DE9208796U1 - Jet nozzle for high-pressure cleaning equipment - Google Patents

Description

Gesthiiysen & von Rohr

The invention relates to a jet nozzle for high-pressure cleaning devices according to the preamble of claim 1. The invention also relates to an additional unit for such a jet nozzle.

Jet nozzles of the type in question have long been known in many different designs, as an example the jet nozzle known from DE 89 10 907 U. Jet nozzles of this type are arranged or are to be arranged at the front end of a high-pressure hose or a high-pressure spray pipe and are usually connected there via a screw connection. For this purpose, the water inlet of the housing often has an internal thread. The high pressure at the water outlet of the jet nozzle is achieved by a high-pressure nozzle with a strongly drawn-in flow cross-section, the nozzle channel of which in most cases has a circular cross-section, although it is also conceivable that the cross-section deviates from the circular shape for flat jet generation.

The flow of liquid through the jet nozzle is usually controlled by a valve gun, i.e. it is switched on and off. After switching off, the pressure-free liquid column remains in the high-pressure hose or spray pipe and the jet nozzle, reaching as far as the mouth of the nozzle channel in the high-pressure nozzle. If the high-pressure cleaning device is not used for a long time, the inside of the jet nozzle dries out from the mouth of the nozzle channel, and impurities in the water and in particular calcium crystals settle. The neuralgic area is of course the area with the smallest cross-section, i.e. the nozzle channel of the high-pressure nozzle. Corrosion also sometimes occurs there. Overall, it is found that if a high-pressure cleaning device is not used for a long time, the high-pressure nozzle in the jet nozzle is often clogged or at least its cross-section is greatly reduced. The result is a low-pressure and in any case very dirty liquid jet.

Gesthiiysen & von Rohr

The invention is based on the task of designing the jet nozzle explained at the beginning in such a way that even after a long period of non-use of the high-pressure cleaning device, the high-pressure nozzle functions perfectly.

The previously indicated task is solved in a jet nozzle with the features of the generic term of claim 1 by the features of the characterizing part of claim 1. The closure element provided according to the invention closes the high-pressure nozzle as soon as the liquid column in the high-pressure hose or the spray pipe and the jet nozzle becomes pressureless (practically pressureless) and the liquid flow through the high-pressure nozzle stops. The movement of the closure element supports the emptying of the nozzle channel in the high-pressure nozzle to the outside, while at the same time preventing impurities and in particular calcium crystals from the liquid column in the jet nozzle from settling on the edge of the nozzle channel and in the nozzle channel of the high-pressure nozzle. This ensures that even if the high-pressure cleaning device is not used for a long time, the neuralgic area of the jet nozzle is protected and that when the cleaning device is switched on again, a high-pressure jet of unchanged quality can immediately emerge from the high-pressure nozzle.

Preferred embodiments and further developments of the jet nozzle according to the invention are the subject of the subclaims. The closure element according to the invention for the high-pressure nozzle can also be arranged in an additional unit for a jet nozzle of the type in question, so that this additional unit is available as a retrofit part for existing jet nozzles.

In the following, the invention is explained in more detail using a drawing that merely shows exemplary embodiments. The drawing shows

Fig. 1 shows a schematic representation of a high-pressure cleaning lance with a jet nozzle,

Gesthuyson & von Rohr

Fig. 2 shows an embodiment of a jet nozzle according to the invention in section, the area of the nozzle channel of the high-pressure nozzle shown again enlarged, and

Fig. 3 a retrofittable additional unit for equipping an otherwise commercially available jet nozzle according to the invention, also in section.

Fig. 1 shows a schematic of a high-pressure cleaning lance 1, to the head of which a jet nozzle 2 is attached, here screwed on. This serves to illustrate the use of such a jet nozzle as an example. The high-pressure cleaning lance 1 comprises an angled spray pipe 3 with an additional handle 4 serving as contact protection and a valve gun 5, to which a high-pressure hose 6 is connected on the inlet side. The high-pressure hose 6 leads to a high-pressure cleaning device (not shown in more detail) with a pump, chemical supply, heating device or the like. The subject of the invention is the jet nozzle 2.

