DE4206587A1 - Nozzle for producing cleaning jet of compressed air and liquid mixture - is in two parts with intermediate annular gap into which is sucked atomised liquid from nozzle surroundings to joint emerging jet - Google Patents

Abstract

The incoming compressed air and liquid mixture passes through a first nozzle piece (16) with an outlet (22). A second, replaceable nozzle piece (28) is positioned just behind the first nozzle piece to create an annular entrance gap (30). The passage of the compressed air and liquid mixture through the nozzle causes a pressure drop at the gap (30) and atomised liquid from the intermediate surroundings of the nozzle is sucked in directly or through a filter (44) to join the emerging jet. USE/ADVANTAGE - Better utilisation of cleaning liquid.

Description

The invention relates to a device for generating a under pressure standing fluids such as compressed air or compressed air-liquid mixture at least in particular cleaning objects, comprising a compressor, a liquid keitsquelle and at least one nozzle emitting the compressed fluid, which via a (First) line connected to the compressor, according to patent. . . . (Patent application P 41 22 864.2).

With that in the patent. . . . (Patent application P 41 22 864.2) device described the compressed fluid in successive steps with different Temperatures affect the cleaning object or the object to be treated. In Depending on the respective temperature, the fluid can have different aggregates have conditions with which the desired object has certain desired effects  gene are caused. The compressed fluid is e.g. B. in the steam state on the directed each object before the object is exposed to liquid fluid, the z. B. can have a temperature close to 0 ° C. This makes it possible not only to add objects clean, but also to change, in which z. B. shells are removed.

The invention is based on the problem of a device according to the patent (Patent application P 41 22 864.2) to develop so that a particularly effective Flow of fluid and air to act on one or more objects is available.

The object is achieved in that the nozzle has an outlet that has at least one opening through which is sucked in from the vicinity of the nozzle Fluid and / or sucked-in air can be added to the fluid stream discharged from the nozzle is. If fluid is supplied to the object to be treated under high pressure, atomized fluid also gets close to the nozzle. The nozzle comes out certain vacuum, through which air and atomized fluid from the nozzle environment is suctioned off and added to the fluid stream. In this way, the for the Treatment of the object or the objects available quantity of fluid better exploited, d. H. less fluid is lost if there is no recovery with reprocessing is provided, or it must be in a device with recovery and recovery Preparation of the fluid can be reprocessed less if the same cleaning effect should be achieved.

In a preferred embodiment it is provided that the nozzle is a first nozzle part with an outlet, behind which, separated by the opening, a second nozzle part is interchangeably arranged with another outlet. The second nozzle part with  the further outlet can be specially adapted for the respective application.

Various nozzle parts are available for the different applications. The second nozzle part can be one that is suitable for generating a point jet Have exercise. It is also possible that the second nozzle part is one for production of a flat jet has a suitable outlet. Furthermore, the second nozzle part can be so train that the effect of a reversing nozzle is created.

A prechamber is preferably arranged at the opening, which leads to the environment Nozzle has at least one suction opening filled by a filter. The Filter prevents the dirt particles from being sucked out of the surrounding fluid Particles are added to the fluid stream emitted by the nozzle.

However, there are applications in which no dirt particles are treated by the th surface can be separated. Then it is not necessary to use a nozzle with one Pre-chamber and filters to be provided at intake openings.

It is advantageous if the outlet opening at least one nozzle on the gap in front of the Contact point of the ends of bristles of a rotating cylindrical brush and an area to be treated. The fluid acts on both Bristle ends as well as on the surface to be treated, which has the effect on the Area is improved. Instead of a brush, a cleaning fleece can also be used Sponge or similar mechanical cleaning arrangement used will.

In the case of a device having an independent inventive content, the  Nozzle arranged in a rotatably mounted rotor, which one run towards the nozzle has the channel for the fluid and rotates with the flowing fluid baren surfaces is provided, the nozzle in the middle of a pot-like brush is arranged. In this device, the nozzle preferably has the one described above characteristics. The fluid rotates the brush. In addition to one Movement along an area to be treated becomes intense due to the rotation Treatment of this surface achieved.

