 70 ° C before cutting.

10. The method according to one or more of the preceding claims 1 to 9, that the steam curing of the cellular concrete cakes in the autoclave is shortened at customary values for pressure and temperature and in particular is carried out over a period of 7 to 9 hours.

11. Plant for the production of lightweight materials, in particular gas or aerated concrete, in particular for carrying out the method according to one or more of claims 1 to 10, wherein an aerated concrete mass is filled in forms in which the mass floats and sets by suitable means and the cellular concrete cakes thus obtained are then first cut into the desired formats and then subjected to steam curing in an autoclave, characterized in that the system has one or more heating chambers (6a) for heating the cellular concrete cakes after cutting and before steam curing.

12. System according to claim 11, so that the heating chambers (6a) are arranged parallel to the autoclaves (7a).

13. Plant according to claim 11 and / or 12, characterized in that the plant has heat chambers (5a) in which the filled molds are stored after filling and before cutting.

14. System according to one or more of claims 11 to 13, that the heating chambers (5a) are arranged parallel to the heating chambers (6a) and / or autoclaves (7a).

15. Plant according to one or more of claims 11 to 14, characterized in that functional sections with the autoclaves (7a), the heating chambers (6a) and the preheating chambers (5a) and the stations in which the aerated concrete mass or the aerated concrete cake are processed, as well as their buffer sections and the hardness floor buffer section (19) are aligned parallel to one another, are approximately of the same length and are aligned, so that the two end regions can be run over by a transfer device, in particular a transverse crane, or can be driven off with sliding platforms, and the transfer device can form a track can move to any other route.

16. Plant according to one or more of the preceding claims 11 to 15, so that the entire plant is mounted on flat foundation plates and contains no foundation pits.

17. Plant according to one or more of the preceding claims 11 to 16, d a d u r c h g e k e n n z e i c h n e t that the heating chambers (5a) are arranged above the heating chambers (6a).

18. Plant according to one or more of the preceding claims 11 to 17, d a d u r c h g e k e n n z e i c h n e t that the saw station (23a) at the level of the over

Heating chambers (6a) arranged heating chambers (5a) is located. CHANGED REQUIREMENTS

[Received at the International Office on November 4th, 1997 (November 4th, 1997); original claims 1-18 replaced by new claims 1-17 (3 pages)]

1. Plant for the production of lightweight components, in particular gas or aerated concrete, with a filling station (18) in which aerated concrete is filled into molds, one or more heating chambers (5a), into which the filled molds are brought and in which the expansion and so-called setting or stiffening of the aerated concrete mass takes place, a sawing station (23a) into which the set aerated concrete cakes are then moved and in which they are cut into desired formats, one or more heating chambers (6a) in which the cut aerated concrete cakes are introduced and are stored under the influence of heat, and one or more autoclaves (7a) into which the cellular concrete cakes are inserted and subjected to steam curing, all devices (18, 5a, 23a, 6a, 7a) having functional sections equipped with rails, characterized in that the Functional sections of the sawing station (23a), the heating chambers (5a), the heating chambers (6a) and the autoclave (7a) are arranged side by side in parallel.

2. Plant 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 entire system is on without foundation pits on level foundation slabs.

3. Plant according to claim 1 and / or 2, characterized in that the heating chambers (5a) are arranged above the heating chambers (6a).

4. Plant according to claim 3, so that the sawing station (23a) is at the level of the heating chambers (5a) arranged above the heating chambers (6a).

5. Plant according to one or more of the preceding claims, characterized in that functional sections with the autoclaves (7a), the heating chambers (6a) and the prechambers (5a) and the stations in which the cellular concrete mass or the cellular concrete cake are processed, and their Buffer sections and a hardness floor buffer section (19) are aligned parallel to each other, are of approximately the same length and are aligned laterally, and that a displacement device, in particular a transverse crane (9a, 9b) or transfer platforms are provided, which run through the two free end areas of the functional sections or run over so that the transfer device can move molds from one route to any other route.

6. System according to one or more of the preceding claims, d a d u r c h g e k e n n e e c h n e t that devices are available which supply waste heat, in particular exhaust steam from one or more autoclaves (7a) to the heating chambers (6a).

7. Plant according to one or more of the preceding claims, characterized in that devices are present which supply waste heat from one or more heating chambers (6a) to the heating chambers (5a) and / or waste heat, in particular exhaust steam from one or Feed several autoclaves (7a) to the heating chambers (5a).