DE10248336A1 - Spray can, to deliver a liquid jet spray as a mouth wash and clean the teeth, has an eddy chamber at the jet body to develop a cone spray of micro droplets to rinse the mouth and remove plaque - Google Patents

Abstract

The spray can (1), to generate a stream of liquid for a mouth wash, has a jet body (2) with a chamber (6) with a fluid channel (5) to carry the liquid under pressure. The chamber has an outlet for the jet stream. The chamber is linked to an eddy chamber (15) with a round cross section, to give a rotating liquid jet stream from the center jet outlet, which starts with a narrow cylindrical stream and which expands into a cone spray. The liquid is held in the can under pressure, so that it is formed into micro droplets in the jet stream.

Description

The invention relates to a Process and spray nozzle for production a jet of liquid for one Oral irrigator with a nozzle body, one liquid channel arranged therein, the opens into an outlet for the cleaning liquid, and a device for the spray nozzle with a Pump, a liquid container and a handpiece.

It is known to improve the cleaning effect of oral irrigators by using special spray nozzles to generate certain types of liquid jets. Spray nozzle in the context of this application can also be understood to mean a nozzle for dispensing a water jet which does not consist of individual drops. From the EP 0 841 038 A1 It is known to arrange a paddle wheel rotating about its axis of rotation in the spray nozzle, which is set in rotation by the cleaning liquid supplied to the paddle wheel. The cleaning liquid reaches the outlet via a channel in the paddle wheel arranged at an angle to the axis of rotation. As a result of the rotation of the paddle wheel, the cleaning liquid leaves the outlet of the spray nozzle in the form of a rotating liquid jet. In this way, a single jet is generated, which is evenly distributed on an expanding cone. Despite the increased effective area, the cleaning effect of a liquid jet generated with such a spray nozzle is not yet optimal. Marginal plaque removal, in particular, is only insufficiently possible with such a spray nozzle. Only non-adherent plaque can be removed with the liquid jet from an oral irrigator. The removal of plaque in the proximal area and in the gum line is only possible with manual toothbrushes, dental floss or electric toothbrushes, although not satisfactorily. Another disadvantage of the spray nozzle is the rotating paddle wheel, since moving components are subject to greater wear. The increased wear and tear with increasing service life leads to an increase in the bearing, which in turn can result in a reduction in speed up to the standstill of the paddle wheel.

The present invention lies therefore the task of a method and a spray nozzle for performing the Method for generating a jet of liquid for an oral irrigator to create with improved cleaning effect. The liquid jet should be able to hold firmly adherent plaque in the proximal area as well as on the gum line. The spray nozzle for producing such liquid jet should if possible wear worked and be simply constructed. In addition, a device for the Spray nozzle created that allows a comprehensive cleaning of the teeth and gums.

The task is regarding the Method according to the invention solved, that the cleaning fluid a spray nozzle with high Pressure supplied and that of a jet of liquid at the nozzle outlet high speed of the emerging cleaning liquid is generated from microfine drops. In particular, from that Nozzle outlet a thin, yourself fast moving liquid film formed, which then changes into microfine drops at high speed.

As a result of the high impact energy the drop on the plaque layer becomes the cleaning liquid pushed sideways. The shear forces generated tear the plaque surface under formation of pits and craters. Because the liquid jet from a variety of drops, this process repeats itself more quickly Episode. In this way, the plaque layer is removed in layers. The advantage of a liquid jet generated in this way and consisting of drops is that now also Removed plaque from the proximal area and the gum line can be. Furthermore, due to the mechanical removal of the Plaque layer no addition for the cleaning liquid necessary so that water for plaque removal as a cleaning liquid can be used.

To generate the drops with high The cleaning liquid of the spray nozzle becomes high at high speed Pressure supplied. Dependent on the special design, the pressure is between about 25 bar and 55 bar, with a pressure range of 35 bar to 45 bar get the best cleaning results.