Fig. 2 shows an embodiment of a jet nozzle 2 according to the invention in section. This jet nozzle 2 has a pressure-resistant housing 7, which in the embodiment shown consists of several parts, partly made of metal, partly of plastic, which will be explained in more detail later. The housing 7 is circularly cylindrical here and has a water inlet 8 on one end and a water outlet 9 on the other end. At the water inlet 8, not shown in detail here, a threaded connector with an internal thread for screwing onto the spray pipe 3 is provided. Other designs of jet nozzles 2 are screwed into the spray pipe 3 with an external thread. A high-pressure nozzle 10 is arranged in the housing 7 associated with the water outlet 9, the nozzle channel 11 of which here and in most cases has a circular cross-section.

en & from Rohr

The teaching of the invention is applicable to jet nozzles 2 that only have the housing 7 with the high-pressure nozzle 10 located therein, but the illustrated embodiment of a jet nozzle 2 has some special features that are explained below only for the sake of understanding, but are not of essential importance for the teaching of the invention.

The housing 7 here consists of an inner housing 12 made of metal, at the end of which facing the water outlet 9 the high-pressure nozzle 10 is screwed in by means of a thread. The inner housing 12 is directly connected to the spray pipe 3 during operation, it can be moved longitudinally in a nozzle body 13 made of plastic. The inner housing 12 has a liquid flow channel 14 extending in the axial direction from the water inlet 8 to the high-pressure nozzle 10, to which radially branching transverse channels 15 are connected near the high-pressure nozzle 10, which open into an annular space 16 in the nozzle body 13. The annular space 16 is axially sealed both towards the water inlet 8 and the water outlet 9. However, its length in the axial direction is dimensioned such that the seal 17 arranged towards the water outlet 9 extends into the area of the annular space 16 and thus becomes ineffective when the inner housing 12 in the nozzle body 13 is pulled back in the direction of the water inlet 8. This then opens a bypass channel for the liquid flow outside around the high-pressure nozzle 10, which has a considerably larger flow cross-section than the nozzle channel 11 of the high-pressure nozzle 10. Towards the water outlet 9, behind the high-pressure nozzle 10 on the nozzle body 13, a low-pressure channel 18 is arranged in alignment with the nozzle channel 11. Liquid flowing in the bypass exits from this low-pressure channel 18 at low pressure; in the illustrated, advanced position of the inner housing 12, the bypass is closed, the liquid flow guided through the high-pressure nozzle 10 exits through the low-pressure channel 18 at high pressure and with a small jet diameter.

In the illustrated embodiment of a jet nozzle 2, the low-pressure channel 18 is connected to an approximately T-shaped control carrier 19, via which

Gestnuysen <Ü from pipe

Spring tabs 20 extending axially away from the low-pressure channel 18, which in Fig. 1 shown in side view only as lines, are adjustable in their distance from one another. These spring tabs 20 are used if necessary to shape the jet from a point jet to a flat jet.

The control carrier 19 is adjustable by a control curve 21 on the inside of an outer, plastic adjustment cap 22, whereby the adjustment cap 22 can be rotated about the longitudinal axis of the jet nozzle 2 relative to the nozzle body 13. It is snapped onto the nozzle body 13. Finally, a cap 23, also made of plastic, is screwed onto the nozzle body 13 on the water inlet side. Finally, an integral component of the nozzle body 13 is also an outer metal pressure sleeve 24, which ensures the pressure resistance of the plastic nozzle body 13 in the area of the annular space 16.

The teaching of the invention is that a movable closure element 25 is arranged in the housing 7 in front of the high-pressure nozzle 10, which closes the high-pressure nozzle 10 from the inside as soon as the flow of liquid through the high-pressure nozzle 10 stops or falls below a lower limit. In particular, and as shown here, the closure element 25 closes the high-pressure nozzle 10 as soon as the liquid pressure in front of the high-pressure nozzle 10 falls below a lower limit, and opens again as soon as the liquid pressure in front of the high-pressure nozzle 10 exceeds this or a higher limit. The mode of operation and the result of using such a closure element 25 have been explained in the general part of the description, and reference may be made to this.

