DE29908974U1 - Heating device, storage device, fresh concrete mixing plant - Google Patents

Description

Patent attorneys

BEETZ & PARTNER

Stelnsdorfetr. 10, D-60538 Munich

299 08 974.6 981-54.347G-EK/AP/wa

Reminder device, storage device, fresh concrete mixing plant

The invention relates to a heating device, a storage device and a fresh concrete mixing plant according to the preambles of the independent claims.

Known concrete mixing plants can be constructed in such a way that storage boxes for mixed goods are arranged in a star shape around a mixing plant. The storage boxes can be more or less open compartments that are separated from each other by vertical walls, for example concrete walls. The partition walls then run in a star shape towards the center. In the

The center itself contains weighing and mixing equipment. The individual boxes become increasingly narrower towards the center. Typical dimensions are 6 m high, 18 m long (from the front wall of the box to the outer edge), and, for example, 6 m in diameter of the central mixing area. The storage boxes can be located outdoors. This means that the mixed goods stored can contain a lot of moisture and can also change more or less quickly depending on the outside temperature. This can cause various problems:

At outside temperatures below 0 ⁰ C, the mixed material can clump together due to the water it contains and which eventually freezes, so that it is no longer free-flowing and transport mechanisms are disrupted.

If very cold base materials are used in the production of concrete, the concrete produced will also be very cold. This has the disadvantage that processing or setting of the concrete may be impossible or at least take a very long time.

To overcome the above disadvantages, various techniques are currently in use:

To raise the temperature of the fresh concrete, warm water can be added. However, the effect is small. Due to various effects, the water cannot be heated above 8 0 ⁰ C. Since its mass fraction is significantly lower than that of the cold components, the addition of warm water leads to only insufficient temperature increases (numerical example: 1 m ³ of concrete requires about 2 t of aggregate (very cold), about 350 kg of cement (very cold) and

100 to 150 1 water (80 ⁰ C). Water therefore makes up about 5% of the weight, so that the heat input is not sufficient).

The already mixed concrete or the mixed goods that have not yet been mixed can be heated by introducing steam. For example, steam lances can be inserted into the materials through which steam is fed. This can achieve a certain preheating of the material, but it has the disadvantage that considerable amounts of water are introduced into the mixed goods. This is particularly disadvantageous when dry concrete has to be produced, as is common in the precast concrete industry, for example. When steam is introduced into sand, a considerable amount of moisture remains on the surface of the sand grains, which can lead to too much water being introduced into a mixture via the aggregates. In addition, this method has the disadvantage that when the plant is switched off, for example overnight, the additional amounts of water introduced can freeze, thus making the problem even worse at the start of the next day. Finally, the energy input via steam is quantitatively insufficient.

Hot air can also be added to the aggregates. This requires powerful fans. The investment costs are high and the energy input is unsatisfactory.

Heating the mixing trough in which the individual components (e.g. cement, aggregates, water) are mixed is also known. This can, to a certain extent, compensate for the problem of fresh concrete that is too cold. However, since the problem of mixed goods clumping together and therefore no longer flowing is not solved, further equipment is required.

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The object of the invention is to provide a device for heating a mixed material, in particular for concrete, a storage device for a mixed material and a concrete mixing plant with which the flowability of the individual mixed materials can be maintained and a sufficiently high temperature of the fresh concrete can be set.

This object is achieved with the features of the independent claims. Dependent claims are directed to preferred embodiments of the invention.

According to the invention, a heated medium is preferably passed through the material to be heated by means of a line. The material to be heated can be one of the mixed materials for producing fresh concrete, in particular an aggregate such as sand, gravel, gravel chippings, lime chippings or the like.

The heat transfer between the heated medium and the material to be heated can take place by means of infrared radiation and/or by means of body-bound heat conduction. In particular, components of a dark radiator (usually used for hall heating) can be used. For example, the burner and/or the heating tube of a dark radiator can be used.

The heating of the mixed material preferably takes place in an area that is close to the area where the mixed material is removed from the storage facility. In general, temperatures of over 100 ⁰ C can be used, which lead to the evaporation of the residual water contained in the material to be heated, so that heat is transported within the material via the water vapor thus produced. The

The medium used can be at least 200 ⁰ C hot, but temperatures of over 350 ⁰ C can also be used. The heated medium can be the exhaust gas from a burner (dark radiator principle) or heated oil.

A device for storing mixed material, in particular for concrete, has a storage area for storing the mixed material, a removal area for removing the mixed material from the storage area and a heating device as described above.

The heating device can be installed in particular near the removal area, in particular at least in parts vertically above it. The heating device can be movable so that it can be transported either from one storage device to another or within a storage device. A movement device can be provided for this purpose.

A concrete mixing plant has a plurality of storage devices for mixed materials and a mixing plant which mixes mixed materials from a plurality of storage devices, wherein at least one storage device is constructed as described above.

