DE10008389A1 - Influencing drop spectrum of suspensions comprises adjusting splitting ratio of partial streams divided by nozzles, and adjusting average diameter of drops using valve or pump - Google Patents

Abstract

Influencing the drop spectrum of suspensions comprises adjusting the splitting ratio of partial streams (T3, T4) divided by nozzles (6a, 6b) which change the drop size using a valve (5, 8) or pump connected to one of the partial streams; adjusting the average diameter of the drops using the valve or pump; and changing the width of the spectrum by adjusting different admission pressures for several nozzles connected in the system. An independent claim is also included for a feeding system for carrying out the process. Preferred Features: Further parallel nozzles (21, 22) are operated with feed lines (23, 24) in the conveying direction after the pump (2) connected in the total fluid stream or in one of the total fluid streams.

Description

The invention relates to a method and an associated line system for Influencing the drop spectrum of fluid substances during their atomization by means of single-substance pressure nozzles, in particular by spray drying or prilling melts.

When spray drying suspensions or prilling melts is often a special spectrum of the powder to be produced is desired. Under the term Spectrum are primarily to be understood the granulometric properties, which, for. B. through the characteristic values of average drop diameter and the width of the drops distribution are characterized. It is known in practice when using Single-substance pressure nozzles a selection of certain nozzles of different geometries to be determined. However, the spectrum of the atomized fluids can no longer be influenced arbitrarily. It is different with Two-component nozzles, where by changing the ratio of gas flow to Liquid throughput during operation, the spectrum of the atomizing fluid can be adjusted.

WO 99/47270 describes a method for changing the swirl movement of a Fluids in the swirl chamber of a nozzle are known, in which the division of the swirl chamber reaching tangential partial flows to realize different Control options during operation independent of throughput is made. The total fluid flow is outside the single-substance pressure nozzle divided into at least two partial flows, one in one of the partial flows Control valve is integrated. With this method it is e.g. B. possible during the running operation the average diameter of the droplets of an atomizer Influencing fluids by changing the form and by the change the flow rate is kept constant by means of the valve. The disadvantage is that this procedure has no influence on the width of the Spectrum of the fluid to be atomized can be taken.

The invention has for its object a method for influencing the Drop spectrum of fluid substances during their atomization using single-substance pressure nozzles  to create, with which the width of the Spectrum and the mean diameter of the drops can be changed without Replacement of individual nozzles. Furthermore, one should carry out the method suitable pipe system can be created.

According to the invention the object is achieved by the features specified in claim 1 solved. Suitable design variants are in claims 2 to 11 specified. A line system suitable for carrying out the method is The subject matter of claim 12. Suitable design variants for this are described in claims 13 to 18.

To implement the proposed procedure, it is necessary to at least to use a nozzle with which the drop size is independent of the throughput can be adjusted. Such nozzles are e.g. B. from the publications EP 0794 383 A2 and WO 99/472 70 are known. In addition, within a plant, e.g. B. a spray tower, also other parallel nozzles or nozzles groups are used in which the drop size depends on the throughput can be changed. To implement the method according to the invention Total throughput to be conveyed through one nozzle to at least two Partial streams divided, which are fed to the feed channels within the nozzle become. The ratio of the two partial flows is then as desired set. In comparison to the known prior art, the use of several nozzles within a spray tower, not all nozzles at the same time can be controlled. The total throughput that is to be atomized in the tower is first divided into the individual nozzles. It is possible that several nozzles to be grouped together, controlled jointly or separately can be. According to the proposed procedure, everyone can do either suitable nozzles or only certain nozzles or groups of nozzles are controlled separately become. This is achieved by means of control elements that are operated independently of the throughput Partial flow ratio regulated for each nozzle or nozzle group. If a defined drop in front of a nozzle or group of nozzles to be influenced. With the ratio of the partial flows that each nozzle or nozzles group, the total throughput for each nozzle or nozzle group fixed. If you set the same pre-pressure and the same throughput for all nozzles the drop spectrum that can be achieved is the smallest. For example, if you want increase the proportion of fine drops, so you set for a nozzle or nozzle group a higher admission pressure and changes the ratio of the partial flows that this Nozzle or group of nozzles are fed so that this nozzle or group of nozzles a greater throughput is run in relation to the other nozzles. Analogous  one can proceed with an increase in the proportion of large drops. The middle one Drop diameter can be selected by choosing a suitable form for the Overall system to be adjusted. This way both are the middle drop diameter and the width of the spectrum independently of each other running operation adjustable.

