DE102021006406A1 - Device for spraying concrete - Google Patents

Abstract

The present application relates to a device 1 for spraying concrete with the following features: a) a conveyor line 2, which is set up and designed to receive concrete from an inlet end 5 and to direct it to its other outlet end 6, b) a lance 13, the is set up and designed to discharge the concrete by spraying; c) the lance 13 has an inlet end for the concrete fed in from the delivery line 2 and a water supply 7 adjacent to this inlet end, the water supply 7 being set up and designed to pump water into the lance 13 so that the concrete mixes with the water in the lance 13 and the flowability of the concrete within the lance 13 is increased; the binder supply 9 is set up and configured to introduce a binder into the water-enriched concrete;g) at a distance from the binder supply 9, an air supply 11 is connected to the lance 13, which is set up and configured to form an annular air flow 12 which the size of a spray cone of the concrete emerging from the lance 13 is determined.

Description

The invention relates to a device for spraying concrete according to the features of claim 1.

Blast furnace chutes have a refractory lining that is subject to constant wear and tear and must be continuously repaired. This repair is z. B. by shotcrete. The shotcrete sets immediately in contact with the hot channel lining. Therefore, the necessary technology for introducing shotcrete is usually available in the area of a blast furnace.

A mixer is usually used to mix the shotcrete. The mixer is fed with a fine-grained material, resulting in a flowable mass. This flowable mass is then transported from the mixer to a concrete pump. The concrete pump typically conveys the material into a delivery hose via a double piston system. The conveying hose often has a diameter of 120 mm. This makes it very difficult to handle. The operation of the system requires a relatively large number of personnel. One person has to start the concrete mixer, another person the pump and two people have to carry the relatively heavy hose with the nozzle. The work is physically difficult and laborious.

Another disadvantage of this system is the relatively high water consumption for cleaning the machine. Concrete is always lost when cleaning, as both the pump and the mixer and, of course, the delivery hoses have to be cleaned. On average, around 300 kg of concrete accumulates and has to be disposed of. Apart from the concrete losses, the outlay on equipment for such an arrangement for introducing shotcrete is also relatively high.

The invention is therefore based on the object of demonstrating a device for spraying concrete that is significantly easier to handle and, in particular, can be operated more cost-effectively.

The invention solves this problem with a device having the features of claim 1.

The dependent claims relate to advantageous developments of the invention.

The device according to the invention for spraying concrete firstly comprises a delivery line which is set up and designed to receive concrete from an inlet end and to convey it to its outlet end. The concrete is fed to a lance, which in turn is set up and designed to discharge the concrete by spraying. The special advantages of the invention result in particular from the design of the lance. The lance has an entry end for the concrete being fed from the conveyor line and a water supply adjacent the entry end. The water supply is arranged and designed to introduce water into the lance so that the dry concrete mix mixes with the water in the lance and the flowability of the concrete in the lance is increased.

Due to the fact that the water is only added to the concrete mixture in the lance, the concrete mixture in the delivery hose is drier up to the point where the water is fed in and is therefore also considerably lighter. A dry refractory mass can therefore be used as the concrete mix, which is usually transported by means of a pneumatic conveyor. It is not mandatory to use a completely dry refractory mass. It is sufficient to use a relatively dry or only slightly damp concrete mix. This relatively dry concrete mixture, which is also referred to below as dry concrete, is transported with air from the pneumatic conveying source in the direction of the lance.

A binder supply is located in the area of the lance at a distance from the water supply. The binder supply is set up and designed to introduce a binder into the water-enriched concrete. Water glass or potassium silicate, for example, can be used as a binder. This mixture, which was only produced shortly before the actual discharge, can now be applied. The binder is also fed in at a relatively late point in time, which means that the dry concrete in the delivery line can be particularly dry. It does not have to transport binding agent or water in the quantities required for setting. This makes it possible to equip the conveying line and the lance with a comparatively small cross section of, for example, less than 50 mm, in particular with a cross section of 45 mm. The lance is therefore significantly lighter than a delivery line with a cross-section of 120 mm, which is also filled with a wet concrete mix. As a result, the lance can be held and operated by just one person, which is a major handling advantage.