The cleaning liquid must be used to generate the drops atomized or sprayed become. Particularly small drops can be made with the same nozzle diameters and press generate when the liquid jet is formed as a divergent hollow cone beam. The divergent Hollow cone jet also has the advantage that the spray surface with increasing distance is enlarged from the nozzle outlet, which enables faster cleaning. Next to the hollow cone beam however, the generation of a full cone or flat jet is also conceivable.

In addition to the beam shape is education of the ray determining for the formation of microfine drops. This can be done generate that cleaning fluid in the nozzle outlet as a thin film is formed, which is evenly on the Inner wall of the nozzle outlet is distributed. When leaving the nozzle outlet, it tears evenly distributed Film just behind the nozzle outlet in the microfine drops.

Adhesive plaque layers can be particularly well with a liquid jet consisting of drops ablate, the drops of which are about 5 µm to 10 µm and a speed of about 45 m / s to 55 m / s have.

The task is regarding a Spray nozzle for generation a jet of liquid for an oral irrigator, with a nozzle body that has a chamber into which a liquid channel for the supply of pressurized cleaning fluid opens and from which a nozzle outlet for the discharge of a Cleaning liquid jet proceeds, according to the invention solved, that the Chamber with a vortex chamber of approximately round cross-section for production a circulating flow of the cleaning liquid is connected from the center of the nozzle outlet goes out, that of a preferably approximately cylindrical constriction and one optional following it there is in particular about a conical extension. Possibly the extension can also be omitted or not conical his.

This design enables a jet of liquid, consisting of microfine drops of high speed, which is able to plaque due to the drop speed remove. A cleaning performed with the spray nozzle designed as a hollow cone nozzle allows with the same service life due to significantly less abrasion the epithelial cell layer a gentler cleaning than with a electric toothbrush. Furthermore enables the spray nozzle the use of an electric toothbrush, especially in the approximal Area an additional Reduction of approximately 60% plaque. The spray nozzle comes without moving Components that are reinforced Subject to wear would.

For the generation of the microfine drops at high speed has a constriction in the form of a hole with a diameter from about 0.1 mm to 0.2 mm and a depth of about 0.05 mm to 0.2 mm was found to be advantageous. One trained in this way Bottleneck ensures that the out cleaning fluid emerging from the swirl chamber at a high pressure and high speed in the optional subsequent expansion entry.

Finally, from the many drops existing liquid jet to form has an expansion, especially in the form of a Cone or hollow cone as cheap proven, the expansion follows the bottleneck. With this atomization principle particularly fine drops can be produced. After passing the bottleneck places cleaning liquid on the wall of the Hollow cone as evenly distributed thinner Film on, this film due to the vortex chamber around the axis of symmetry the extension rotates. Because of the high tangential speed tears the film into the microfine drops as soon as it leaves the hollow cone, especially just behind the nozzle outlet. For one A cone or hollow cone has optimal formation of the drops with a length from about 0.2 mm to 0.5 mm and an opening angle of about 20 ° to 70 °. This nozzle geometry also stands out in that also at high drop speeds, small volume flows, e.g. of less than 80 ml / min possible are without the nozzle geometry is so small that the cost for the Manufacturing go up. In this way, extremely small nozzle geometries, which is also a shorter one Have a lifetime, avoided. The one designed as a hollow cone Nozzle also the advantage that they even with manufacturing inaccuracies or contamination has a stable spray pattern.

But it is also conceivable instead the hollow cone nozzle a flat fan nozzle or full cone nozzle use.

The outlet can be compact and thus saves space build up if it is in a nozzle attachment arranged on the nozzle body is trained.

For further simplification in the manufacture of the nozzle attachment wear it if the constriction and the expansion in a separate component, e.g. a nozzle plate, are arranged. The assembly of the nozzle plate in the nozzle attachment is only associated with a small additional effort, while the Manufacturing in terms of accuracy, dimensional accuracy and cost with a nozzle plate better is. In addition, the nozzle plate from another, more wear-resistant Material.