With the procedure according to the invention, these parameters can differ be managed. For this purpose, such parameters are suitable as a measured variable which are given in are functionally related to the drop size, e.g. B. the pressure, or as an alternative, the parameters of a drop spectrum are measured directly or certainly. With a desired broadening of the spectrum, there is then a larger one Choose the difference in the form between individual nozzles or nozzle groups at If the spectrum is narrowed, this difference must be reduced. The middle drop size is independent of this by choosing a higher form for the entire nozzle system reduced or increased by a lower admission pressure.

In addition, the method can also be used to determine the local distribution of the change sprayed amounts. The drop sizes generated can be the same kept constant in time or additionally changed. Inside the nozzle systems of a spray tower it is possible to lower the nozzles or nozzle groups to arrange different heights, with nozzles with which large drops are formed will be installed at a higher location. The nozzles or nozzle groups can also in the radial direction, lying on one level at different distances are arranged to each other, e.g. B. Nozzles that will produce large drops in installed a smaller distance from the central axis of the tower. This measure is particularly well suited for the production of agglomerates.

Within an installed nozzle system, e.g. B. a nozzle practically always Produce particles with the same droplet size distribution while the other nozzle produces either larger or smaller drops. With the specification of a division ratio for the throughput that passes through both nozzles, one determines the Change in the spectrum. However, you only change the division ratio by the total throughput is distributed to both nozzles, but not the pre-pressure, so it represents there is no broadening of the spectrum. But you can change the place with it where the main throughput is to be atomized in a spray tower. So can you either atomize more in the middle or more on the edge of a tower and thus specifically influence processes such as agglomeration.

Of course, these statements also apply to the combination of several Nozzles to groups of nozzles that operate as indicated above. Terms Lich further details on the proposed procedure and the implementation  The piping system suitable for the method is based on the following Examples referenced.

The invention will be explained below using a few examples. In the show associated drawing

Fig. 1 shows the circuit diagram for a pipe system with a pump, three valves and two nozzles,

Fig. 2 shows the circuit diagram for a line system with two pumps, two valves and two nozzles,

Fig. 3 shows the circuit diagram for a line system with four pumps and two nozzles,

Fig. 4 is a circuit diagram for a pipe system with a pump, three valves and four nozzles,

Fig. 5 is a circuit diagram for a pipe system with a pump, two valves and four nozzles,

Fig. 6 shows another circuit diagram for a line system with a pump, two valves and four nozzles for use in a spray tower.

In the following examples, different process variants and the associated pipe systems explained in more detail. In each of the examples are at least two nozzles are provided as single-substance pressure nozzles, which atomize the Allow fluids regardless of total throughput and where the drops size of the fluid to be atomized changed during the operating state can be. Such nozzles have two feeds that are inside the nozzle tangential and radial or only tangential channels are connected and in one Swirl chamber open. The feed into which an actuator, valve or pump, should either be connected to the non-tangential channels or with the tangential channels that enter the swirl chamber at the point of entry have a larger cross-section or in total the larger cross-sectional area. However, other single-component nozzles with two that serve the same purpose can also be used Feeders are used that are only radial and / or inside the nozzle have axial channels that open into a nozzle chamber.

The line system shown in FIG. 1 for supplying a liquid to the two nozzles is designed as follows.

The liquid removed from a container (not shown in any more detail ) is conveyed through a total fluid flow line 1 by means of a pump 2 arranged in this line. The design of the pump depends on the pressure increase to be achieved for the fluid to be atomized. In the total fluid flow line 1 a booster pump is thus involved, preferably may be pressure pump while a high. After the pump 2 , the total fluid flow FG is divided into the two partial flows T3 and T4 through the two partial flow lines 3 and 4 . A valve 5 is integrated into the partial flow line 3 . The two sub-streams T3 and T4 are divided by the respective further branches A and B into further sub-sub-streams T3a and T3b as well as T4a and T4b, which are each fed to a nozzle 6 and 7 , which are connected to lines 3 a and 3 b and 4 a and 4 b are related. The ratio of the sub-streams T3a and T3b and T4a and T4b fed to the nozzles 6 and 7 is influenced by means of the control valves 8 and 9 integrated in the sub-stream lines 3 a and 4 a. The partial flow T3a, T4a, which can be influenced directly by the valve 8 or 9 , is introduced in nozzles with tangential to the swirl chamber arranged feed channels in those feed channels with the largest cross section to the swirl chamber. In the case of nozzles which have feed openings which are not arranged tangentially to the swirl chamber, these are acted upon. The respective other partial stream T3b or T4b is then fed into feed openings which have a smaller radial or axial component in relation to the other channels or are arranged tangentially, but in any case cause a higher swirl speed.

