DE2065063A1 - Fluidic oscillator. Elimination from: 2017 600 - Google Patents

Description

Pluidik oscillator The present invention relates to a fluidic oscillator, especially for a spray head, with a power nozzle, a pair of control channels, which open into opposite sides of an interaction chamber, a pair of feedback channels and an exit area, which diverges outwards Has winds and emits a pulsating current.

It is already known, a fluidic oscillator for generating a pulsating beam to use the reciprocating motion of a tooth burstc instead of an electric drive (Fluiden, 1965, page 104, edited from Fluid Amplifier Associates, Boston).

Such fluidic oscillators use to achieve the current switching a feedback, with part of the operating resources usually being fed back is to control nozzles in order to achieve a flow deflection in the opposite Perform sime. If a liquid is used as the operating medium, work the oscillators are usually quite slow and the oscillators need to be more fluid Environment, which limits their applicability.

Such a limitation makes the use of these known oscillators impractical for applications where the fluid is a liquid is, while the respective environment is gaseous, such as for a Shower applies The invention is based on the object of a fluid oscillator using both a liquid and a gas as the fluid can, and also when using a liquid fluid in ambient air can work without constant leakage of fluid from each of them working outlet takes place.

According to the invention, this object is achieved in that each feedback channel between one of the control channels and the exit area extends through opposing locations in the walls of the exit area, and the feedback channels enter the exit area at such an angle that the pressure in the interaction chamber is on one side of the flow as a result the feedback of the fluid through a channel less is than the pressure on the other side of the power flow as the result of the feedback of the gas pressure in the outlet area through the other feedback channel.

Diverge in a further embodiment of the oscillator according to the invention the walls of the interaction chamber, starting from a narrow entry area a small angle near the outside and converge with a relatively strong curved angle towards a neck, which adjoins the chamber Area connects to the exit area of the fluid oscillator.

According to one embodiment of the oscillator according to the invention are Arranged in the exit area two island-like fluid dividers, which one generate the same flow.

In a further embodiment of the invention, the variable D is a function of T within the range delimited in FIG. 2 by the curves W A and B; included where D = distance from the output of the power nozzle to the oscillator neck (10), W = width of the power nozzle, T = width of the ifals (10).

The invention is then based on Hantl of an exemplary embodiment described. 1 shows a schematic sectional view of a inventive oscillator, FIG. 2 shows a graph from which the necessary Relationship between the various dimensions of the oscillator after Fig. 1 can be seen to achieve an oscillation and Fig. 5 shows a longitudinal section of the oscillator according to the invention.

According to FIG. 1, the oscillator 5 according to the invention has a power nozzle 1, which a flow in an interaction area 2 and from there through an area 3 inclined initially outward and then inward, which ends in a neck 10 which extends into an exit area which widens towards the end 4 opens. The oscillator has a pair of control nozzles 6 and 7, each over Feedback channels 8 and 9 with the upper and lower side of the outward widening area 4 downstream of area 7 are connected.

When the device is in operation, the one coming out of the power nozzle 1 occurs The flow initially enters the interaction area 2 in the middle and flattens the area 3 with a mixture of flow, spray and trapped air bubbles, ' while part of the flow exits from area 3 into area lt. From the liquid flow emerging from the power nozzle 1 (its moment and speed) and the resulting mixture of flow, spray and air bubbles, which moves from area 2 through area 5 to area 4 tends to be as Result of disturbances of the flow more on the lower or more on the upper wall of area 3 to adhere. The mixture adhering to a wall in this way has a tendency to follow the lower wall of the area 3, for example, and is shown in the Area 4 ejected against the top wall of the same. The ones on the control nozzles 6 and 7 in area 2 passing flow exerts on these control nozzles and the with them connected feedback channels e 8 and 9 from a strong suction effect. the controlled Flow mixing, which is ejected into area 4 and is in abutment with the top wall of the same is in the feedback channel 9 and flows through this channel and through the control nozzle 7 into the area 2, while through the feedback channel 8 and through the control nozzle 6 only Air in the area 2 on the lower side of the exiting through the power nozzle 1 Power current is sucked in. Because the volume of air flow as a result of suction through the control nozzle 6 is much larger than the volume of the flow through the Control nozzle 7, passing flow mixture, occurs on the upper side of the Power flow in area 2 has a lower pressure than on the lower side, whereby the power flow is applied to the upper wall of the area 2 and the upper wall of the area 5 follows, so that the star now to the lower wall of the area 4 is deflected.

