EP0061756A1 - Apparatus for the surface-treatment of buildings and ships - Google Patents

Abstract

PCT No. PCT/DE82/00070 Sec. 371 Date Nov. 30, 1982 Sec. 102(e) Date Nov. 30, 1982 PCT Filed Mar. 29, 1982 PCT Pub. No. WO82/03346 PCT Pub. Date Oct. 14, 1982.A device for treating the surfaces of structures and ships, even under water, with a spray medium which cleans, preserves, or coats, and is sprayed onto the surface which is to be treated by way of a pressurized gas flow via an at least partially flexible conduit which leads to the work location and is provided with an outlet nozzle. The outlet nozzle, which is constructed as a Laval nozzle, is provided with a funnel-shaped nozzle adapter which has a longitudinally extending, parabolic inner chamber. A controllable shunt, capable of bypassing the spray medium source may be provided for the pressurized gas between the pressurized gas source and the line leading to the outlet nozzle so that the device can be used under water.

Description

The invention relates to a device for the surface treatment of structures and ships, which can also be carried out under water, with a cleaning, preserving or coating blasting agent which is blasted onto the surface to be treated with a compressed gas stream via an at least partially flexible line leading to the workplace and provided with an outlet nozzle.

Compressed air blasting as free blasting is a proven method for surface treatment of the blasting material. The method requires a compressor as a compressed air source, a compressed air dryer, a compressed air filter, a blasting agent container for metering in the blasting agent and a hose line with a nozzle, which is usually a Laval nozzle. The performance of the process is determined by the parameter field air Delivery quantity of the compressor depending on the required final pressure, abrasive throughput, hose length, pressure in front of the nozzle and nozzle size.

When it comes to cleaning and roughening surfaces with only one use of the abrasive, typical working values under normal conditions are: 8 mm nozzle diameter, 25o mm distance from the surface of the blasting material and 8o mm blasting spot diameter, corresponding to about 5ooo mm ² Beam area. The abrasive throughput depends on the required surface quality. Understandably, less abrasive is required for cleaning than to achieve a bare metal surface with a certain roughness depth.

Experience of the inventors has shown that the effectiveness, or the ability to work, of the abrasive stream on the path between the nozzle outlet and the surface to be processed decreases very greatly, since the supersonic flow velocity is reduced very quickly to the subsonic area. The theoretically most favorable working distance from zero is in practice not feasible because the beam spot must not fall below a critical small area. However, this corresponds to a working distance, over the length of which the undesired reduction in jet speed already occurs.

• 1. Das Strahlmittel tritt nach der Beschleunigung in der Laval-Düse in ein Medium mit vielfach höherer Dichte ein. Dadurch verliert das beschleunigte Strahlmittel in verstärktem Maße an Geschwindigkeit, so daß es beim Auftreffen auf die zu bearbeitende Oberfläche kaum Wirkung zeigt, wenn zwischen Düsenaustritt und zu bearbeitender Oberfläche ein Wasserspalt vorhanden ist.
• 2. Eine Arbeitsverrichtung ist nur möglich durch Schrägansetzen der Laval-Düse unmittelbar auf die Oberfläche; damit wird der Strahlfleckdurchmesser gleich dem Düsenaustrittsdurchmesser. Für eine 8 mm-Düse beträgt die Strahlfläche unter Wasser nur etwa 5o mm² und es kann eine definierte Oberflächengüte mit bestimmter Rauhtiefe unter diesen Bedingungen nicht erzielt werden.
• 3. In der Laval-Düse tritt ein proportional zur Einsatztiefe zunehmender Gegendruck auf.

The above disadvantage also occurs when working in or under water. There are also other disadvantages as follows:

• 1. After the acceleration in the Laval nozzle, the abrasive enters a medium with a much higher density. As a result, the accelerated abrasive loses its speed to an increased extent, so that it has little effect when it hits the surface to be processed if there is a water gap between the nozzle outlet and the surface to be processed.
• 2. Work can only be carried out by placing the Laval nozzle diagonally on the surface; the jet spot diameter thus becomes equal to the nozzle outlet diameter. For an 8 mm nozzle, the jet area is under water only about 50 mm ² and a defined surface quality with a certain roughness depth cannot be achieved under these conditions.
• 3. In the Laval nozzle, a back pressure increases proportionally to the depth of use.