The ratio of the division of the two partial flows T3 and T4 to the respective further branches A and B is regulated by means of the valve 5 integrated in the partial flow line 3 . If the valve 5 is throttled, the branch B is supplied with a larger amount of partial flow and at the same time atomizes a larger amount via the nozzle 7 than via the other nozzle 6 .

Regardless of this distribution on branches A and B, the drop size can be set separately for each of the nozzles 6 , 7 . For example, if the material properties and the properties of the nozzle do not change, it is generally sufficient if the pressure in front of the nozzle 6 , 7 is kept constant. For this purpose, the pressure can be measured and the respective valve 8 , 9 can be adjusted until a predetermined setpoint is reached. However, the drop size can also be measured and the valve positions changed until a predetermined value for the drop size is reached.

The following procedure is used to influence the drop size. If the valve 5 is opened, the same properties of the lines 3 and 4 with respect to the pressure loss occurring are atomized essentially the same amounts through the nozzles 6 and 7 . Is used as the pump 2 in the overall conveying line 1 is a positive displacement pump, it is possible by means of these that are set via the nozzles 6 and 7 to be atomized flow rate. The average drop size can then be influenced by changing the settings of the valves 8 and 9 . If the valves 8 and 9 are throttled evenly, a smaller medium drop size results because then a larger proportion of the liquid is atomized with a high swirl. If nozzles of the same design are used, the middle drop will change, but not the basic course of the drop spectrum. Of course, this only applies if one ignores additional phenomena which, like agglomeration processes, also influence the grain spectrum produced. This can occur in particular if nozzles are used which have strong changes in the spray angle with a different partial flow ratio and which can influence the drops of adjacent nozzles. If, however, nozzles are used which have a hardly changed spray angle when the admission pressure changes, only the mean drop diameter is influenced by changing the admission pressure. However, if one wishes to broaden the spectrum, each nozzle 6 , 7 must be operated with a different form. For this purpose, the position of the valve 5 integrated in the partial flow line 3 is changed so that the amounts of the partial flows T3 and T4, which lead to the branches A and B, which are atomized via the nozzles 6 and 7 , are determined. Instead of the valve 5 , a positive displacement pump can also be used, the advantage of which is that there is no need to measure the throughput, since the speed of this pump also serves as a measure of the quantity passed through. If you measure the drop or grain distribution of the product produced, you can intervene again in the sense of a regulation. If the mean grain diameter is increased, the desired values for the pressure in front of the nozzles 6 and 7 are reduced. If the spectrum is to become wider, the difference between the two pressure setpoints must be increased or the ratio of the partial flow quantities T3 and T4 increased. The measures described make it possible to change the mean droplet size or the width of the droplet spectrum during operation without changing nozzles.

In the variant shown in FIG. 2, two total fluid partial flows FGa and FGb are assumed, which, for. B. can be removed from a common container. A pump 2 a, 2 b is arranged in each of the total partial fluid flow lines 1 a and 1 b. The total fluid sub-flow lines 1 a and 1 b are divided behind the pumps 2 a and 2 b into branches A and B, which are designed analogously to the corresponding branches A and B according to FIG. 1 and provided with the same reference numerals as in FIG. 1 are. In this case, the two total fluid partial flows FGa and FGb form the total fluid flow FG according to FIG. 1. Each partial flow amount of the partial flows FGa and FGb is determined by the speed of the respective pump 2 a and 2 b. This means that information about the flow rate is available without flow rate measurement. Analogously to the measures described in FIG. 1, the drop size for each nozzle 6 , 7 can be set independently of the throughput.

By selecting the admission pressure in front of each nozzle 6 , 7 , as explained in relation to FIG. 1, the mean drop size is influenced and the drop spectrum is influenced by selecting different pressures for each of the nozzles 6 , 7 . The amounts that are atomized with each of the nozzles 6 , 7 at the drop size set can be adjusted via the speed of the pumps 2 a and 2 b.

