CH713471B1 - Device for cleaning, engraving or removing coatings, graffiti or other surface dirt using abrasive blasting media on parts, workpieces or surfaces. - Google Patents

Abstract

The invention relates to a device for cleaning, engraving or removing coatings, graffiti or surface dirt using abrasive blasting agents on parts, workpieces or surfaces, for example walls, pillars, fences, facades, profiles, floors, ceilings, doors, stone furniture, concrete , wood, metal, plastic or glass. The device consists of a container (15) with the integrated components: a dry vacuum cleaner with fine dust filter (11) in the upper third of the container (15) with the other components, a hopper (14) lying under the fine dust filter (11) as the middle part container ( 14) with a flap (12), a sieve (13) underneath with a funnel-shaped reservoir (1) underneath for the blasting agent (2) and a dosing device (3) with adjoining air flow guide (4), and having a first connection on Container (15) at the level of the fine dust filter (11) for a suction hose (10), and a second connection on the container below the dosing device (3) with adjoining air flow guide (4) for a flexible suction hose (5). The suction hose (10) is connected to the first connection and a flexible suction hose (5) is connected to the second connection. There is also a jet hood (6) with one, two or more viewing windows (9) and with a jet lance (7) and connections for the suction connection (5) and for the suction hose (10).

Description

The invention relates to a device for cleaning, engraving or removing coatings, graffiti or surface contamination using abrasive blasting media on parts, workpieces or surfaces, in particular for cleaning surfaces of natural stones, tile cleaning, facade cleaning, staircase renovation, for removing paint coatings, Graffiti removal, solar module cleaning and for engraving a wide variety of materials such as stone, concrete, wood, metal, plastic or glass.

[0002] Document DE 197 47 838 C2 describes a method and a device for dry removal of coatings, graffiti or other surfaces. A blasting agent is formed by gravity from a storage tank in one is introduced within a carrying air flow guided by a hose line system formed from inlet and outlet lines, conveyed through this by means of negative pressure, thrown against the surface to be treated in a blasting chamber through a blasting lance, from there transported back into the carrying air flow in such a way that the blasting agent is circulated. The acceleration of the blasting medium is generated by the negative pressure applied to the blasting chamber and by increasing the blasting speed in an acceleration section by reducing the diameter of the supply line to the acceleration section. The vacuum supply line is connected to an acceleration pipe which runs in a straight line and forms an acceleration section, which is arranged upstream of the jet lance and which has a diameter device opposite the supply line.

The object of the invention is to improve essential structural elements of the known device according to DE 197 47 838 C2 in order to enable more effective cleaning of a wide variety of surfaces, further applications with the device and easier handling of the device.

With the changes and additions made, the possible uses of the device increase, the possibility of clogging from the suction hose is reduced to a minimum and the effectiveness and operator options of the jet hood is improved.

A dosing device consisting of a dosing disk with notches arranged offset every 45 degrees on the outer edge and nozzles with different diameters passing through the dosing disk in the direction of the center of the dosing disk and a handle in the center of the dosing disk enables rapid manual adjustment of the dosing disk to a desired flow rate for the abrasive. The dosing disk is arranged below a funnel-shaped reservoir. Furthermore, the dosing device includes a passage below the dosing disc, which lets the blasting agent through in the direction of the suction hose. Only a nozzle located centrally above the passage allows the blasting media to flow through. All other nozzles have no connection to the passage.

[0006] This dosing device can cause the blasting agent to accumulate. A vibrating unit attached to the outside can eliminate a possible jam. You can tell that a jam has occurred when no more blasting media escapes from the blasting lance.

An electrically conductive design of the suction hose and the suction hose can be neutralized again for certain blasting agents that are electrically charged by friction or when the blasting agent hits the surface to be cleaned. This avoids voltage flashovers. All parts, such as the housing, have electrical connections to the neutral conductor.

The jet lance on the jet hood is advantageously guided and held by an electrically conductive rubber seal. Similar effects are achieved here as with the electrically conductive version of the suction hose. Slidable and removable cover plates can be arranged inside or on the jet hood. These cover plates have, for example, a rod attached to one side, which is guided in a tube. Advantageously, a cover plate can be moved from right to left or vice versa and a cover plate can be moved from bottom to top or vice versa. This allows certain areas on the surface to be treated to be covered that should not be hit by the blasting agent.