The closure element 25 could be displaceable radially relative to the high-pressure nozzle 10, it could be foldable, in the embodiment shown it is movable in the axial direction. For radial displacement, for example, a radially extending recess could be provided in the wall of the housing 7. However, this would possibly be more feasible with a jet nozzle that is not as complicated as the jet nozzle 2 shown.

Gestnuysen &. von Rohr

The closure element 25 could simply be placed in front of the inlet of the nozzle channel 11 of the high-pressure nozzle 10, but the embodiment shown shows a more practical design, for which the closure element 25 enters at least slightly into the nozzle channel 11 of the high-pressure nozzle 10 and partially comes to rest flat against the wall of the nozzle channel 11 of the high-pressure nozzle 10. In the embodiment shown, the nozzle channel 11 of the high-pressure nozzle 10 is conically drawn in from the inside over a short distance and the closure element 25 has a correspondingly conically shaped inlet tip 26. This design naturally corresponds particularly well with the axial displacement of the closure element 25, but this type of design could also be considered if the closure element 25 were to be folded in.

In principle, it would be possible for the inlet tip 26 of the closure element 25 to completely penetrate the nozzle channel 11 of the high-pressure nozzle 10. This could lead to foreign bodies stuck in the nozzle channel 11 being pushed out of the nozzle channel 11 by the inlet tip 26. However, investigations have shown that the effective feed force of the closure element 25 is usually too low to push out a contamination from the nozzle channel 11 that is so firmly seated that it has not already been pushed out by the fluid pressure during operation of the high-pressure cleaning device. Consequently, the embodiment shown shows the preferred embodiment in which the closure element 25 enters the nozzle channel 11 for a small distance at most, and here only into the conically drawn-in part.

The illustrated embodiment shows the preferred embodiment of a jet nozzle 2 with a movable closure element 25 arranged axially in alignment with the high-pressure nozzle. In Fig. 1, the inlet area of the nozzle channel 11 with the inlet tip 26 of the closure element 25 located therein is shown enlarged.

Gestpuysen 6. vcn pipe

Fig. 1 now shows a particularly preferred embodiment of a jet nozzle according to the invention in that a cylinder 27 with a piston 28 that can be moved in a sealed manner is arranged in the housing 7 in front of the high-pressure nozzle 10, that the piston 28 in the cylinder 27 is acted upon on one side - front side - by an opening force resulting from the liquid pressure and on the other side - rear side - by a smaller restoring force acting against the opening force, and that the closure element 25 is moved by the piston 28. This construction makes it particularly easy to control the movement of the closure element 25 automatically solely by the pressure in the liquid column in the flow channel 14 in the housing 7. The cylinder 27 can be arranged on supports that cannot be seen here inside the housing 7, i.e. in the flow channel 14, so that the flow cross-section of the flow channel 14 is impaired as little as possible.

In the embodiment shown, the back of the piston 28 is in a chamber 29. The chamber 29 is ventilated here via a sealed tube 30. The tube 30 leads to the radial outside of the inner housing 12 in the space between the inner housing 12 and the nozzle body 13, which is connected to the outside atmosphere and is therefore pressureless. In principle, it would also be possible not to ventilate the chamber 29 in the cylinder 27, but to fill it with a gas of a certain pressure. Since gas is compressible, unlike a liquid, this would create a gas pressure spring of a certain spring force on the back of the piston 28. In order to open the high-pressure nozzle 10, the liquid pressure in the flow channel 14, which suddenly increases when the valve gun 5 is opened, would have to generate such a force acting in the opening direction via the effective piston surface on the front of the piston 28 that the restoring force of the gas pressure spring is overcome.

The embodiment shown does not have a gas pressure spring, but rather a ventilated chamber 29 and a return spring 31 therein.