The lance also has as a special feature an air supply, which is not to be confused with an air supply for conveying the concrete mix, but is set up and designed to form an annular air flow that is the size of a spray cone from the lance escaping concrete. This allows the classic refractory cast concrete to be processed in a particularly targeted manner. The ring-shaped air flow, which can also be referred to as an air ring, acts like a nozzle jacket that surrounds the material flow.

It is an essential advantage of the invention that no costs are required for the development of a new type of special shotcrete. A conventional, refractory pourable concrete can be used in order to apply it with the device according to the invention, ie to spray it. In addition, the preparation of the concrete mix is much easier. No double-piston pump or mixer is required. Fewer staff are required. The corresponding systems do not have to be transported and installed. With fewer system components, there are fewer hoses and less cleaning effort.

Another advantage is that there is no loss of concrete. The finished mixture is produced shortly before exiting the lance. As a result, the water consumption for cleaning the hoisting machine is also significantly lower, especially since the dry concrete is only conveyed pneumatically in the conveying line. The high proportion of air in the conveying section reduces the weight of the conveying line per metre.

Another advantage is that no time-consuming site preparation is required. A concrete conveyor machine is usually always present in the area of blast furnaces. It is used for gutter repairs with a special gunning compound. However, cast concrete has the advantage over this special gunning compound that it is denser and of a higher quality. The more densely the wall of the channel can be lined, the less slag and iron can penetrate the wall and wear out the wall. The concrete is usually applied to the hot channel and hardens immediately. The less water there is in the concrete mix, the faster the concrete hardens.

A further advantage of the method according to the invention is that there is no need to encase the channel wall. If formwork can be dispensed with, stripping can also be omitted. With the invention, therefore, intermediate repairs of the channel are possible quickly and easily. Downtimes of the blast furnace can be significantly reduced.

The device according to the invention is also particularly suitable for spraying coarse-grained material with a grain size of up to 19 mm. Material of this grain size cannot be processed with double-piston pumps because they would block. The very low water content of the material leads to a higher density and thus to a higher quality of the improvement work on the channel.

In a development of the invention, a nozzle ring is arranged at an outlet end of the lance, which is adjustable in the longitudinal direction of the lance. The nozzle ring is designed and configured to adjust the size of the spray cone of the concrete. The further the nozzle ring is pulled back in the direction of the lance, the larger the spray cone becomes. If the nozzle ring is pushed further forward, the spray cone of the concrete is reduced.

The air supply is advantageously used to form an annular air flow in an annular space between the nozzle ring and the lance, so that the size of the spray cone can be controlled by controlling the air flow alone without adjusting the nozzle ring.

In a development of the invention, it is provided that the water supply is ring-shaped, so that the water can be supplied to the concrete distributed over the circumference. The water supply is therefore preferably an annular nozzle arrangement with a plurality of outlet openings for the water arranged over the circumference of the flow channel. Due to the even supply of water, the dry mix of the concrete is wetted as evenly as possible and bonds with the concrete.

The binder is supplied in the direction of flow at a distance from the water supply. In an advantageous development of the invention, the binder feed is also designed in the form of a ring, so that the binder can also be fed to the concrete previously mixed with water, distributed over the circumference. The distance between the binder supply and the water supply can be 50 cm to 2 m. The mixing section only has to be long enough for the water to be sufficiently mixed with the relatively dry concrete mixture and for the binding agent to be absorbed evenly.

The quality of the finished concrete mixture depends largely on the addition of water and binder. The supply can be controlled via valves.

In an advantageous development, these valves for opening and closing the water supply, the binding agent supply and the air supply are located directly on the lance. The operator of the lance can control all three valve positions and readjust them while spraying the concrete in order to create an optimal mixing ratio for the concrete.

In a further development of the invention, it is provided that the valve for the water supply and the valve for the binding agent supply are arranged adjacent to one another at a distance of less than 30 cm, so that an operator of the lance only needs one hand to operate both valves while he is holding the spear with the other hand. The device according to the invention is designed for one-man operation. If the valves needed to operate are in close proximity, the concrete can continue spraying while the operator adjusts or dials the valve positions to get the right mix ratio.