The nozzle attachment ensures an interchangeability when connected to the nozzle body by means of a detachable connection is. The detachable Connection can either be a screw connection or as a snap and Plug connection to be formed. This allows the nozzle attachment for example in the event of damage Replace. Allows at the same time a nozzle body designed in this way Conventional recording Nozzle attachments that with a much larger volume flow operate at significantly lower pressure.

The arrangement of a pressure piece in the spray nozzle has proven to be advantageous for the design of the swirl chamber. The pressure piece is arranged in a chamber which is formed between the nozzle attachment and the nozzle body. To fix the pressure piece in the chamber, the part of the pressure piece located in the nozzle body or nozzle attachment is inserted with a press fit or fixed by means of locking elements arranged on the nozzle attachment or nozzle body. This fixation facilitates the assembly on the one hand and on the other hand the pressure piece is captively connected to one of the two parts when the nozzle attachment is changed. But it is also conceivable to interpose the pressure piece due to an excess or by means of a spring Clamp the nozzle body and nozzle attachment.

The pressure piece can at both ends each a pot-shaped Have part. The first pot-shaped Part is the constriction in the nozzle attachment facing and forms the vortex chamber with its interior. The second pot-shaped Part is to the liquid channel in the nozzle body aligned.

In the first pot-shaped part is at least one opening arranged through which the cleaning liquid from the interior the first pot-shaped Part can get into the chamber. A free drainage of the cleaning fluid is guaranteed if the interior of the pot-shaped Partly about at least one opening, but preferably three to four openings communicates with the chamber.

Are the openings as axial slots through the pot-shaped Part designed, so form the areas between the slots of the cup-shaped part Spring arms that support the fixation of the pressure piece.

The function of the spring arms is supported if the pressure piece made of an elastic material, e.g. a plastic.

The arrangement of the vortex chamber in the pressure piece guaranteed as a separate component a particularly simple manufacture. The vortex chamber is formed from the interior in the first cup-shaped part that faces the area is placed around the constriction, the constriction of the outlet from the Whirl chamber is. The pot-shaped part lies to seal the vortex chamber around the bottleneck. A particularly good sealing effect is achieved if the pot-shaped Part flat rests. This type of sealing prevents deformation in the pressure piece. such Deformations with a linear Sealing occurs when the pot-shaped part has an edge seals.

Beyond that too a formation of the sealing surfaces conceivable as a cone. Here the cone angle from nozzle plate and pressure piece exactly match. Opposite are two flat surfaces cost-effective in production.

To secure the seal can also in Area around the constriction locking hooks are provided, which have locking points on the outer circumference of the pressure piece interact. This fixation has the additional advantage that in one Changing the spray nozzle captive the pressure piece in the nozzle attachment is held.

Access to the swirl chamber will be of at least one perpendicular or at an angle of less than 90 ° to the axis of symmetry of the pressure piece lying opening in the first cup-shaped Part formed. It has been shown that the beam formation through the number, the cross section and the position of the openings is influenced. Good results were achieved with two opposite slots trained openings reached.

For the formation of a sufficient vortex in the vortex chamber opens approximately the openings transversely and with a center offset to the longitudinal axis of the swirl chamber in the vortex chamber. The size of the center offset and the angle at which the openings open into the vortex chamber also crucial for the formation of the beam. So a center offset has turned out to be cheap, who is so big that the out of the openings escaping liquid jet to the opposite Wall of the swirl chamber hits at an angle less than 45 °. It is in this angular range that the beam can most effectively apply its energy transfer the developing vortex.

The supply of the cleaning liquid to the openings takes place via Grooves running parallel to the axis of symmetry of the pressure piece in the first cup-shaped Part. This type of feeding avoids radial feeding, which in turn is a big one Would take up space. The spray nozzle can thus be formed with a small diameter.

A pressure piece with two cup-shaped parts is advantageous if the liquid channel lies on one axis with the constriction. A spray nozzle with less axial extension can be achieve when the fluid channel is aligned approximately radially to the constriction. With this configuration can the liquid channel facing area is eliminated, which causes the pressure piece in the structure simplified.