The foregoing process is followed by a small portion of the Supports current in area 5, which is peeled off there and as a result of the curvature on the neck 10 from the area 3 to the area 4 in the area 5 wi.rd. Of the Returned flow part circulates within the area 3 in a clockwise direction thus giving positive feedback to the power current at the top To hold wall. This feedback flow also causes the exit to close of the area 5 against outside air, which is otherwise only partially with fluid The filled area 4 could enter the area 5 and the correct and the desired operation of the oscillator.

The deflection of the power flow towards the bottom wall of area 4 makes it possible that at the entrance to the feedback channel 8 flow stream from the Power current is sucked in, which then through the feedback channel 8 and the control nozzle 6 on the lower side of the power flow in area 2 lower pressure than generated on the upper side. This will remove all of the liquid sucked from the feedback line 9 via the control nozzle 7, and further is Air sucked in from the top of area 4. This reversal of pressure on both sides the power flow in area 2 in turn causes a deflection of the power flow to the lower wall of area 3, which is supported by the feedback in area 5 so that the power flow is now diverted to the upper wall of the area 4.

In the aforementioned manner, the flow between the upper and lower wall of the area 4 deflected, at a speed which is determined by the time delay, which is proportional to the speed the flow in the channels is the speed of the power flow determines the time delay in the forward direction from area 2 to area 4 while the velocity of the feedback flow the feedback time delay from Sets area 4 to area 2.

The latter speed is a function of the pressure difference between the feedback channel entrance in area 4 and the feedback control nozzle in area 2. Since the pressures at these two points are determined by the extent of the suction are given, whereby the suction effect in area 2 is always greater than in area 4 is, the time delay and therefore the oscillator frequency can not only be by one Change of the channel length and the speed of the power flow are changed, but also through changes in shape in area 2 and in area 4.. In particular change the shape and direction of the feedback channel inputs in area 4 large changes in the pressure at these points, as can be seen without further ado Fig. 1 can be seen where in the extreme through the feedback channel inlet flow derive and a high pressure (and thus a low feedback delay) could get or where by means of an almost tangential guidance of the feedback channel in the area 4 a strong suction effect (and thus a low pressure and a could get big delay. The entry angle of the FückkoppluiCkanal in the area 4 is limited in the case of a discharge of flow, since when the angle is too large, the feedback pressure of the liquid predominates and the flow Is deflected onto a wall of the area 3 and then no longer switched can be.

As previously described, the flow between the upper and lower wall articulated back and forth and creates a pulsating flow represent.

In the area 4, two small islands 11 can be arranged for this purpose serve to divide the currents so that the pulsating effect, if desired, is reduced and a more even water flow is created compared to the position of the current at the mouth of area 4. The oscillator can be flat be, d. H. each of the kanciles has a rectangular cross-section; the Channels of the oscillator have a depth that depends on the amount of water to be dispensed under a given water pressure.

The parameters of the oscillator are shown in the graph in Fig. 2 shown. In this representation, the values D, W and T each indicate the distance from the output of the power nozzle to opening 10> the width of the power nozzle and the width of the opening 10. The dimensions D and T are given as quotients D / W and T / W applied.

In the curve display, an area is delimited which is marked by the lines A and B are determined, which emanate from point C, being this area limits the operating range of the oscillator on three sides. If the mentioned Dimensions of the oscillator above the operating range or above a line parallel to the T / W axis starting from point C, the device is monostable.

If, on the other hand, the dimensions of the oscillator are such that they fit into a Operating range fall below the said line, the power current not distracted.

Lines A and B are parallel over a wide range of their length and have a slope of approximately 10.

As soon as the lines approach point C, they converge at about 2.4 of the T / W coordinate, two of the T / W coordinate and about 19 of the D / W coordinate.

The oscillator according to the invention can, for example, be used in connection can be used with a spray head 12 shown in Fig. 5, which one with Has internal thread equipped connection nut 15. The spray head 12 can be external be of a known shape, sheet metal on the outside in an essentially conical shape Training rejuvenates. A fluidic oscillator 14 is attached within the spray head, which according to the order. Fig. 1 can be formed.

