DE102022125463A1 - Tunnel for curing concrete products - Google Patents

Abstract

A tunnel (1) for the continuous hardening of concrete products (15) stored on mobile bases (14), the tunnel (1) being closable at the entrance and exit by gates (2, 3), is to be developed in such a way that carbonization of concrete in a continuous process, and that at the same time the drying and carbonization of the concrete can take place in an open process using carbon dioxide-containing flue gas or air and with no additional carbon dioxide escaping through the open process into the environment. It is proposed that the tunnel interior is airtight when the gates (2, 3) are closed, that the tunnel (1) is divided into at least three procedural zones, that the first zone (4) is connected to a drying air supply, the second zone (5) to a supply of gases containing more CO2 than ambient air and the third zone (6) are connected to an exhaust air duct, that at least the exhaust air duct is assigned a control or regulating device (12), and that the delivery volume of the exhaust air duct is controlled via the control or regulating device (12) can be adjusted depending on the CO2 content of the exhaust air.

Description

The invention relates to a tunnel for the continuous hardening of concrete products stored on mobile bases, the tunnel being closable by gates at the entrance and exit, and a method for operating the tunnel.

Plants for curing concrete products have been known for a long time. For this purpose, the concrete goods are placed in hardening racks, which are stored in large, closed climatic chambers for a period of several hours to days. In the closed climatic chambers, however, only one climate can be formed without specific differences in temperature and/or relative humidity in the chamber or over time. These chambers cannot be exposed to harmful gases due to their leaks and openings for board and run.

In contrast, known air-conditioning passages that can usually be closed via roller shutters are also comparatively tight. It is therefore also possible to vary the temperature and humidity over time in the closed air-conditioning aisles.

New cements/binders that do not harden by adding water but by adding carbon dioxide, for example, impose requirements on the concrete hardening that no harmful gases may escape from the climatic chamber, firstly because they are harmful to health and, secondly, because these gases (e.g. carbon dioxide) have a severe impact on the climate. This means that hardening must be carried out in a closed process.

In addition, it is necessary for the mixing water to be partly removed from the concrete products again by a drying process. This is usually done convectively in an open process by adding warm, dry air and blowing moist air back out of the chamber. However, this is in conflict with the requirement that no gases may escape from the environmental chamber. As a result, the drying has to be carried out in a condensation dryer, which is associated with high energy costs.

The carbonization of the concrete goods is generally done by batch processes, in which stationary stored concrete goods are subjected to a treatment process that changes over time, in which temperature, humidity and carbon dioxide concentration change over time. In the batch process, however, the carbon dioxide must be supplied in pure form and cannot be supplied in the form of carbon dioxide-containing flue gas or air. The background is that the additional gases have to be discharged from the chamber and it is technically not possible to keep the carbon dioxide in the chamber at the same time. Thus, a large part of the carbon dioxide contained in the air or in the flue gas would escape from the chamber again.

In many industries, such as the brick industry, continuous drying processes are known, in which the material to be dried is transported through a drying tunnel. By adding warm, dry air, the water evaporates or evaporates from the drying material. At the end of the process, the moistened drying air is blown out of the drying tunnel again by a wet air fan. However, these processes are mainly concerned with the dehumidification of dry material and not with the controlled carbonization of concrete. Accordingly, there are no control elements for this in these conventional dryers. In addition, it has not been clarified how the drying air enriched with carbon dioxide can be treated in such a way that carbon dioxide-free drying air can be blown out of the tunnel again.

There is currently no known process under which concrete products can be carbonized in an open and continuous process and using carbon dioxide-containing flue gases or air.

The invention has for its object to provide a process plant that allows carbonization of concrete in a continuous process, in which both drying and carbonization of the concrete can be done in an open process with the use of carbon dioxide-containing flue gas or air and in which no significant amounts of carbon dioxide escape into the environment through the open process, and no CO ₂ escapes to the outside when the mobile documents are locked in and out when the gates are open

The object is solved by the features of claims 1 or 7. Further solution features result from claims 2 to 6 and 8 to 10.

The object is achieved in terms of device in that the tunnel interior is gas-tight with the gates closed for CO ₂ hardening, that the tunnel is divided into at least three procedural zones, that the first zone to a drying air supply, the second zone to a Supply with gases containing more CO ₂ than ambient air and the third zone are connected to an exhaust air duct, that at least the exhaust air duct is assigned a control or regulating device, and that the delivery volume of the exhaust air duct via the control or regulating device depends on the CO ₂ -Content of the exhaust air is adjustable.