The other embodiment variant shown in FIG. 3 differs from that according to FIG. 1 only in that displacement pumps 10 , 11 and 12 are used on parts of the valves 3 , 8 and 9 . The total fluid flow FG, which is conveyed by means of a booster pump 2 is divided after the pump 2 in the two substreams T3 and T4, in which the partial flow line 3, the positive displacement pump is integrated 10th After this pump 10 , the partial flow branch A is arranged, which is formed by the two sub-flow lines 3 a and 3 b, which are connected directly to the single-substance nozzle 6 with two liquid feeds without further branching. In the lower part 3 a power line a further positive-displacement pump 11 is incorporated.

The partial flow line 4 is also connected to a further partial flow branch B, which is formed by the two partial flow lines 4 a and 4 b, which are also connected to a second single-substance nozzle 7 with two liquid supply lines without further branching. A displacement pump 12 is also integrated in the lower part flow line 4 a. The two pumps 11 and 12 are each integrated in the lower flow lines 3 a and 4 a, which are connected to the supply channels within the nozzle with the larger cross-sectional area at the entry point into the nozzle chamber. This circuit variant enables additional regulating or control options for the fluid to be atomized. By means of the pump 10 in the partial flow line 3 , the partial flow ratio between the partial flows T3 and T4 can be changed, that is to say the partial flow quantities which are fed to the nozzles 6 or 7 . In practice, when atomizing fluids in a spray tower, the nozzles 6 and 7 are generally arranged at different locations in the tower. The quantities that can be atomized at different locations in the tower can thus be influenced by means of the pump 10 . By changing the delivery characteristics of the pumps 11 and 12 , the atomization quality can be regulated by changing the drop size for the two nozzles 6 and 7 . Using a common line system, variable portions with different droplet sizes can be atomized within a spray tower. The various setting options can be changed as required during operation.

Such a local division of the quantities to be atomized is expedient if, during the atomization process, specific agglomeration effects are to be used, which are influenced by the different position of the nozzles. However, the droplet spectrum can also be influenced by increasing or reducing the difference in the mean droplet size of the fluid emerging from the nozzles 6 and 7 , the pump 10 determining how large the quantity that is determined with the particular one is Drop size is atomized. Instead of the individual nozzles 6 , 7 shown , it is also possible to use a plurality of nozzles which form a so-called nozzle group.

The embodiment variant shown in FIG. 4 corresponds in its essential structure to the embodiment shown in FIG. 1. The only difference is that the branches A and B are each divided into two single-substance nozzles 6 a and 6 b and 7 a and 7 b with two feeds. The further division over the lines 13 and 16 to the nozzle 6 a, the lines 14 and 15 to the nozzle 6 b and the lines 17 and 20 to the nozzle 7 a and the lines 18 and 19 to the nozzle 7 b takes place after the last control valve 8 or 9 . In this parallel connection of several nozzles 6 a, 6 b and 7 a, 7 b, the nozzles are influenced simultaneously according to the method. The control valves 8 and 9 can thus be used independently of one another to influence the nozzles 6 a, 6 b and 7 a, 7 b connected in parallel. Otherwise, the same functions can be implemented in terms of method as in the embodiment shown in FIG. 1.

The circuit variant shown in FIG. 5 differs from that according to FIG. 4 in that the branching B ( FIG. 4) is replaced by a division into two single-substance nozzles 21 , 22 , each with a feed. The partial stream T4 is distributed directly via the lines 23 and 24 to the nozzles 21 and 22 . These two nozzles 21 and 22 cannot be influenced separately within the system according to the method. An influence is only possible on the nozzles 6 a and 6 b in the sense of the measures already described.

In Fig. 6, the same circuit structure as shown in Fig. 5 is shown, on the one hand the nozzles 6 a and 6 b which can be influenced according to the method with two feeds and on the other hand the nozzles 21 and 22 with a feed inside a spray tower 25 are arranged differently locally . In practice, several nozzles are usually arranged within a spray tower, so that, as shown in FIG. 6, the uncontrollable nozzles 21 , 22 are arranged concentrically with nozzles 6 a and 6 b. The conventional pressure nozzles 21 , 22 can, for example, be distributed in an outer ring. The influenceable nozzles 6 a, 6 b can then be arranged more in the middle of the tower 25 in order to be used specifically for agglomeration. The partial streams are controlled in the manner already described.