In particular, the channel is provided with a spiral bridge and stands on its End facing away from the plate a plate-shaped end of a supply pipe for the Fluid with bores opposite to the axis of rotation. With this arrangement a less complex, economical drive of the brush can be achieved.

In another preferred embodiment, at least two nozzles are longitudinal Direction of a bristle holding plate of a hand-held and guidable brush arranged, each on the side of the bristle holding plate facing away from the bristles contains a cavity in front of each nozzle, the cavities having openings via are connected to a feed channel that runs through a handle that connects to one Hose can be connected. This device can in particular work with a nozzle as in the patent. . . . (Patent application P 41 22 864.2) is described. Especially this device works well with the nozzles explained above. The above be Written handheld device can be used in many ways. The duration of exposure to the Fluids on a patch can vary in length depending on how dirty they are.

With the device of brushes and nozzles explained above, numerous can be Items, e.g. B. containers for bottles or food, glass objects, streets  Clean coverings, plates, walls, tiles, etc.

Further details, advantages and features of the invention do not only result from the claims, from the features to be extracted - for themselves and / or in Combination - but also from the following description of a drawing preferred preferred embodiments.

Show it:

Fig. 1, the half of a first nozzle half and a second nozzle for dispensing a pressurized fluid, in longitudinal section,

Fig. 2 shows an apparatus for cleaning objects with nozzles according to Fig. 1 from above,

Fig. 3 shows a device for cleaning objects in a side view, partly in section,

Fig. 4 shows an enlarged detail of the device shown in Fig. 3,

Fig. 5 shows another embodiment of a device for cleaning Ge objects in side view, partly in section.

In Fig. 1, a first nozzle ( 10 ) is shown with a half to the left of a center line ( 12 ). A second nozzle ( 14 ) is shown in FIG. 1 to the right of the center line ( 12 ), which runs in the longitudinal direction of the respective nozzle. The nozzles ( 10 ), ( 14 ) are components of devices for generating and dispensing pressurized fluids, e.g. B. compressed air or compressed air-liquid mixtures, with which in particular objects are cleaned. Both high and low pressure values can be considered as pressure values.

The nozzle ( 10 ) has a first nozzle part ( 16 ), which consists of a body made of nozzle material such as hard metal, ceramic or aluminum, which is hard anodized.

After the rotationally symmetrical nozzle part ( 16 ), a nozzle with a nozzle inlet ( 18 ), a constriction ( 20 ) and an outlet ( 22 ) is provided. The end ( 24 ) of the nozzle part ( 16 ) surrounding the nozzle inlet ( 18 ) is cylindrical and has an external thread with which a coupling ( 26 ) is screwed, to which a pipe or hose, not shown, is connected. The tube or hose runs to a liquid source or a compressor, as described in the patent (patent application P 41 22 864.2).

A second nozzle part ( 28 ) - as seen in the direction of flow of the fluid - is arranged behind the first nozzle part ( 16 ). The nozzle part ( 28 ) is separated from the nozzle part ( 16 ) by an opening ( 30 ) and contains a further outlet ( 32 ). The opening ( 30 ) is located, in particular, at the narrow point of a rotationally symmetrical nozzle-like inlet point ( 34 ) surrounding the end region of the nozzle part ( 16 ), which starts from a space ( 36 ) that is open to the surroundings of the nozzle ( 10 ). The nozzle part ( 28 ) has, near the end of the nozzle part ( 16 ), an outer, unspecified shoulder, against which a ring ( 38 ) is leaned, with which at least two or three struts ( 40 ) arranged at equal intervals along the circumference are connected, which are attached to the nozzle part ( 16 ) at the other ends. The outlet ( 32 ) has the same angular position as the outlet ( 22 ) at least in the region of the end of the nozzle part ( 28 ). The ends of the struts ( 40 ) are screwed onto the nozzle part ( 16 ), ie releasably connected to the nozzle part ( 16 ). Therefore, nozzle parts ( 28 ) can be connected to the nozzle part ( 16 ) with differently formed outlets. In this way, a nozzle part can be connected to the nozzle part ( 16 ) in order to generate a point jet. Or a nozzle part which is designed to generate a flat jet is connected to the nozzle part ( 16 ). Another possibility is to connect a nozzle part, with which a reversing nozzle is realized, to the nozzle part ( 16 ).