As already mentioned, the heated medium can be the exhaust gas from a burner. The burner can be located in the area of the mixing plant. The residual heat remaining in the heated medium (after passing through the pipe) can be used in a heat exchanger, in particular to heat the mixing water for the fresh concrete.

Individual embodiments of the invention are described below with reference to the drawings, which show

Fig. 1 schematically shows a concrete mixing plant in plan view,

Fig. 2 shows schematically a concrete mixing plant in section, Fig. 3 shows schematically a heating device, and Fig. 4 shows schematically further embodiments.

Fig. 1 shows a schematic top view of a concrete mixing plant. 13a to 13f are storage devices that are sealed off from one another and in which mixed materials 16a to 16f are located. In particular, aggregates for concrete can be located here. The storage device for cement is usually sealed against the effects of the weather. The other devices are usually open and thus exposed to environmental influences (temperature, humidity). The storage devices are grouped around a central mixing plant 11. The individual components from the storage devices 13 are fed to the mixing plant 11 by suitable mechanisms and mixed there. They can then, for example, be filled from there into a mixing vehicle 14 via an outlet 15 and thus transported to the construction site. The individual storage devices have removal areas 12a to 12f. In addition, one or more of the storage devices 13 have one or more heating devices 10, as described later.

Fig. 2 shows a schematic section through the mixing plant. The same reference numbers as in Fig. 1 denote the same components. 16d is the material dumped towards the center, for example the aggregates, which are each kept separately in individual storage devices. 20 is an operable flap, with-

by means of which the removal of the mixed material can be controlled. It is located in the area of the removal area 12d. When the flap 20 is open, the mixed material 16d trickles downwards. A weighing device 21 is symbolically shown under the flap 20, by means of which the quantity removed can be determined by weight. 22 is a transport device with which the weighed mixed material can be transported in a mixing trough 23. There, mixing takes place (preferably dry at first, then wet) by means of an agitator 24. 10d shows a schematic side view of an embodiment of the heating device. It is shown in more detail in Fig. 3.

In Fig. 3, 30 designates a line which runs in the poured mixture 16. The line 38 symbolizes the dividing wall between the storage device 13 and the mixing plant 11. A heated medium which comes from a heat source 31 is guided in the pipe 30. An embodiment is shown in which the pipe 30, as the heated medium, guides the exhaust gases from a burner. As shown in Fig. 3, the burner 31 can be located in the area of the mixing device 11. However, it can also be provided elsewhere. If the exhaust gases from a burner 31 are guided in the line 30, a fan 32 can be provided which supports the flow of the medium through the line 30. The fan can, for example, be provided on the outlet side and designed as a suction fan. It can also be located in the area of the mixing plant 11. 33 represents an exhaust gas duct which leads, for example, to a chimney.

34 symbolises an optional heat exchanger with which the residual heat contained in the outflowing exhaust gas (or oil) can be used, in particular to preheat the mixing water for the concrete to be mixed.

Typical numerical values for the parts of the heating device that are in the mix can be as follows: vertical dimension x=2m (0.5 m <x;&khgr;< 3 m), horizontal dimension y=lm (0.3 m <y; y < 2 m), pipe diameter &zgr; = 11 cm (6 cm <&zgr;;&zgr;< 20 cm), heating output 10 to 100 kW, horizontal surface temperatures on the pipe 30 between 150 and 500 ⁰ C, preferably between 250 and 430 ⁰ C.

In Fig. 3, the x-direction is the vertical, the y-direction is the horizontal. The line 3 0 preferably has regions 3 0a that do not run horizontally. They can run vertically or be inclined more or less to the vertical (not more than 10°, not more than 30°). This results in the advantage that a significant section of the line 3 0 runs approximately in the direction of movement of the material to be heated, so that a uniform heat transfer from the line 3 0 to the material 16 to be heated is achieved.

The line 30 can have areas made of stainless steel. The line 30 must be mechanically resistant, since materials are constantly sliding past it. It must also be chemically resistant, since high temperatures prevail on its surface both inside and out, which can lead to accelerated chemical reactions.

The burner 31 can also be a gas burner, an electric heater, etc. The use of a burner (or its exhaust gases as a heated medium) has the advantage that high heating outputs can be achieved in a technically simple and efficient manner.

A control or regulation 35 can be provided. It can receive signals from sensors 36 (e.g. 36a outside temperature sensor, 36b sensor for the mixture temperature). In accordance with control algorithms, it can output signals 37 to the actuators (fuel supply for burner 31, fan 32, heat exchanger 34). The control/regulation 35 can have an interface 35a to higher-level controls, an input device (mouse, keyboard) 35b and a display device 35c. The control or regulation 35 implements methods for controlling or regulating the temperature of the mixture. For example, a signal for adjusting the fuel supply to the burner 31 can be generated in accordance with the difference between a target temperature of the mixture and the actual mixture temperature (from sensor 36b). The outside temperature (from sensor 36a) can also be taken into account.