The edge of the jet hood, which rests on the surface to be processed, advantageously has removable sealing rubbers with variable height and thickness. Several layers of sealing rubber can also be arranged one on top of the other. These are preferably connected to one another with Velcro. This results in areas that can be securely sealed despite the different heights. This can also be done by adapting the contact surface of the jet hood to the surface to be treated, e.g. by adapting to curvatures, profile shapes and/or angles. The adaptation of the contact surface does not have to match one hundred percent. The rubber seals can compensate for deviations. However, it is also conceivable that adapters are attached to the jet hood as attachments, which simulate a wide variety of shapes, such as semi-circles with a wide variety of radii for processing columns or posts.

[0010] Within the jet hood, electric light sources, preferably LEDs, are advantageously arranged in all four corners. The LEDs radiate with their beam direction in the direction of the surface to be processed. The result of the irradiation with the blasting agent can thus be easily checked by the operating personnel.

Several embodiments of the invention are illustrated in the accompanying drawings and are described in more detail below. They show: Fig. 1 a complete device in the basic structure, partially in section showing the jet hood and the connecting hoses, Fig. 2 the plan view of a metering disk of the metering device, Fig. 3 the side view of a metering disk, Jet hood in the area of the contact surface with two movable cover plates, FIG. 5 shows the detail of a jet hood with a curved contact surface and corresponding rubber seal, and FIG. 6 shows the detail of a jet hood with a cover surface angled by 90 degrees.

The device is mobile and is mounted on a carriage 24 for this purpose. The container 15 of the device is advantageously divided into three parts: in the upper third of the container 15 there is a dry vacuum cleaner with a fine dust filter 11, in the middle part a middle part container 14 with a hopper 14 and in the lower third a funnel-shaped storage container 1 with a dosing device 3. These three parts are preferably connected to one another with bayonet locks and can therefore be easily detached from one another for maintenance work. In the upper third of the container 15, the suction hose is connected as a connection between the emitting hood and the container 15. The dry vacuum cleaner with the fine dust filter 11 sucks the used abrasive 2, e.g. in the form of granules 2, and the removed dirt particles 25 out of the suction hose 10. The fine dust is collected on the fine dust filter 11, larger dirt particles 25 fall onto the sieve 13 and can be disposed of from there later. The granulate 2 can be collected in the central part container 14 or is guided further to the funnel-shaped storage container 1 via this. The use of a wide variety of blasting agents 2, e.g. shredded plant residues, can lead to bridging in the funnel-shaped storage container 1. In order to avoid or eliminate this bridging, a vibration unit 16 is attached to the outer wall of the funnel-shaped storage container 1 . The head of the device also accommodates the operating elements 26 and display instruments 26, among other things. From here, for example, the vibration unit 16 is also switched on and off manually. If the blasting agent 2 bridges, no more blasting agent escapes from the blasting lance 7 of the blasting hood 6 . The operator can then switch on the vibration unit 16 for a short time.

Below the funnel-shaped reservoir 1, a metering device 3 is arranged in a circular, open-topped body. This body has a protruding holder 28 which engages in a desired detent 17 of the dosing disk 27 of the dosing device 3 and thus prevents the dosing disk 27 from twisting while the device is working. The detents 17 are arranged offset by 45 degrees on the outer circumference of the manually adjustable metering disk 27 . Nozzles 18 with different nozzle diameters, which are assigned to the detents 17 and pass through the metering disk 27, are incorporated in each case. The circular body of the dosing device 3, which is open at the top, has an opening leading down to the suction hose 5.

This opening only releases a nozzle 18 of the metering disc 27 arranged above it. The metering disc 27 can be easily removed from the open body by means of a handle 23, rotated to select a desired nozzle size and reinserted into the open body. The nozzle size then determines the amount of blasting agent 2 that later emerges from the blasting lance 7 and is available for processing the surface 8 to be processed.

The suction hose 10 and the suction hose 5 between the jet hood 6 and the housing 15 are advantageously designed to be electrically conductive. This means that electrically charged blasting media 2 can be discharged again.

An electrically conductive rubber seal is also advantageously provided between the jet lance 7 and the jet hood 6 .

Within or on the jet hood 6 in the direction of the surface to be processed 8, sliding and removable cover plates 19, z. B. each consisting of a metal sheet 19 with a rod 20 attached to one side, guided in a tube 21 through the outer shell of the jet hood 6 can be arranged. As a result, certain areas of the surface 8 to be machined that are not to be machined can be covered.