Even when the entrance gate is open, the addition of drying air before the CO ₂ feed ensures that no CO ₂ can escape into the environment.

The subdivision into zones allows different climate zones to be set simultaneously, not just one after the other, so that the concrete products in the tunnel can pass through different climate zones in which the optimal drying/hardening process takes place.

It has proven that the second zone is also connected to the drying air supply.

It is advantageous that the second zone, distributed at least in the longitudinal direction, has at least two supplies that can be individually adjusted in their CO ₂ content and/or in the amount of CO ₂ -containing gases via the or a control or regulating device.

In this way, the climate zones provided for in the transport direction of the concrete goods can be influenced even better.

It is advantageous that a fresh air supply fed by a fresh air fan is connected in the third zone in the direction of transport behind the exhaust air duct, and that the intensity of a countercurrent against the direction of transport can be adjusted via the control or regulating device and/or the fresh air fan.

This ensures that no CO ₂ can get into the environment when the mobile supports are driven out of the tunnel, ie when the exit gate is open.

Instead of the fresh air supply, a drying air supply can also be provided in the third zone.

It is expedient for the or a control or regulating device to be connected to at least one heat exchanger, via which the temperature in the tunnel can be controlled or regulated zone by zone

It is worth imitating that the control or regulating device or the control or regulating devices are connected to valves and/or fans and control or regulate them.

In terms of the method, the object is achieved in that the concrete products are moved through the tunnel in the direction of transport, that in the first zone of the tunnel the CO ₂ concentration is adjusted to emission-related permissible values via the drying air supply, that in the second zone of the tunnel CO ₂ - containing air or flue gases are introduced, the CO ₂ concentration and / or the amount of CO ₂ -containing gases decreases in the direction of transport of the concrete products up to the permissible emission values, the decrease in the CO ₂ concentration due to the increasing carbonization of the Concrete goods takes place, and that in the third zone the exhaust air is discharged after falling below the maximum permissible CO ₂ concentration in terms of emissions.

It is noteworthy that in the second zone, the CO ₂ concentration decreases in the direction of movement of the concrete products due to the CO ₂ supplies distributed in the direction of transport.

It is expedient for different temperature zones to be set at least in the second zone via heat exchangers and/or the drying air supply in the transport direction of the concrete products.

It is advantageous that the gas flow in the tunnel is parallel to the transport direction, and that the fresh air fed in in the third zone in the transport direction behind the exhaust air duct is sucked off from the exhaust air duct in countercurrent to the gas flow.

This ensures that no CO ₂ can escape into the production hall when the exit gate is open and the mobile supports are moved out.

This is also achieved at the entrance in the same way, in that the CO ₂ -containing gas is fed in in the direction of travel only after the dry air has been introduced. In particular, this does not result in a continuous process that is safe for people.

• 1 einen erfindungsgemäßen Tunnel,
• 2 ein weiteres Beispiel für einen erfindungsgemäßen Tunnel, und
• 3 ein Beispiel für einen erfindungsgemäßen Tunnel mit Gegenstrom lösung.

The invention is explained in more detail with reference to a drawing. while showing

• 1 a tunnel according to the invention,
• 2 another example of a tunnel according to the invention, and
• 3 an example of a tunnel according to the invention with countercurrent solution.

1 shows a tunnel 1, which can be closed by an entrance gate 2 and an exit gate 3. The tunnel 1 has a first zone 4 , a second zone 5 and a third zone 6 . The first zone 4 is supplied with drying air 8 via an inlet air fan 7 , while the second zone 5 is supplied with flue gas 10 via a fan 9 . At the end of the tunnel 1, the drying air in the third zone 6 is removed from the tunnel via an exhaust fan 11. The fans 7, 9, 11 can be influenced in terms of their delivery rate via a control or regulating device 12. The measured values of a CO ₂ measuring device 13 are applied to the control or regulating device 12 .

In the first zone 4, a mobile base 14, e.g. a wagon, is shown on which concrete products 15 are arranged. The concrete products 15 are moved through the tunnel 1 in the transport direction 16 by means of the mobile base 14 .

2 shows tunnel 1 according to FIG 1 , in which, however, drying air 8 is fed to the second zone 5 via various valves 17, 17′, 17″, 17′″ offset in the transport direction 16 . Similarly, flue gas 10 is fed to the second zone 5 via valves 18, 18', 18''. The valves 18, but also the valves 17, are connected to the control or regulating device 12, not shown. Also not shown is, for example, a further CO ₂ store or a CO ₂ flue gas source connected to various valves 18 . As a result, for example, the CO ₂ content in the second zone 5 in the transport direction 16 can be better influenced, depending on the carbonization state of the concrete products.