The above disadvantages arise not only in the case of a surface treatment with a cleaning abrasive, but also in the case of surface treatments with preserving or coating abrasives.

The object of the invention is to provide an improved device which, based on the prior art described above, gives the possibility of using such blasting methods with higher efficiency.

This object is achieved in that the outlet nozzle, which is designed in a manner known per se as a Laval nozzle, has a funnel-shaped, an elongated paraboloid-shaped interior space surrounding nozzle attachment is provided.

The tests of the device according to the invention show a significantly higher effectiveness, apparently due to increased jet speed.

According to a further development of the invention for underwater use, it is proposed according to the invention to provide an additional, controllable shunt for the compressed gas, which bypasses the blasting agent source, between the compressed gas source and the line leading to the outlet nozzle and thus to the surface to be treated.

The shunt provided according to the invention can be regulated so that the line leading to the underwater work station and the nozzle can be kept dry and free of water even in times without blasting agent supply. A relatively low excess pressure is sufficient for the compressed gas passed through the shunt, which ensures that the compressed gas bubbles out at all times at the free end of the outlet nozzle and thereby prevents water from entering.

Further details of the invention emerge from the subclaims.

An embodiment of the invention preferred for underwater use is explained below with reference to the accompanying drawings, for example.

• Fig. 1 eine schematische Darstellung der über und unter der Wasserfläche befindlichen Bauelemente der erfindungsgemäßen Vorrichtung zur Oberflächenbehandlung und
• Fig. 2 einen axialen Schnitt durch die Strahlmittelaustrittsdüse mit erfindungsgemäßem Düsenansatz.

The drawings show:

• Fig. 1 is a schematic representation of the components located above and below the water surface of the device for surface treatment and
• Fig. 2 shows an axial section through the blasting agent outlet nozzle with nozzle attachment according to the invention.

description

The blasting system shown in Fig. 1 contains a large part of conventional components. These conventional components include a compressor 1, which feeds the compressed air supply line 4 via a water separator 2 and an air filter 3.

Between the compressor 1 and the water separator 2 there is a pressure measuring point 5 and a shut-off valve 6. Conventional is also the blasting agent container 2o containing the blasting agent with a closable refill opening 21, a line 22 which pressurizes the blasting agent container and is provided with a control valve, which leads to the Supply line 4 is connected and also a pressure relief valve 23. When the refill opening 21 is open, the blasting agent to be used for cleaning, preserving or coating can be refilled from a storage container 24 via a feed line 25 or a funnel.

If underwater cleaning is to be carried out with the device according to the invention, the blasting agent container 24 contains quartz sand, corundum, copper slag, natural or artificial mineral granules, cork or the like. For the intended underwater use with only one use of the blasting agent, unlike in the case of open air blasting, blasting agents can also be used that have recently been used because of the danger to the respiratory tract of the worker operating the device may no longer be used or may only be used under special protective conditions.

The connection of the compressed air supply 4 to a blasting hose 8 leading to the work station, which ends at an outlet nozzle 9, which is preferably designed as a Laval nozzle, is also conventional.

For the underwater use provided according to the invention, in which the jet hose 8 leads below the water surface 40 to an underwater work station 41, at which a diver 42 is located, as shown in FIG. 2, a nozzle attachment 12 is attached to the Laval nozzle 9 connected. A sleeve 10 which overlaps the free end of the nozzle and is held releasably and interchangeably with screws 11 is used to fasten the nozzle attachment 12. The funnel-shaped nozzle extension 12 encloses an elongated paraboloid-shaped interior and has a length which is essentially the required working distance between Laval nozzle 9 and the corresponding surface 5o corresponds. For a nozzle attachment with a 5o mm outlet diameter, for example, this length is approximately 25o mm.