Claims (18)

1. A method for influencing the drop spectrum of fluid substances, in particular suspensions in the spray drying or prilling of melts, using a plurality of single-substance pressure nozzles ( 6 , 6 a, 6 b, 7 , 7 a, 7 b, 21 , 22 ), wherein With at least one nozzle ( 6 , 6 a, 6 b, 7 , 7 a, 7 b), the drop size can be changed independently of the throughput, which is based on a total fluid flow (FG) or several total fluid partial flows conveyed by pumps ( 2 , 2 a, 2 b) (FGa, FGb), which are divided in the delivery direction after the pump ( 2 , 2 a, 2 b) into several partial flows (T3, T4, T3a, T3b, T4a, T4b) and are fed independently, whereby several partial flows (T3 , T3a, T4a) via the delivery characteristic by means of valves and / or pumps ( 5 , 8 , 9 , 10 , 11 , 12 ) to at least one nozzle ( 6 , 6 a, 6 b, 7 , 7 a, 7 b) with two Feeders is influenced in such a way that the total throughput by means of the total fluid flow (FG) or the total fluid rapid flow (FGa, FGb) integrated pumps ( 2 , 2 a, 2 b) is set, and optionally, individually or in combination, the following measures are initiated during the operating state at the same or different times:

• a) the division ratio of the part of the streams (T3, T4, T3a, T3b, T4a, T4b) divided into the respective flow rates (T3, T4, T3a, T3b, T4a, T4b) of the nozzles ( 6 , 6 a, 6 b, 7 , 7 a, 7 b) the partial flows (T3, T3a, T4a) integrated valve ( 5 , 8 , 9 ) or pump ( 10 , 11 , 12 ) is set,
• b) via the two partial flows fed directly to the nozzle ( 6 , 6 a, 6 b, 7 , 7 a, 7 b), which can change the drop size independently, by means of a valve ( 5 , 8 , 9 ) or pump ( 10 , 11 , 12 ) the average diameter of the droplets, i.e. the droplet size, is set separately for the respective nozzle ( 6 , 6 a, 6 b, 7 , 7 a, 7 b) depending on the admission pressure applied in front of the valve or the pump and
• c) by setting different admission pressures for several nozzles integrated into the system ( 6 , 6 a, 6 b, 7 , 7 a, 7 b) by changing the division ratio according to process step a) in connection with the measures according to process step b) of the spectrum is changed.