The spray head can expediently consist of a plastic molded part, the oscillator 14 being provided by channels in the mating sides of the mold halves is formed. The spray head 12 terminates at the water dispensing end, i. H.

in Fig. 5 at its right end in an annular shoulder 16, which delimits a remote area 17 on its inside.

The outlet area 4 of the oscillator 14 has an interior essentially dixergierenc outwards, it Element 18 on which has a rounded, smaller end which is on the left according to FIG. 3, wherein different parts of the Sprühkoprs, which are described below, by means of a bolt 19 to be attached know. The annular shoulder 16 is in the Areas 21 and 22 slotted to receive a slide 23, which with two substantially rectangular openings 24 is provided. The slide carries on its surface on the left according to FIG. 3, stop pins 26, which rest against come with the annular shoulder 16 to allow movement. of the slide closed limit.

In the position of the slide shown in FIG. 3, the slots are 24 arranged in alignment with the outlet openings of the area 4, so that in this Position the water passing through the oscillator passes through the slide, u; to be thrown against the body of the user of the spray head.

If the sieve is moved upwards, the openings 24 are no longer there aligned with the area 4 so that the water moved by the oscillator hits a solid surface of the slider and into the stepped area 17 of the spray head 12 arrives, which is limited by the Rign 16; is.

The slide 25 is located; above the bottom surface of the deposited Area 17 so that the water can flow around the slide when the openings 24 are not aligned with area 4 of the oscillator. he spray head is with an end plate 27 which has a number of small openings 28, which are arranged in the direction of movement of the water; are. The hinged by the slide 23 Water flows when the slide openings 24 are not; with the outlet openings The oscillator must be in line, around the slide and through the openings 28 and reaches the user's body as a spray jet.

If the user wishes to use the vibrating effect of the spray head, so the slide is brought into the position shown in FIG. 7, wherein the Oscillator 14 causes an alternating movement of the water between the channels 29.

A pulsating stream, for example, has the ability to remove dirt more effective than a continuous jet of water. Therefore, an inventive Oscillator can be used in cleaning paths and streets by the Oscillator is used as a spray nozzle.

The oscillator according to the invention can also be used for stirring or mixing of substances are used.

The oscillator is shown in Fig. 1 as a planar arrangement. It however, it should be noted that the oscillator is used to increase the flow rates or flow forces can have a spatial training and in particular one Shape could be created by rotating the two-dimensional image of the Fig. 1 arises around an axis which runs parallel to the longitudinal axis of the figure, for example by rotating around the lower edge of the body 5.

Such a device provides an annular flow which expands and diminishes in its diameter.

As a result of the ring formation, relatively large currents can flow and thus large flow forces are obtained.

Claims (5)

P a t e n t a n s p r ü c h e 1. Fluidic oscillator, especially for a spray head, with a Power nozzle, a pair of control channels, which in opposite sides open to an interaction chamber, a pair of feedback channels, and a Exit area, which has outwardly diverging walls and a pulsating one Emits flow, characterized in that each feedback channel (8, 9) between one of the control channels (6,7) and the exit area through each other opposite locations in the walls of the exit area, and the Feedback channels enter the exit area (4) at such an angle that the pressure in the interaction chamber (2) on one side of the flow as Consequence of the feedback of the fluid through one of the channels is lower than the pressure on the other side of the power flow as a result of the feedback of the gas pressure in the outlet area through the other feedback channel. 2. Fluidic oscillator according to claim 1, characterized in that the walls of the interaction chamber (2) starting from a narrow entry area diverge outwards at a small angle ud relatively diverging with one strongly curved angle to a neck (10) converge, which is a oh to the area (3) all-closing the chamber with the exit area of the fluid oscillator connects. 3. Fluidic oscillator according to claim 1 to 2, characterized in that that two island-like fluid dividers (11) are arranged in the outlet area (4) which produce a more even flow. 4. Fluidic oscillator according to claim 1, characterized in that the quantity D / W plotted as a function of T / W within the in Fig. 2 by the Curves A and B limited area; where D = distance from the exit of the Power nozzle to the oscillator neck (10), W = width of the power nozzle, T = width of the neck (10). 5. fluidic oscillator according to claim 1, characterized in that the control channels and outlet openings are designed as rotating bodies, which obtained by rotating a planar oscillator arrangement about a longitudinal axis thereof will.