To ensure that the underwater device parts, that is the blasting hose 8, the blasting nozzle 9 and the blasting nozzle attachment 12, remain constantly dry and cannot run full of water, a shunt control 3o is provided according to the invention. This shunt control 3o is connected on the inlet side via a line 31 to the outlet of the air filter 3 and on the outlet side via a control valve 32 to a part of the supply line 4 located downstream of the blasting agent container. The line system 31-3o-32 thus bridges the part of the supply line 4 in which the blasting agent is fed into the supply line 4 via a discharge valve 26.

If the blasting agent container is not shut off, there is therefore the possibility of constantly flushing the underwater components of the device with a pressurized gas stream, so that no water can penetrate can. The compressed gas - preferably air - discharged into the blasting hose 8 via the shunt must have a pressure which is slightly above the water pressure at the place of use 41. In order to effect this pressure setting automatically, a control line 36 leads from the shunt 3o to the underwater work station. The pressure detected in the shunt 3o at a pressure measuring point 38 directly influences a control valve 35 of the shunt and adjusts it so that compressed air is constantly emitted in small quantities at the jet nozzle attachment 12. 1, additional pressure gauges 33 and 34 can be provided in the shunt control arranged above water in order to be able to read the normal working pressure and the reduced pressure in the shunt.

So that the blasting device can be switched on and off in the simplest possible manner by the diver at the underwater work station 41, there is a button 51 next to the blasting nozzle 9, with which a signal line 52 detects a water-borne nozzle Control unit 53 can be operated. The control unit 53 is used to switch on the blasting agent supply, ie the control unit 53 acts directly on the metering valve 26 of the blasting agent container 20 or, if this is permanently set, on the main shut-off valve 7 of the compressed air supply line 4. It is also possible to act on the shunt 3o with the control unit 53. As a rule, however, the shunt is left open, so that water cannot penetrate at the jet nozzle attachment when the blasting agent addition is switched on and off.

Both above-water and underwater operation resulted in significantly shorter working hours and improved surface qualities. For underwater operation was achieved for example in connection with the inventive compressed air by-pass and the nozzle attachment 12 in 1o m water depth the following performance: Strahlfäche about 22oo mm ^2, at a gas pressure of about 9 bar beam power: 3 m ² / h at a degree of purity Sa 2 1/2 (according to DIN 55928 part 4) and a roughness depth of 3o µm.

Overall, it can thus be ascertained that the device according to the invention leads to a safe and economical above- and underwater working method for standard-compliant surface treatment with a high degree of purity and required surface roughness while at the same time substantially increasing the area coverage and reducing the abrasive consumption.

Claims (5)

1.Device for surface treatment of structures and ships, which can also be carried out under water, with a cleaning, preserving or coating blasting agent which is blasted onto the surface to be treated with a compressed gas stream via an at least partially flexible line leading to the work station and provided with an outlet nozzle that the outlet nozzle (9), which is designed as a Laval nozzle in a manner known per se, is provided with a funnel-shaped nozzle attachment (12) surrounding an elongated paraboloid-shaped interior. 2. Device according to claim 1 for underwater use, characterized in that the length of the nozzle attachment (12) substantially the required working distance between. Nozzle (9) and the surface to be treated ( ₅₀ ) corresponds. 3. Device according to claim 1 and 2, characterized in that between the compressed gas source (1) and the outlet nozzle (9) leading line (4,8) an additional, the blasting agent source (2o) bypassing adjustable shunt (30) is provided for the compressed gas is. 4. Apparatus according to claims 1 to 3, characterized in that the controllable shunt (3o) is provided with a control line (36) leading to the underwater work station (4) and a pressure measuring device (38) which detects the water pressure and which does this via the shunt (30 ) keeps the pressure gas released at a pressure exceeding the water pressure. 5. Apparatus according to claim 1 to 4, characterized in that a remote control (51,52,53) is provided at the underwater work station (4) for the blasting agent delivery in the compressed gas stream.

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