In a device with an electric motor drivable pump and a liquid container, at which the pump over a hose and a handpiece connected to a spray nozzle is, a spray nozzle according to one of the device claims is preferably arranged on the handpiece.

Is the spray nozzle interchangeable with another nozzle? on the handpiece arranged of the device, the device can be in different operating modes operate. In addition to the high-pressure spray nozzle according to the invention for removing plaque allows interchangeability e.g. the use of a conventional Jet and / or spray nozzle. The spray nozzle according to the invention with a high pressure at a small volume flow and a normal one Mundduschendüse with a great Volume flow operated at low pressure. If both nozzles with approximately the pump can be operated with the same hydraulic power be driven by an electric motor, the pump being switchable, e.g. is formed by a switchable transmission.

Switching between the operating modes can take place without additional effort or devices in the handpiece if the nozzle attachment is used for the detection of the operating mode to be set. Depending on the nozzle attachment used, a certain pressure builds up in the device. A pressure sensor can be located between the pump and the spray nozzle to detect the pressure of the cleaning conveyed to the spray nozzle be arranged liquid, wherein a signal corresponding to the detected pressure of a control unit can be fed from the pressure sensor and can be controlled by the control unit of the electric motor with the operating mode assigned to the detected pressure.

In another embodiment exploited the fact that in Contrary to a conventional jet spray operated in the oral irrigator mode and / or spray nozzle with the high pressure mode the spray nozzle according to the invention a large torque and causes a low speed. A speed or Torque sensor on the pump or on the electric motor for detection the speed or torque of a rotor of the pump or Electric motor may be arranged, with the speed or torque sensor one of the captured Speed or the detected torque Corresponding signal can be fed to a control unit and from the Control unit of the electric motor and / or the pump and / or the transmission with that of the captured Speed or the detected torque assigned operating mode can be controlled. It is understood that the torque and / or the speed also over measure the current drawn by the motor can. In summary, it should be noted that switching between the Operating modes can be carried out by a pressure or current detection.

The invention is based on two exemplary embodiments explained in more detail. there demonstrate

1 : a section through a first embodiment of a spray nozzle,

2 : an enlarged view of the nozzle plate after 1 .

3 : a perspective view of the pressure piece after 1 .

4 : a top view of the swirl chamber according to 1 .

5 : a section through a second embodiment of a spray nozzle,

6 : a section through a third embodiment of a spray nozzle,

7 : a device with a spray nozzle.

In the 1 shown spray nozzle 1 consists of a nozzle body 2 with a nozzle attachment 3 by means of a screw connection 4 connected is. In the nozzle body 2 is a fluid channels 5 arranged for the cleaning liquid.

The nozzle body 2 forms together with the nozzle attachment 3 a chamber 6 into which the liquid channel 5 empties. In this chamber 6 is a pressure piece 7 used.

The pressure piece 7 is radially expanded pot-shaped at both ends. With the first pot-shaped part 8th the pressure piece sits 7 on a nozzle plate 9 on. The second cup-shaped part 10 surrounds the area where the fluid channel 5 into the chamber 6 opens.

The second cup-shaped part 10 has four evenly spaced axial slots 11 , through the in the fluid channel 5 supplied cleaning liquid into the chamber 6 can flow.

The first pot-shaped part 8th has two axially on the circumference of the pressure piece 7 trained grooves 12 , In the area of the grooves 12 is the pot-shaped part 8th from a ring 13 surround. This ring made of polyamide 13 seals the circumference of the pot-shaped part 8th off so that the grooves 12 act as channels. At the bottom of the grooves 12 close to it radially extending channels formed as slots 14 which is almost tangential into a swirl chamber 15 extend.

The vortex chamber 15 is through the interior of the first cup-shaped part 8th and the nozzle plate 9 educated. At the same time, the nozzle plate closes 9 an opening 16 in the nozzle attachment 3 ,

The nozzle plate 9 in turn has a passage 17 , through which the cleaning fluid from the swirl chamber 15 exit.