Geslhuysen &aacgr; von Rohr

It is possible in various ways to move the closure element 25 under the influence of the piston 28. The embodiment shown shows a structurally particularly simple and practical solution, in which the closure element 25 is designed as a piston rod protruding from the piston 28, at the end of which facing away from the piston 28 the inlet tip 26 is formed. The piston 28 simultaneously forms the longitudinal guide for the closure element 25 in the cylinder 27, whereby the conically drawn-in area of the nozzle channel 11 together with the correspondingly conical inlet tip 26 always compensates for certain inaccuracies.

The embodiment shown shows that the cylinder 27 is permanently installed in the housing 7. Here, the return spring 31 and the piston 28 with the closure element 25 attached to it as a piston rod are inserted into the flow channel 14 and into the cylinder 27 from the then open side with the high-pressure nozzle 10 unscrewed. Alternatively, the closure element 25 could also be inserted into the housing as a unit together with the piston 28 and the cylinder 27 and, if necessary, the return spring 31 etc.

It has already been explained above that a closure element 25 would also be useful for existing, commercially available jet nozzles 2. The additional unit 32 shown in an example in Fig. 3 is used for this purpose. In the embodiment shown, this additional unit 32 can itself be screwed into the housing 7 of a jet nozzle 2 at the water inlet 8, the far-protruding closure element 25 then touches with its inlet tip 26 just the beginning of the nozzle channel 11 of the high-pressure nozzle 10. In the embodiment shown here, the additional unit itself has a body 33 with flow channels 34 and is itself provided with a water inlet 35 with an internal thread (or external thread).

Otherwise, the same statements apply to the equipment of the additional unit 32 as previously made in connection with a jet nozzle 2 as a whole. In particular, one can see here the cylinder 27 formed in the body 33 with

Gssthuysen &Aacgr;. from Rohr

the piston 28 running in it and the ventilation tube 30, which is realized as a hole in the body 33 and which of course connects to the ambient atmosphere without any problem.

A simple design for the closure element could also be implemented alternatively by leading the closure element out of the space in the housing exposed to the fluid pressure, in particular out of the housing as a whole and subjecting it to a restoring force on the outside. This would be particularly useful if the closure element is moved radially, then the required pressure difference for the control movement of the closure element could be achieved without major problems and special design measures, just with an appropriate seal.

Claims (24)