In a further development of the invention, it is additionally provided that the valve for the air supply is also arranged at a distance of less than 30 cm from the other valves, so that an operator of the lance only needs one hand to operate the valves while he is working with holding the spear in his other hand. This concept is also based on one-man operation of the device. For ergonomic reasons, all necessary settings for operating the lance or the spraying device can be combined in such a way that the operator can always hold the lance with one hand and does not have to interrupt his work when the valves are actuated.

In a further advantageous development, the invention provides that the valve for the water supply, the valve for the binding agent supply and the valve for the air supply can be actuated via a single common actuating lever. All three gas and liquid flows can be stopped and started via a common actuating lever in the sense of a start-stop function. The respective valve positions can preferably be adjusted independently of one another in such a way that the desired mixing ratio results. The respective valve position can be adjusted independently of the actuating lever.

For one-man operation of the device according to the invention, it is advantageous if the lance has a cable cross-section of less than 50 mm, so that the lance can be carried and operated by a single person. The line cross-section of less than 50 mm preferably also continues in the area of the delivery line.

The lance according to the invention is, in particular, set up and designed to discharge refractory concrete and in particular to apply it to a hot tapping channel of a melting furnace. As mentioned above, the concrete used is, in particular a dry concrete, which can be transported by means of air within the conveyor line. There is no lower limit to the grit. In combination with a pneumatic rotor spraying machine, via which the concrete can be introduced into the delivery line, dry concrete with a grain size of up to 19 mm can be processed.

In an advantageous development of the invention, the rotor spraying machine includes a remote control for start-stop with regard to the concrete to be conveyed and the conveying air for conveying the concrete, with the remote control being arranged in the area of the valves for the water supply, the binding agent supply and the air supply .

In a development of the invention, the remote control and the valves can be actuated via a common actuating element.

With the device according to the invention, a possibility is created of discharging shotcrete, specifically with significantly fewer personnel and with less outlay on equipment. The loss of concrete due to cleaning of the device according to the invention is also significantly lower compared to the prior art.

The invention is explained in more detail below using a purely schematic representation of an exemplary embodiment.

The figure shows a device 1 for pointed concrete with a delivery line 2 in the form of a flexible transport hose. The transport hose has a diameter of preferably less than 50 mm, in particular a diameter of 45 mm.

A dry concrete mixture 3 is introduced pneumatically via a rotor spraying machine 4 into an inlet end 5 of the conveying line 2 and transported to the outlet end 6 thereof. The outlet end 6 is followed by a water supply 7 which is designed and set up to introduce water into a mixing section 8 which follows in the direction of flow of the concrete mixture 3 . The water supply 7 is ring-shaped, so that the water can be fed to the concrete distributed over the circumference. Several entry points for the water in the area of the water supply 7 are shown symbolically. It is an annular arrangement which surrounds the mixing zone 8 .

In the flow direction at a distance from the water supply 7 follows a ring-shaped binder supply, for example for the supply of silicate or water glass. Here, too, several inlet openings are shown as an example, so that the concrete mixture previously mixed with water can also be evenly wetted with the binders. The binder supply 9 is followed by a further mixing section 10 and finally an annular air supply 11. The air supply 11 builds up an annular air flow 12 between an outer casing of the lance 13 and a nozzle ring 14 that can be adjusted in the longitudinal direction of the lance 13 . Depending on the position of the nozzle ring 14 relative to the lance 13 or relative to the strength of the air flow 12, the size of the spray cone of the concrete can be influenced.

From the illustration it can be seen that valves 15, 16, 17 for the supply of water, binding agent and air are arranged relatively close together, in this case in the area of binding agent supply 9. Binding agent supply 9 is located approximately in the middle area between the preceding ones Mixing section 8 and mixing section 10 downstream in the flow direction. The distance between the valves 15, 16, 17 is preferably of the order of less than 30 cm. The actuation of the valves 15, 16, 17 can be combined with one another, so that a single-lever operation of all three material flows is possible. In addition, the air and material supply to the rotor spraying machine 4 can also be controlled via a remote control 18 for the rotor spraying machine 4 .