2. The method according to claim 1, characterized in that in the conveying direction after the in the total fluid flow (FG) or in one of the total fluid partial flows (FGa, FGb) integrated pump ( 2 ) further parallel nozzles (( 21 , 22 ) with a supply line ( 23 , 24 ) are operated. 3. The method according to any one of claims 1 or 2, characterized in that the individual nozzles ( 6 , 6 a, 6 b, 7 , 7 a, 7 b, 21 , 22 ) are put into operation simultaneously or at different times. 4. The method according to any one of claims 1 to 3, characterized in that the pressure in front of the nozzles ( 6 , 6 a, 6 b, 7 , 7 a, 7 b) is determined and, depending on this, the partial flow ratios between the partial flows (T3, T4, T3a, T3b, T4a, T4b) can be set. 5. The method according to any one of claims 1 to 4, characterized in that various parameters of the drop spectrum during the operating state be measured or determined and regulated. 6. The method according to any one of claims 1 to 5, characterized in that the influenceable nozzles ( 6 , 6 a, 6 b, 7 , 7 a, 7 b) and the nozzles ( 21 , 22 ) which cannot be separately influenced within an atomization system in predetermined distances from each other. 7. The method according to any one of claims 1 to 6, characterized in that in the total fluid flow line (FG) and in the total fluid partial flow lines (FGa, FGb) pressure booster pumps ( 2 , 2 a, 2 b) are integrated. 8. The method according to any one of claims 1 to 7, characterized in that in the partial flow lines ( 3 , 3 a, 4 a) positive displacement pumps ( 10 , 11 , 12 ) are integrated and the respective throughput is determined via the speed of these pumps. 9. The method according to any one of claims 1 to 8, characterized in that the feed pumps ( 10 , 11 , 12 ) or the valves ( 5 , 8 , 9 ) in the partial flow line ( 3 , 3 a, 4 a) are integrated, the have the largest cross-section at the point of entry into the nozzle chamber of the nozzle ( 6 , 6 a, 6 b, 7 , 7 a, 7 b) or, in the case of a distribution over further partial flows, the sum of the cross-sectional areas at the entry points into the nozzle chamber have the greater value . 10. The method according to any one of claims 1 to 9, characterized in that when using nozzles ( 6 , 6 a, 6 b, 7 , 7 a, 7 b) with not exclusively arranged tangentially to the nozzle chamber supply channels, the pump ( 10 , 11th , 12 ) or the valve ( 5 , 8 , 9 ) is integrated in the partial flow line ( 3 , 3 a, 4 a), which in different directions in the nozzle chamber of the nozzle ( 6 , 6 a, 6 b, 7 ) opening supply channels is connected to such supply channels that ensure non-tangential introduction of the fluid into the nozzle chamber. 11. The method according to any one of claims 1 to 10, characterized in that the partial streams (T3a, T3b, T4a, T4b) within one of the branches (A, B) on several nozzles ( 6 a, 6 b, 7 a, 7 b ) can be divided. 12. conduit system for implementing the method according to at least one of claims 1 to 11, characterized in that in a total fluid flow line (1) has a booster pump (2) is integrated, and then the total fluid flow line (1) into at least two partial stream lines (3, 4) is branched, a valve ( 5 ) or a feed pump ( 10 ) being integrated in one of the partial flow lines ( 3 ), and at least one of the partial flow lines ( 3 ) being connected to a further branch (A) consisting of at least two partial flow lines ( 3 a, 3 b) and in one of these partial flow lines ( 3 a) a valve ( 8 ) or a feed pump ( 11 ) is integrated, and the two partial flow lines ( 3 a, 3 b) with at least one nozzle ( 6 , 6 a, 6 b) are connected, and the other partial flow line ( 4 ) branching off immediately after the pressure booster pump ( 2 ) is connected to at least one nozzle ( 7 , 7 a, 7 b, 21 , 22 ). 13. Pipe system for performing the method according to at least one of claims 1 to 11, characterized in that two sub-lines ( 1 a, 1 b) forming the total fluid flow (FG) are arranged, in each of which a pressure booster pump ( 2 a, 2 b ) is arranged, whereby at least one of the sub-lines ( 1 a, 1 b) is connected after the respective pump ( 2 a, 2 b) with a branch (A, B) consisting of at least two sub-flow lines ( 3 a, 3 b, 4 a, 4 b), which are connected to at least one nozzle ( 6 or 7 ) and in the branching (A, B) a valve ( 8 , 9 ) is integrated, and the other partial line ( 1 a, 1 b ) is connected to at least one nozzle. 14. Pipe system according to one of claims 12 or 13, characterized in that from the pump or valve-free partial flow line ( 4 ) branch off a plurality of further partial flow lines ( 23 , 24 ) which are connected to single-fluid nozzles ( 21 , 22 ) with a liquid supply. 15. Pipe system according to one of claims 12 to 14, characterized in that the first two partial flow lines ( 3 , 4 ) after the booster pump ( 2 ) on further line branches (A, B), consisting of at least two sub-flow lines ( 3 a, 3 b , 4 a, 4 b) are divided per line branch (A, B), and a feed pump ( 11 , 12 ) or a valve ( 8 , 9. ) In one of the sub-flow lines ( 3 a, 4 a) of each line branch (A, B) ) is arranged. 16. Line system according to one of claims 12 to 15, characterized in that the partial flow lines ( 3 , 3 a, 4 a) in which a feed pump ( 10 , 11 , 12 ) or a valve ( 5 , 8 , 9 ) is integrated, are connected within the nozzle ( 6 , 6 a, 6 b, 7 , 7 a, 7 b) to one or more supply channels which are located at the point of entry into the nozzle chamber of the nozzle ( 6 , 6 a, 6 b, 7 , 7 a, 7 b) have the largest cross-section or, in the case of a distribution over several supply channels, the sum of the cross-sectional areas at the entry points into the nozzle chamber have the greater value. 17. Pipe system according to one of claims 12 to 16, characterized in that at least immediately in front of a nozzle ( 6 , 6 a, 6 b, 7 , 7 a, 7 b), a pressure measuring device is integrated into the associated supply line. 18. Pipe system according to one of claims 12 to 17, characterized in that the feed pump ( 5 , 11 , 12 ) is designed as a displacement or centrifugal pump.