Gesthuysen &aacgr; von Rohr Protection claims: 1. Jet nozzle for high-pressure cleaning devices or other devices with a liquid jet emerging under high pressure, with a pressure-resistant housing (7), with a water inlet (8) and a water outlet (9) and a high-pressure nozzle (10) associated with the water outlet (9) with a nozzle channel (11) with a preferably circular cross-section, characterized in that a movable closure element (25) is arranged in the housing (7) in front of the high-pressure nozzle (10), which closes the high-pressure nozzle (10) from the inside as soon as the liquid flow through the high-pressure nozzle (10) stops or falls below a lower limit. 2. Jet nozzle according to claim 1, characterized in that the closure element (25) closes the high-pressure nozzle (10) as soon as the liquid pressure in front of the high-pressure nozzle (10) falls below a lower limit, and opens again as soon as the liquid pressure in front of the high-pressure nozzle (10) exceeds this or a higher limit. 3. Jet nozzle according to claim 1 or 2, characterized in that the closure element (25) enters at least slightly into the nozzle channel (11) of the high-pressure nozzle (10) and partially comes to rest flatly on the wall of the nozzle channel (11) of the high-pressure nozzle (10). 4. Jet nozzle according to claim 3, characterized in that the nozzle channel (11) of the high-pressure nozzle (10) is conically drawn in over a certain distance starting from the inside and the closure element (25) has a correspondingly conically shaped inlet tip (26). 5. Jet nozzle according to claim 3 or 4, characterized in that the closure element completely penetrates the nozzle channel of the high-pressure nozzle in the closed state. Gesthuysen &aacgr; by Rolir 6. Jet nozzle according to one of claims 1 to 5, characterized in that the closure element (25) is arranged axially aligned with the high-pressure nozzle (10). 7. Jet nozzle according to one of claims 1 to 6, characterized in that in the housing (7) in front of the high-pressure nozzle (10) there is arranged a cylinder (27) with a piston (28) which can be moved in a sealed manner in it, that the piston (28) in the cylinder (27) is acted upon on one side - front side - by an opening force resulting from the liquid pressure and on the other side - rear side - by a smaller restoring force acting against the opening force, and that the closure element (25) is moved by the piston (28). 8. Jet nozzle according to claim 7, characterized in that the rear side of the piston (28) is arranged in a chamber (29). 9. Jet nozzle according to claim 8, characterized in that the chamber (29) is preferably ventilated via a sealed tube (30). 10. Jet nozzle according to one of claims 7 to 9, characterized in that a return spring (31), preferably arranged in the chamber (29), engages the rear side of the piston (28). 11. Jet nozzle according to one of claims 7 to 10, characterized in that the closure element (25) is designed as a piston rod protruding from the piston (28). 12. Jet nozzle according to one of claims 1 to 11, characterized in that the closure element (25), optionally together with the piston (28) and the cylinder (27) and optionally the return spring (31) as a unit, can be inserted into the housing (7). Gesthuysen &. von Rohr 13. Jet nozzle according to one of claims 1 to 6, characterized in that the closure element is led out of the space in the housing exposed to the liquid pressure, in particular out of the housing as a whole, and is subjected to a restoring force outside. 14. Additional unit for a jet nozzle for high-pressure cleaning devices or other devices with a liquid jet emerging under high pressure, such a jet nozzle being provided with a pressure-resistant housing with a water inlet and a water outlet and a high-pressure nozzle associated with the water outlet with a nozzle channel with a preferably circular cross-section, characterized in that the additional unit (32) can be fastened to the water inlet of the housing of the jet nozzle and has a closure element (25) which, when the additional unit (32) is attached, extends in the housing to the high-pressure nozzle and closes the high-pressure nozzle from the inside as soon as the liquid flow through the high-pressure nozzle stops or falls below a lower limit, in particular closes as soon as the liquid pressure in front of the high-pressure nozzle falls below a lower limit, and opens again as soon as the liquid pressure in front of the high-pressure nozzle exceeds this or a higher limit. 15. Additional unit according to claim 14, characterized in that the additional unit (32) can be screwed into the water inlet of the jet nozzle and itself has a threaded water inlet (35). 16. Additional unit according to claim 14 or 15, characterized in that the closure element (25) enters slightly into the nozzle channel of the high-pressure nozzle when the additional unit (32) is attached to the water inlet of the housing of the jet nozzle and partially comes to rest flatly on the wall of the nozzle channel of the high-pressure nozzle. Gssthuysen -&. from Rohr 17. Additional unit according to claim 16, characterized in that the nozzle channel of the high-pressure nozzle is conically drawn in over a certain distance starting from the inside and the closure element (25) has a correspondingly conically shaped inlet tip (26). 18. Additional unit according to claim 16 or 17, characterized in that the closure element completely penetrates the nozzle channel of the high-pressure nozzle in the closed state. 19. Additional unit according to one of claims 14 to 18, characterized in that the closure element (25) is arranged axially aligned with the high-pressure nozzle. 20. Additional unit according to one of claims 14 to 19, characterized in that a cylinder (27) with a piston (28) which can be moved in a sealed manner is arranged in the housing in front of the high-pressure nozzle, that the piston (28) in the cylinder (27) is acted upon on one side - front side - by an opening force resulting from the liquid pressure and on the other side - rear side - by a smaller restoring force acting against the opening force, and that the closure element (25) is movable by the piston (28). 21. Additional unit according to claim 20, characterized in that the rear side of the piston (28) is arranged in a chamber (29). 22. Additional unit according to claim 21, characterized in that the chamber (29) is ventilated, preferably via a sealed tube (30). 23. Additional unit according to one of claims 20 to 22, characterized in that a return spring (31) preferably arranged in the chamber (29) acts on the rear side of the piston (28). GoSthuyssn & von Rohr 24. Additional unit according to one of claims 20 to 23, characterized in that the closure element (25) is designed as a piston rod protruding from the piston (28).