In 2 is the passage 17 the nozzle plate 9 shown enlarged. The passage consists of a hole 18 which is the outlet from the swirl chamber 15 forms. The hole 18 has a diameter of 0.15 mm and a length of 0.11 mm, for example.

To the hole 18 a diverging hollow cone closes 19 on. The hollow cone 19 has an opening angle of, for example, 30 ° and a length of, for example, 0.35 mm.

The one in the vortex chamber 15 through the almost tangential channels 14 Rotating cleaning fluid is due to the small diameter of the bore 18 in this swirling accelerated strongly. The cleaning liquid then enters the hollow cone 19 on. In the hollow cone 19 due to the vortex movement and decompression, the cleaning liquid forms as a uniformly distributed thin film on the wall of the hollow cone 19 out. At the same time, the film rotates around axis A at high speed. If the cleaning liquid moves in this way, it will reach the edge 20 , the film tears into a multitude of drops with an average size of about 10 μm, which move at a speed of about 50 m / s. The drops in their entirety form a hollow cone.

The pressure piece 7 in 3 shows the two pot-shaped parts 8th . 10 , The second cup-shaped part 10 is due to four slots evenly distributed around the circumference 11 divided into four areas. Due to their shape, these areas act as spring arms 21 , The spring arms 21 lean against the nozzle body 2 off, so that the first cup-shaped part 8th with the area 22 against the nozzle plate 9 is pressed.

On the circumference of the first cup-shaped part 8th are the two grooves 12 arranged. On the grooves 12 one channel closes 14 on, almost tangential which directly into the vortex chamber 15 lead. About the grooves 12 and the channels 14 the cleaning liquid flows from the chamber 6 to the swirl chamber 15 ,

The location of the channels 14 to the swirl chamber 15 is the 4 removable. The canals 14 lead from the grooves 12 not radially to the center, but run in opposite directions parallel to each other and enter the vortex chamber with a center offset X. 15 on. The center offset is chosen so that an undisturbed in the swirl chamber 15 incoming beam hits the wall of the vortex chamber at an angle of less than 45 ° and is diverted into a circulating flow on the wall.

The 5 and 6 show a second embodiment of the spray nozzle 1 , The nozzle body 2 is in relation to the axis of symmetry of the nozzle attachment 3 not radial but preferably approximately tangential to the nozzle attachment 3 arranged. As a result, the liquid channel opens 5 also into the side of the chamber 6 , The chamber 6 is with a lid 23 locked

The pressure piece 7 is simplified in that no second cup-shaped part is necessary. The vortex chamber 15 is again in the first pot-shaped part 8th arranged. In 5 the pressure piece is supported 7 on the lid 23 off so that the area 22 sealing on the nozzle attachment 3 rests. In 6 becomes the sealing effect of the surface 22 by a spring 24 that supports the pressure piece 7 against the nozzle attachment 3 presses.

About grooves 12 and slots 14 that are similar to those in the 1 to 4 are arranged, the cleaning liquid in turn gets into the swirl chamber 15 , In contrast to 1 have the spray nozzles 1 in 5 and 6 no nozzle plate. The hole 18 and the hollow cone 19 are in the nozzle attachment 3 arranged. On the nozzle attachment 3 are several projections around the emerging jet 25 available. The formations 25 have an axial extension of about 3 mm. The formations 25 are used to set an optimal working distance by the spray nozzle 1 with the formations 25 is placed on the areas to be cleaned.

The device 26 in 7 includes a liquid container 27 which can be filled with cleaning fluid by the user. For this liquid container 27 the cleaning liquid is pumped 28 by an electric motor 29 is driven via a hose 30 to a handpiece 31 promoted. On the handpiece 31 is the spray nozzle 1 arranged interchangeably. On the electric motor 29 is a sensor 32 arranged, that of the electric motor 29 generated torque measures and then a signal to the pump 28 delivers so that it can be operated in the operating mode which corresponds to the spray nozzle used.