The edge of the jet hood 6 to the surface to be processed 8 is advantageously provided with removable rubber seals 22 made of sponge rubber with variable height and thickness or several layers of rubber seal 22 one above the other. These rubber seals 22 are preferably connected to one another or to the jet hood 6 by means of Velcro. The contact surface of the jet hood 6 can be adapted to the surface 8 to be processed, e.g. in terms of curvature, profile design and angle. It is logical that jet hoods 6 that have been adapted in each case must then be used for this work. Another variant of the design is that 6 attachments can be attached to the jet hood as adapters, which have a wide variety of shapes, adapted to the shapes of the surfaces to be processed, such as curves, columns, angled surfaces, etc. These adapters can be quickly replaced and can definitely have deviations, since the rubber seals 22 compensate for them. This adapter variant saves costs compared to a complete jet hood change with the most diverse forms of the contact surface.

Within the jet hood 6, electric lamps, preferably LEDs, can be arranged in all four corners, which radiate with their beam direction in the direction of the surface 8 to be processed. Due to the arrangement on four sides, no shadows are formed by the jet lance 7. Due to the arrangement of the lamps in the vicinity of the surface 8 to be processed, unevenness can be better recognized by the light shining in from the side.

Compilation of reference numbers

1 funnel-shaped reservoir 2 blasting media, granules 3 dosing device 4 air flow guide 5 suction hose 6 blast hood 7 blasting lance 8 surface to be treated 9 viewing window 10 suction hose 11 fine dust filter 12 flap 13 sieve 14 discharge hopper, central part container 15 container 16 vibration unit 17 latches 18 nozzle 19 cover plate, Sheet metal 20 Rod 21 Pipe 22 Rubber seals 23 Handle 24 Trolley 25 Removed dirt particles 26 Operating elements, display instruments 27 Metering disk 28 Bracket

Claims (10)

1. Device for cleaning, engraving or removing coatings, graffiti or surface dirt using abrasive blasting media on parts, workpieces or surfaces, for example walls, pillars, fences, facades, profiles, floors, ceilings, doors, furniture made of stone, concrete, wood , metal, plastic or glass, consisting of a container (15) with the integrated components: - a dry vacuum cleaner with fine dust filter (11) in the upper third of the container (15) with the other components, - A below the fine dust filter (11) lying hopper (14) as a middle part container (14) with a flap (12), - An underlying sieve (13) with an underlying funnel-shaped reservoir (1) for the blasting agent (2) and a metering device (3) with adjacent air flow guide (4), - A first connection on the container (15) at the level of the fine dust filter (11) for a suction hose (10), a second connection on the container (15) below the dosing device (3) with adjacent air flow guide (4) for a flexible suction hose (5), - The suction hose (10) being connected to the first connection on the container (15) and the flexible suction hose (5) being connected to the air flow guide (4), and - A jet hood (6) with one, two or more viewing windows (9) and with a jet lance (7) and connections for the suction hose (5) and the suction hose (10) are present. 2. Device according to claim 1, characterized, that a vibration unit (16) is arranged on the funnel-shaped storage container (1). 3. Device according to one of the preceding claims, characterized, that the dosing device (3) consists of a manually adjustable dosing disk (27) with latches (17) arranged on the outer circumference, each offset by 45 degrees, and associated nozzles (18) with different nozzle diameters passing through the dosing disk (27), and is inserted within a circular, upwardly open body with a holder (28) and downwardly leading opening to the suction hose (5). 4. Device according to one of the preceding claims, characterized, that the suction hose (10) is designed to be electrically conductive. 5. Device according to one of the preceding claims, characterized, that the jet lance (7) on the jet hood (6) is guided through an electrically conductive rubber seal. 6. Device according to one of the preceding claims, characterized, displaceable and removable cover plates (19), each consisting of a plate (19) with a rod (20) fastened to one side and guided in a tube (21), are arranged inside or on the jet hood (6). 7. Device according to one of the preceding claims, characterized, that at the edge of the jet hood (6) to the surface (8) to be processed, removable sealing rubbers (22) with different heights and thicknesses or several layers of sealing rubber (22), preferably with Velcro, are arranged. 8. Device according to one of the preceding claims, characterized, that the bearing surface of the jet hood (6) to the surface to be processed (8) z. B. is adjusted in terms of curvature, profiles and angles. 9. Device according to one of the preceding claims, characterized, that on the jet hood (6) adapter can be attached as attachments with differently designed contact surfaces. 10. Device according to one of the preceding claims, characterized, that inside the jet hood (6) in all four corners electric lamps, preferably LEDs, are arranged, which radiate with their beam direction in the direction of the surface (8) to be processed.