3 shows opposite 2 that in the third zone 6 in the transport direction 16 behind the exhaust air duct 11', a fresh air supply 19' fed by a fresh air fan 19 is connected. The fresh air, which can also be drying air 8, is drawn off in counterflow 20 from the exhaust air duct 11'.

The temperature in the various zones can be set optimally via a heat exchanger 21 influenced by the control device 12 .

Reference List

1

tunnel

2

entrance gate

3

exit gate

4

First zone

5

Second zone

6

Third zone

7

supply air fan

8th

dry air

8th'

drying air supply

9

fan

10

flue gas

11

exhaust fan

11'

exhaust duct

12

control device

13

CO ₂ meter

14

Mobile base

15

concrete goods

16

transport direction

17

Valve

18

Valve

19

fresh air fan

19'

fresh air supply

20

countercurrent

21

heat exchanger

Claims (10)

Tunnel (1) for the continuous hardening of concrete products (15) stored on mobile bases (14), the tunnel (1) being closable at the entrance and exit by gates (2, 3), characterized in that the interior of the tunnel when the gates ( 2, 3) it is gas-tight for CO ₂ hardening that the tunnel (1) is divided into at least three procedural zones (4, 5, 6), that the first zone (4) in the transport direction (16) is connected to a drying air supply ( 8`), the second zone (5) in the direction of transport (16) is connected to a supply of gases containing more CO ₂ than ambient air and the third zone (6) in the direction of transport (16) is connected to an exhaust air duct (11') such that at least a control or regulating device (12) is assigned to the exhaust air duct (11'), and that the delivery volume of the exhaust air duct (11') can be adjusted via the control or regulating device (12) depending on the CO ₂ content of the exhaust air . Tunnel (1) to claim 1 , characterized in that the second zone (5) is also connected to the drying air supply (8'). Tunnel (1) to claim 1 or 2 , characterized in that the second zone (5) distributed at least in the transport direction 16 over at least two individually in their CO ₂ content over the or a control or regulating device (12) has adjustable supplies. Tunnel (1) after one of Claims 1 until 3 , characterized in that a fresh air supply (19') fed by a fresh air fan (19) is connected in the third zone (6) in the transport direction (16) behind the exhaust air duct (11'), and that the control or regulating device ( 12). and/or the fresh air fan (19) the intensity of a countercurrent can be adjusted counter to the transport direction (16). Tunnel (1) after one of Claims 1 until 3 , characterized in that the or a control or regulating device (12) is connected to at least one heat exchanger (21) via which the temperature in the tunnel (1) can be controlled or regulated in zones. Tunnel (1) after one of Claims 1 until 4 , characterized in that the control or regulating device (12) or the control or regulating devices are connected to valves (17, 18) and/or fans (7, 9, 11, 19) and control or rules. Method for operating a tunnel (1) according to claims 1 until 6 , characterized in that the concrete products (15) are moved continuously through the tunnel (1) in the direction of transport (16), that in the first zone (4) of the tunnel (1) the CO ₂ concentration via the drying air supply to emission-technically permissible values is set that in the second zone (5) of the tunnel (1) CO ₂ -containing air or flue gases (10) are introduced, wherein the CO ₂ concentration and / or the amount of CO ₂ -containing air or the The amount of flue gas in the direction of transport (16) of the concrete products (15) decreases to emission-related permissible values, with the decrease in the CO ₂ concentration taking place as a result of the increasing carbonization of the concrete products (15), and that in the third zone (6) the exhaust air is discharged after falling below the maximum permissible CO ₂ concentration in terms of emissions. procedure after claim 7 , characterized in that in the second zone (5) via the transport direction (16) distributed CO ₂ supplies, the CO ₂ concentration of the CO ₂ supply in the transport direction (16) of the concrete products (15) decreases. procedure after claim 7 or 8th characterized in that different temperature zones are set at least in the second zone (5) via heat exchangers and/or the drying air supply in the transport direction (16) of the concrete products (15). Procedure according to one of Claims 7 until 9 , characterized in that the gas flow in the tunnel (1) to the transport direction (16) takes place in parallel, and that the fresh air fed in in the third zone (6) in the transport direction (16) behind the exhaust air duct (11') in countercurrent to the gas flow from exhaust duct is sucked off.

Images