With the nozzle ( 10 ) is from the fluid stream that from the z. B. conical or cylindrical shaped spout (22) emerges, via the opening (30) air and entrained therein fluid particles from the vicinity of the nozzle (10) is sucked due to negative pressure in the opening (30) and admixed to the fluid stream. This makes it possible to suck in sprayed fluid, which is thrown back in droplet or mist form after the impact on a surface to be treated, and use it again by adding it to the fluid stream coming from the nozzle part ( 16 ). This creates a fluid flow at a very high speed, the cross section of which increases. A core remains in the fluid flow, which consists almost entirely of fluid, while a fluid-air mixture is created on the outside, which, like the core, has a high speed. In Fig. 1, a line is shown in broken lines in the nozzle part ( 28 ), which shows that preferably the wall of the outlet ( 32 ) has a certain distance from the imaginary cone, which forms the continuation of the outlet ( 22 ). The dashed line represents the continuation of a line running in the longitudinal direction of the wall of the outlet ( 22 ), which corresponds to the section line in the illustration. This creates an energy-rich flow of fluid and air, which also removes stubborn particles that adhere stubbornly to the parts to be treated.

The nozzle ( 14 ) has a first and second nozzle part, which are of the same design as the nozzle parts of the nozzle ( 10 ). The same reference numerals are used in the figures for identical parts. The nozzle ( 14 ) can also be connected to a coupling ( 26 ) of the same design. In the nozzle ( 14 ) there is a prechamber ( 42 ) on the side next to the nozzle part ( 16 ), which has struts (not shown in detail) that are curved outwards, one end of which rests against the ring of the nozzle part ( 28 ) and the other of which Ends are attached to the nozzle part ( 16 ). A filter ( 44 ) is arranged between these or above these struts, which is impermeable to solid particles, but allows fluid particles in the form of drops or mists to pass through. In this way it is prevented that the dirt particles detached from a surface to be treated can get into the fluid flow. The filter ( 44 ) runs as a wall of the front chamber ( 42 ) rotationally symmetrically in an arc around the nozzle ( 14 ). Therefore, the filter has a large surface area, so that the flow resistance is low.

In the device shown in Fig. 2, a probe brush roller ( 46 ) is provided which over a roof ( 48 ), for. B. a vehicle such as a car, truck, bus trailer, etc. is moved. The probe brush roller ( 46 ) is rotatably mounted in stands ( 50 ). The vehicle is moved along the key brush roller ( 46 ). Two nozzles ( 14 ) are arranged in front of the key brush roller ( 46 ) symmetrically to the latter. The longitudinal axes ( 52 ) of the nozzles ( 14 ) run obliquely to the axis of rotation of the key brush roller ( 46 ). The openings of the nozzles ( 14 ) are directed towards the gap in front of the point of contact of the ends of the bristles of the rotating key brush roller ( 46 ) and the roof ( 48 ). It is the gap where the bristles move towards the roof ( 48 ). For example, the key brush roller ( 46 ) has the direction of rotation indicated by the arrow ( 54 ). An air-water mixture emerging from the nozzles ( 14 ), which can be warm and cold according to a predetermined cleaning program, strikes the roof ( 48 ) and the ends of the bristles of the key brush roller ( 46 ). The air-water mixture can be means such. B. detergent may be added. The lower half of FIG. 2 shows a section of the gap ( 56 ) into which the air-water mixture reaches. In the same way as for the roof ( 48 ), devices (not shown) can be provided for cleaning the side walls ( 58 ) of the vehicle.