Within a storage device 13, several lines 30 can run in parallel through the heated medium in a functional sense, and possibly also physically. The line 30 can have different geometries. It can also be angled several times and in particular can run in a meandering manner.

The line 30 can be located at least in part near or above the extraction area 12. It can also surround it at least in part at a distance. A more or less vertically running part 30a of the line 30 can be located above the extraction area 12.

Fig. 4 shows the basic arrangement of lines 30, heat source 31 and, if necessary, blower. In the left half of the figure, an embodiment is shown in which lines 3 0a and 3 0b for adjacent preference

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storage devices are connected in series with one another. Coming from the heat source 31a, the heated medium first passes through line 30b of the storage device 13b and then line 30a in the storage device 13a. The connection of the two lines can take place within the mixing device 11 (as shown) or through the partition wall 17.

Fig. 4 shows on the right an embodiment in which two lines 30c and 30d (functionally) lie parallel between a heat source 31b and optionally a fan 32b.

In principle, an embodiment is also possible in which one or more lines 30a to 30d in different storage devices 13a to 13d can be optionally coupled to or decoupled from a powerful heat source 31. The same mechanism can optionally be provided for the fan 32. The coupling or decoupling of individual lines 30a to 30d to a heat source 31 and possibly also their heating power and other parameters can be controlled by the control 35.

40 shows a schematic of another heat exchanger that can be provided in the mixed material. It can be located in the area of "dead material" (material that cannot trickle down) that has also been heated, and can be surrounded by it. This allows its heat to be recovered, for example, to heat the mixing water.

In principle, the heating device can also be movable. The line 3 0 or the device as a whole can be movable, which means that storage devices, for example, can be easily or only temporarily retrofitted.

Components of dark radiators can be used for heating or in the heating device 10. In particular, burners and/or control or regulation components of dark radiators can be used. In contrast to conventional dark radiators, however, the exhaust pipe does not run freely in the air. Rather, it runs through the mixture to be heated. In this respect, adjustments may also have to be made in the regulation components, in the burner and, if necessary, in the pipes themselves.

The invention has been described in connection with a star-shaped concrete mixing plant. The invention can also be used in the same way in other concrete mixing plants, for example in plants with row silos or with high silos, where similar problems can arise. The heating device would then have to be provided in the individual silos or silo sections.

The invention can be used generally when grains are to be removed from storage. For example, it can also be used in plants for producing asphalt, in plants for producing sand-lime bricks or aerated concrete blocks.

Claims (17)

1. Device ( 10 ) for heating a mixture ( 16 ), in particular an aggregate for concrete, characterized by
a line ( 30 ) by means of which a heated medium can be passed through the mixture. 2. Device according to claim 1, characterized in that the line is designed to emit infrared radiation. 3. Device according to claim 1 or 2, characterized in that the line is used in the manner of a dark radiator. 4. Device according to one of claims 1 to 3, characterized in that the line is curved and/or angled. 5. Device according to one of claims 1 to 4, characterized in that the line has a region ( 30a ) which is inclined to the vertical by at most 30°. 6. Device according to one of claims 1 to 5, characterized in that the line comprises a stainless steel pipe. 7. Device according to one of claims 1 to 6, characterized in that it is designed to be stationary. 8. Device according to one of claims 1 to 7, characterized in that it is movable. 9. Device according to one of claims 1 to 8, characterized in that the heated medium is the exhaust gas from a burner ( 31 ) or a heated oil. 10. Device ( 13 ) for storing mixed material ( 16 ), in particular for concrete, with
a storage area ( 13 a-f) for storing the mixed material,
a removal area ( 12 ) for removing the mixed material from the storage area, and
a heating device ( 10 ) for heating the mixed material, characterized by
a heating device according to one of claims 1 to 9. 11. Device according to claim 10, characterized in that the heating device ( 10 ) is arranged in the vicinity of the removal area ( 12 ). 12. Device according to claim 11 and 5, characterized in that the first region ( 30a ) of the heating device is located vertically above the removal region. 13. Device according to one of claims 10 to 12, characterized by a movement device which can move the heating device at least in the region of the device. 14. Device according to one of claims 10 to 13, characterized in that the removal area has a closable opening at the bottom through which the mixed material can trickle downwards. 15. Concrete mixing plant, with
Storage devices ( 13 a-f) for mixed goods ( 16 a-f), and
a mixing plant ( 11 ) which mixes mixed goods from storage devices, characterized by
at least one storage device according to one of claims 10 to 14. 16. Concrete mixing plant according to claim 15, characterized by a heat exchanger ( 34 ), by means of which waste heat from the heating device ( 10 ) is used to heat the water for the concrete. 17. Concrete mixing plant according to claim 15 or 16, characterized by a burner, the exhaust gases of which are guided through the line ( 30 ), the burner being located in the region of the mixing plant ( 11 ).