Reference List

1

Device for spraying concrete

2

delivery line

3

concrete mix

4

rotor spraying machine

5

entry end of 2

6

exit end of 2

7

water supply

8th

mixing section

9

binder supply

10

mixing section

11

air supply

12

airflow

13

lance

14

nozzle ring

15

Water supply valve

16

Binder supply valve

17

Air supply valve

18

Remote control for rotor spraying machine 4

Claims (16)

Device (1) for spraying concrete with the following features: a) a delivery line (2) which is set up and designed to receive concrete from an inlet end (5) and to convey it to its other outlet end (6), b) a lance (13) which is set up and configured to discharge the concrete by spraying; c) the lance (13) has an inlet end for the concrete fed in from the delivery line (2) and a water inlet (7) adjacent to this inlet end, the water inlet (7) being set up and designed to introduce water into the lance (13). so that the concrete mixes with the water in the lance (13) and the fluidity of the concrete within the lance (13) is increased; f) a binder feed (9) is connected to the lance (13) at a distance from the water feed (7) in the flow direction of the concrete, the binder feed (9) being set up and designed to introduce a binder into the water-enriched concrete; g) at a distance from the binder supply (9), an air supply (11) is connected to the lance (13), which is set up and designed to form an annular air flow (12) which has the size of a spray cone of the lance (13) escaping concrete. Device (1) after claim 1 , characterized in that at an outlet end of the lance (13) a nozzle ring (14) is arranged, which is adjustable in the longitudinal direction of the lance (13) and is designed and set up to adjust the size of the spray cone of the concrete. Device (1) after claim 2 , characterized in that the air supply (11) is set up and designed to introduce air into an annular space between the nozzle ring (14) and the lance (13). Device (1) according to one of Claims 1 until 3 , characterized in that the water supply (7) is ring-shaped, so that the water can be fed to the concrete distributed over the circumference. Device (1) according to one of Claims 1 until 4 , characterized in that the binder feed (9) is ring-shaped, so that the binder can be fed to the concrete distributed over the circumference. Device (1) according to one of Claims 1 until 5 , characterized in that the valves (15, 16, 17) for opening and closing the water supply (7), the binder supply (9) and the air supply (11) are arranged on the lance. Device (1) after claim 6 , characterized in that the valve (15) for the water supply (7) and the valve (16) for the binder supply (9) are arranged adjacent to each other at a distance of less than 30 cm, so that an operator of the lance (13) only needs one hand to operate both valves (15, 16) while holding the lance with his other hand. Device (1) after claim 6 , characterized in that the valve (15) for the water supply (7), the valve (16) for the binder supply (9) and the valve (17) for the air supply (11) are adjacent to each other at a distance of less than 30 cm are arranged so that an operator of the lance (13) only needs one hand to operate the valves (15, 16, 17) while holding the lance (13) with his other hand. Device (1) according to one of Claims 1 until 8th , characterized in that the valve (15) for the water supply (7), the valve (16) for the binding agent supply (9) and the valve (17) for the air supply (11) can be actuated via a single common operating lever. Device (1) according to one of Claims 1 until 9 , characterized in that the lance (13) has a cable cross-section of less than 50 mm, so that the lance (13) can be carried and operated by a single person. Device (1) according to one of Claims 1 until 10 , characterized in that the lance (13) is set up and designed to discharge refractory concrete. Device (1) according to one of Claims 1 until 11 , characterized in that the concrete transported via the conveyor line (2) is dry concrete which can be transported with air within the conveyor line (2). Device (1) according to one of Claims 1 until 12 , characterized in that it is designed and set up to spray dry concrete with a grain size of up to 19 mm. Device (1) according to one of Claims 1 until 13 , characterized in that the concrete can be introduced into the conveyor line (2) by means of a pneumatic rotor spraying machine (4). Device (1) after Claim 14 , characterized in that the rotor spraying machine (4) has a remote control (18) for start-stop in relation to the concrete to be conveyed and conveying air, the remote control (18) in the area of the valves for the water supply (7), the Binder supply (9) and the air supply (11) is arranged. Device (1) after claim 15 , characterized in that the remote control (18) and the valves (15, 16, 17) can be actuated via a common actuating element.

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