Fig. 3 shows a rotatably mounted, pot-like brush ( 60 ) having a bristle holder plate ( 62 ), in the middle of which a nozzle ( 10 ) or ( 14 ) is arranged. The nozzle ( 10 ) or ( 14 ) sits at one end of a rotor ( 64 ) which is connected to the bristle holder plate ( 62 ). The rotor ( 64 ) is rotatably mounted in a pot-like housing ( 66 ) by means of roller bearings ( 68 ). A tube ( 70 ) in which the fluid is supplied runs through the bottom of the housing ( 66 ). The tube ( 70 ) ends in the interior of the housing ( 66 ) in front of the rotor ( 64 ), which has a central channel ( 72 ) for the supply of fluid to the nozzle ( 12 ) or ( 14 ). At one end of the tube ( 70 ) there is a plate-shaped closure ( 74 ) in which there are a plurality of nozzle channels or bores ( 76 ) which are arranged at regular intervals along a circle. The bores ( 76 ) are arranged with their longitudinal axes inclined to the axis of rotation ( 78 ) of the rotor ( 72 ). A spiral piece ( 80 ) is located in the channel ( 72 ). The fluid is fed via the bores ( 76 ) to the helix ( 80 ), which is rotated and takes the rotor ( 64 ) with it.

On the outside of the rotor ( 64 ) a bushing ( 82 ) is attached, which consists of bronze or ceramic. Inside the housing ( 66 ) on the outside of the tube ( 70 ) a bushing ( 84 ) is slidably mounted longitudinally, which is pressed under the force of a spiral spring ( 86 ) with an end face against the end face of the bushing ( 82 ). The end faces of the bushings ( 82 ), ( 84 ) slide on each other when the rotor ( 64 ) rotates and are designed as finely lapped sealing surfaces. The bushing ( 84 ) is also designed as a bronze or ceramic sliding ring. The bushings ( 82 ), ( 84 ) are matched to one another in such a way that a bronze-ceramic sealing pair or a hard metal-ceramic sealing pair or other suitable pairings of sliding materials are produced. Silicon carbide can be used as the ceramic material. The bushing ( 82 ) is fastened to the rotor ( 64 ) by means of retaining pins ( 88 ). Retaining pins ( 90 ) are provided for fastening the bushing ( 84 ) to the rotor ( 70 ). In the housing ( 66 ), a nut ( 92 ) is screwed centrally to the tube ( 70 ), to which one end of the spring ( 86 ) lies. The other end of the spring ( 86 ) rests on a flange-like shoulder of the bushing ( 84 ). With the nut ( 92 ) the contact pressure between the bushings ( 82 ), ( 84 ) can be adjusted.

The nozzle ( 12 ) or ( 14 ) sprays an air-water mixture in the direction of an object ( 94 ) to be treated, on which the ends of the bristles ( 96 ) slide. The deflection of the jet emerging from the nozzle ( 12 ) or ( 14 ) also leads fluid to the ends of the bristles ( 96 ). The lateral deflection of the beam also depends on the speed of rotation of the rotor ( 64 ).

FIG. 5 shows a brush (98) is held on a handle (100) in the hand. The handle ( 100 ) is provided with an inner channel and is connected via a coupling ( 102 ) which can be screwed onto one end to a hose ( 104 ) which is connected to a liquid source. The brush ( 98 ) has a bristle holding plate ( 106 ) in which two nozzles ( 12 ) and ( 14 ) are inserted at a distance from one another. On the side of the bristle holder plate ( 106 ) facing away from the bristles ( 108 ), two cavities ( 110 ) are provided in the region of the nozzles ( 12 ) and ( 14 ), which are separated from one another by a distributor web ( 112 ), the tip of which is in one Opening ( 114 ) protrudes, which is arranged at the end of the feed channel for the fluid running in the handle ( 100 ).

The handle ( 100 ) ends in a feed piece which is formed in one piece with the bristle holder plate ( 106 ) and which contains the opening ( 114 ).

A fluid is supplied to the brush ( 98 ) via the hose ( 104 ). The fluid has different temperatures depending on the work program. The nozzles ( 12 ) and ( 14 ) spray the fluid and also wet the bristles ( 108 ).

In the illustrated in Fig. 3, Fig. 4 and Fig. 5 devices are used (14) as shown in Fig. 1, preferably nozzles (12). However, other nozzles can also be used.