Will the spray nozzle according to the invention 1 used, the pump 28 generates a volume flow of 50 ml / min at approximately 40 bar in the high pressure mode. This corresponds approximately to a mechanical or hydraulic output of approx. 2000 ml / min bar or approx. 3.3 W. Is a conventional spray nozzle on the handpiece 31 arranged, the sensor recognizes 32 compared to the spray nozzle according to the invention 1 changed torque and the pump 28 is operated in the irrigator mode. The pump delivers 28 a volume flow of approximately 300 ml / min with a pressure of 6 bar. This results in a mechanical or hydraulic output of approximately 1800 ml / min bar or 3.0 W. The device is due to the approximately identical mechanical output in both operating modes 26 with a pump 28 and an electric motor 29 operated.

1

spray nozzle

2

nozzle body

3

nozzle attachment

4

screw

5

liquid channel

6

chamber

7

Pressure piece

8th

first cup-shaped part

9

nozzle plate

10

second cup-shaped part

11

slots

12

groove

13

ring

14

channels

15

swirl chamber

16

opening

17

passage

18

drilling

19

Hollow cone, conical surface

20

edge

21

spring arms

22

area

23

cover

24

feather

25

projections

26

contraption

27

liquid container

28

pump

29

electric motor

30

tube

31

handpiece

32

sensor

Claims (29)