The devices described above are suitable for cleaning objects made of metal, plastic, glass, ceramic and the like. Brush-nozzle systems can also used for cleaning road surfaces, walls, slabs, tiles, etc. will. For some applications, nonwovens, sponges or the like can be used Objects can be used instead of brushes. Dirt films can pass through remove subsequent, light spraying, after which the water drops can be suctioned off. The nozzle system can also be used for fruits, vegetables, tubers or root crops can be cleaned and peeled at different temperatures. At Low pressure and predominantly high water content can e.g. B. leaves, medicinal herbs cleaned particularly gently.

Claims (12)

1. Device for generating a pressurized fluid such as compressed air or compressed air-liquid mixture for at least in particular cleaning objects, comprising a compressor, a liquid source and at least a nozzle emitting the compressed fluid, which via a (first) line connected to the compressor, according to patent. . . (Patent application P 41 22 864.2), characterized in that the nozzle ( 12 , 14 ) has an outlet which has at least one opening through which fluid and / or air drawn in from the vicinity of the nozzle can be added to the fluid stream discharged from the nozzle is. 2. Device according to claim 1, characterized in that the nozzle ( 12 , 14 ) has a first nozzle part ( 16 ) with an outlet ( 22 ), behind which, separated by the opening ( 30 ), a second nozzle part ( 28 ) a further outlet ( 32 ) is interchangeably arranged. 3. Apparatus according to claim 1 or 2, characterized in that the opening ( 30 ) constriction behind a on the first and second nozzle part ( 10 , 14 ) formed, nozzle-like, rotationally symmetrical inlet point ( 34 ). 4. Device according to one or more of the preceding claims, characterized in that the second nozzle part ( 28 ) has an outlet for generating a point jet. 5. The device according to one or more of claims 1 to 3, characterized in that the second nozzle part ( 28 ) has a spout formed for the production of a flat jet. 6. The device according to one or more of claims 1 to 3, characterized in that the second nozzle part ( 28 ) has an outlet designed for the production of a reversing nozzle effect. 7. The device according to one or more of the preceding claims, characterized in that a prechamber ( 42 ) is arranged at the opening ( 30 ), which towards the surroundings of the nozzle ( 12 , 14 ) at least one suction filled by a filter ( 44 ) opening. 8. The device according to one or more of the preceding claims, characterized in that the outlet opening of at least one nozzle ( 12 , 14 ) is directed to the gap ( 56 ) in front of the contact point of the ends of bristles of a rotating cylindrical brush and a surface to be treated. 9. The device in particular according to one or more of claims 1 to 7, characterized in that the nozzle ( 12 ) is arranged in a rotatably mounted rotor which has a channel for the fluid running towards the nozzle and can be set in rotation by the flowing fluid Is provided surfaces, and that the nozzle ( 12 ) is arranged in the middle of a pot-like brush. 10. The device according to claim 9, characterized in that the channel is provided with a spiral web ( 80 ) and at its, the nozzle ( 12 ) facing away from a plate-shaped end ( 76 ) of a feed pipe ( 70 ) for the fluid with obliquely to The axis of rotation ( 78 ) is opposite bores ( 76 ). 11. The device according to claim 9 or 10, characterized in that on the outside of the rotor ( 64 ) a sleeve ( 82 ) is fixed with a sliding surface against which a sliding surface of a further sleeve ( 84 ) is pressed, which is longitudinally displaceable on the tube ( 70 ) is attached for the supply of the fluid. 12. The device in particular according to one or more of claims 1 to 7, characterized in that at least two nozzles ( 12 ) in the longitudinal direction of a bristle holding plate ( 106 ) of a hand-held and guided brush ( 98 ) are arranged, each on the bristles ( 108 ) opposite side of the bristle holding plate ( 106 ) in front of each nozzle ( 12 ) contains a cavity ( 110 ), and that the cavities ( 110 ) are connected via openings with a supply channel which runs through a handle ( 100 ), the a hose ( 104 ) can be connected.