Method for producing a liquid jet for an oral irrigator, in which a cleaning liquid is supplied to a spray nozzle and conveyed to and exits from a nozzle outlet, characterized in that the cleaning liquid is supplied to the spray nozzle at high pressure and in that a liquid jet of high velocity emerges from the nozzle outlet Cleaning liquid is generated from microfine drops. A method according to claim 1, characterized in that the liquid jet is formed as a divergent hollow cone beam. A method according to claim 1 and 2, characterized in that the cleaning fluid the spray nozzle with high Pressure, preferably at about 25 bar to 55 bar, in particular 35 fed up to 45 bar becomes. Method according to one of the preceding claims, characterized characterized in that the liquid jet in the nozzle outlet as a thin film is formed when or after leaving the nozzle outlet turns into microfine drops. Method according to one of the preceding claims, characterized characterized that the Drops with a diameter of about 5-10 μm and a speed from about 40 m / sec to 55 m / sec. Spray nozzle for generating a liquid jet for an oral irrigator, with a nozzle body which has a chamber into which a liquid channel for the supply of pressurized cleaning liquid opens and from which a nozzle outlet for exiting a cleaning liquid jet emerges, characterized in that the chamber ( 6 ) with a swirl chamber ( 15 ) is of approximately round cross-section for generating a circulating flow of the cleaning liquid, from which the nozzle outlet is centered ( 18 . 19 ), which consists of a preferably approximately cylindrical constriction and, if appropriate, preferably an adjoining, in particular approximately conical, extension. Spray nozzle according to claim 6, characterized in that the constriction has a bore ( 18 ) with a diameter of about 0.1 mm to 0.2 mm, preferably of 0.15 mm and a depth of about 0.05 mm to 0.2 mm, preferably of 0.11 mm. Spray nozzle according to one of claims 6 and 7, characterized in that the extension is a hollow cone or a conical surface ( 19 ) is. Spray nozzle according to claim 8, characterized in that the hollow cone or the conical surface ( 19 ) has an opening angle of approximately 20 ° to 70 °, preferably of 30 °, and a length of approximately 0.2 mm to 0.5 mm, preferably of 0.35 mm. Spray nozzle according to one of claims 6 to 9, characterized in that the nozzle outlet ( 18 . 19 ) in one on the nozzle body ( 2 ) arranged nozzle attachment ( 3 ) is trained. Spray nozzle according to one of claims 6 to 10, characterized in that the constriction and the expansion in a nozzle plate ( 9 ) of the nozzle attachment ( 3 ) are arranged. Spray nozzle according to one of claims 10 and 11, characterized in that the nozzle attachment ( 3 ) preferably releasably with the nozzle body by a screw or a snap-in and plug-in connection ( 2 ) connected is. Spray nozzle according to one of claims 10 to 12, characterized in that the chamber ( 6 ) between the nozzle body ( 2 ) and the nozzle attachment ( 3 ) is formed. Spray nozzle according to claim 13, characterized in that in the chamber ( 6 ) a pressure piece ( 7 ) is arranged, which has a first cup-shaped part at one end ( 8th ), the interior of which is the swirl chamber ( 15 ) forms. Spray nozzle according to claim 14, characterized in that in the first cup-shaped part ( 8th ) at least one, preferably 2 to 3 openings ( 14 ) to connect the chamber ( 6 ) with the interior of the first cup-shaped part ( 8th ) are arranged. Spray nozzle according to one of claims 6 to 15, characterized in that the openings ( 14 ) approximately across and with a center offset (x) to the longitudinal axis of the swirl chamber ( 15 ) in the vortex chamber ( 15 ) open out, with the opening ( 14 ) emerging liquid jet onto the opposite wall of the swirl chamber ( 15 ) hits at an angle of at most 45 °. Spray nozzle according to one of claims 14 to 16, characterized in that on the cylindrical outside of the first cup-shaped part ( 8th ) axially extending grooves ( 12 ) from the chamber ( 6 ) to the openings ( 14 ) to lead. Spray nozzle according to one of claims 14 to 17, characterized in that the pressure piece ( 7 ) at its other end a second pot-shaped part ( 10 ), whose interior with the liquid channel ( 5 ) and with the chamber ( 6 ) is connected. Spray nozzle according to claim 18, characterized in that the interior of the second cup-shaped part ( 10 ) via at least one opening, preferably 3 to 4 openings, with the chamber ( 6 ) is connected. Spray nozzle according to claim 19, characterized ge indicates that the openings as axial slots ( 11 ) are trained. Spray nozzle according to one of claims 14 to 20, characterized in that the pressure piece ( 7 ) with its lower end sealing around the area of the mouth of the liquid channel ( 5 ) and around the area of the nozzle outlet. Spray nozzle according to claim 21, characterized in that the pressure piece ( 7 ) in the chamber ( 6 ) is clamped axially resiliently. Spray nozzle according to claim 22, characterized in that the pressure piece ( 7 ) consists of an elastic material. Spray nozzle according to claim 23, characterized in that the through the slots ( 11 ) formed areas of the second cup-shaped part ( 10 ) Spring arms ( 21 ) form. Device with an electric motor-driven pump and a liquid container, the pump being connected via a hose to a handpiece and a spray nozzle, characterized in that on the handpiece ( 31 ) a spray nozzle ( 1 ) is arranged according to one of claims 6 to 24. Device according to claim 25, characterized in that the spray nozzle ( 1 ) on the handpiece ( 31 ) can be exchanged for another spray and / or jet nozzle. Device according to one of claims 25 and 26, characterized in that the pump ( 28 ) depending on the on the handpiece ( 31 ) arranged spray and / or jet nozzle ( 1 ) can be switched between several, in particular between two, operating modes. Apparatus according to claim 27, characterized in that a speed or torque sensor ( 32 ) on the pump ( 28 ) or on the electric motor ( 29 ) for detecting the speed or the torque of a rotor of the pump ( 28 ) or the electric motor ( 29 ) is arranged that the speed or torque sensor ( 32 ) a signal corresponding to the detected speed or torque can be fed to a control unit and from the control unit the electric motor ( 29 ) can be controlled with the operating mode assigned to the detected speed or torque. Apparatus according to claim 27, characterized in that a pressure sensor ( 32 ) between pump ( 28 ) and spray nozzle ( 1 ) to measure the pressure of the spray nozzle ( 1 ) conveyed cleaning liquid is arranged that the pressure sensor ( 32 ) a signal corresponding to the detected pressure can be fed to a control unit and from the control unit the electric motor ( 29 ) can be controlled with the operating mode assigned to the detected pressure.