DE2657791A1 - Liq. jet mixing nozzle - has coaxial inlet and outlet tubes mounted in sleeve and pipe adjustably screwing together - Google Patents

Abstract

The jet nozzle is particularly for mixing two currents together, having coaxial inlet and outlet tubes mounted respectively in a sleeve (4) and a pipe (7). The sleeve is adjustable on the pipe, forming a seal between them. A chamber (9) formed between sleeve and inlet tube (2) has an inlet drilling passing radially through the sleeve and opening into a passage formed between coaxial conical surface (10,11) on inlet and outlet tubes. The distance between these surfaces is adjusted by screwing the sleeve on and off the pipe. The conical surface on the pipe can converge to a cylindrical drilling of smaller diameter than the inlet tube.

Description

Description of nozzle, particularly mixing nozzle. The invention relates to a Nozzle, in particular a nozzle, in which fluid streams are mixed.

The object of the invention is to provide such a nozzle with improved To create utility properties.

To solve this problem, according to the invention, the nozzle is thereby characterized in that it has coaxially extending inlet and outlet pipes, the are mounted in a sleeve or in a receiving head, the sleeve being adjustable is screwed onto the recording head and sealed against it, and that a chamber is formed between the socket and the inlet pipe which has an inlet bore which extends radially through the sleeve, the chamber in a Channel opens out between a first frustoconical surface which is at attached to an end portion of the inlet tube, and one complementary thereto coaxial frustoconical surface extends, the distance between the first Truncated cone surface and the complementary truncated cone surface by turning the receiving head is adjustable relative to the sleeve.

Expedient further refinements of the invention emerge from the subclaims, which / this description together with the main claim are prefixed.

In the drawing, exemplary embodiments of the invention are shown, namely show: FIG. 1 a three-dimensional representation broken away after a longitudinal section a first nozzle formation, FIG. 2 shows a corresponding representation of a modified one second nozzle formation.

The nozzle 1 shown in Fig. 1 has an inlet pipe 2, which the end portion 3 of a sleeve 4 provided with an internal thread penetrates and is soldered to that. A receiving head equipped with a ring seal 14 5 is screwed into the sleeve 4 and has a bore 6, which has a recessed, having threaded end portion 15 into which an outlet pipe 7 is screwed is. The end of the bore 6 facing away from the outlet pipe 7 is frustoconical Surface 12, which widens in the direction of the end region of the inlet pipe 2. The end portion of the inlet pipe 2 is convergent with a cooperating therewith frustoconical surface 11 provided, so that an annular in cross section Nozzle channel 10 is formed between the two surfaces 11 and 12.

The sleeve 4 has a radial, threaded inlet bore 8 communicating with a chamber 9 between the pipe 2 and the socket 4, wherein the chamber 9 opens into the nozzle channel 10. The distance between the surfaces 11 and 12, d. H. the cross-sectional area for the flow in the nozzle channel 10, which along of the channel decreases, can be adjusted by turning the receiving head 5 in the sleeve 4.

The nozzle has various uses. A special one Application is, for example, the use of the nozzle when cleaning ship holds, a long flow rate being advantageous, which is at a considerable distance from the nozzle impinges on the surface of the room over a relatively small area. In practice, the liquid jet tends to go beyond a certain distance to break off from the nozzle. Water at a pressure of 100 p.s.i. (about 7 kg / cm²) becomes the inlet pipe 2 and compressed air of approximately the same pressure becomes the inlet bore 8 supplied. It has been found that the compressed air flowing through the annular Nozzle channel 10 flows, the mentioned distance from the nozzle increased, in which the liquid jet is interrupted in the absence of additional compressed air. This is presumably due to the fact that the compressed air is a kind of jacket around the liquid jet forms. The adjustability of the size of the annular nozzle channel 10 enables the optimization of the management.

Another possible application is the creation of a grinding or emery jet from sand carried in water. The inlet pipe 2 is for this purpose connected to a supply of water and sand or another abrasive material, and water under high pressure is introduced through the inlet port 8 of the annular chamber 9 supplied. The water under high pressure flows through the ring-shaped Nozzle channel 10 in the direction of the axis of the nozzle and creates a partial vacuum in the nozzle, which a sand-air mixture through the inlet pipe 2 into the water flow pulls into it to form an abrasive jet that runs at high speed is discharged through the outlet pipe 7. Here, too, allows adjustability the size of the annular nozzle channel 10 optimizes the operating performance.

Another application example is the use as a jet pump. Water under high pressure wi.rd through the inlet port 8 fed to create a partial vacuum in the nozzle; up to 95% vacuum can be reached. The inlet pipe 2 is in communication with the material to be pumped, namely via a pipe (not shown), the free end of which into the material immersed. The partial vacuum created at the discharge end of the inlet tube 2 the material is drawn into the pipe, and the material is carried along in the water, ejected through the outlet pipe 7 and fed to a further pipeline (not shown), which for the purpose of delivering the material in a container with this is connected. The nozzle is suitable for conveying numerous materials, be it in the form of liquid particles or in powdered solid form or in mixtures thereof.

In the case of using the nozzle for grinding, its inner surfaces are held particularly wear-resistant. In Fig. 2, a nozzle la is shown in which the The receiving head 5 and the outlet pipe 7 according to FIG. 1 are replaced by a head 5a, which is equipped with a threaded hole 6a, which extends through the head 5a, wherein an outlet pipe 7a having a frustoconical surface 12a which is connected to the frustoconical surface 11 of the inlet pipe 2 cooperates, equipped so as to form the adjustable annular nozzle channel 10. Because the sanding jet so only hits the inside of the outlet pipe 7a, a wear of the remaining part of the nozzle avoided by the abrasive jet.

The outlet pipe 7a is only screwed out of the receiving head 5a, when the wear has become intolerable and replaced with a new pipe 7a. The inner diameter of the pipe 7a is larger than that of the pipe 7 of the nozzle according to FIG Fig. 1 (for a given size of the sleeve 4) what the nozzle 1a for use makes it more suitable as a jet pump because larger flow rates can be achieved.

The nozzles shown can easily be disassembled for cleaning will, and the adjustability of the annular nozzle channel enables the nozzle to to be easily adapted to the desired handling conditions.

In the description, in the drawing and in the claims disclosed features of the subject of the application can both individually and in any combinations with each other for the implementation of the invention in their various embodiments may be essential. Blank page

Claims (6)

Claims nozzle, in particular mixing nozzle for fluid streams, thereby characterized in that it has coaxially extending inlet and outlet pipes (2, 7), which are mounted in a sleeve (4) or in a receiving head (5), the Socket (4) is screwed adjustable onto the receiving head (5) and opposite this is sealed, and that a chamber (9) between the sleeve (4) and the inlet pipe (2) is formed which has an inlet bore (8) which extends radially through the sleeve (4) extends, the chamber (9) opening into a channel (10) which opens between a first frustoconical surface (11) which at one end portion of the inlet pipe (2) is attached, and a complementary coaxial frustoconical Surface (12) extends, wherein the distance between the first frustoconical surface (11) and the complementary truncated cone surface (12) by rotating the receiving head (5) relative opposite to the sleeve (4) is adjustable 2. nozzle after Claim 1, characterized in that the complementary truncated cone surface (12) is attached to the receiving head (5) and merges into a cylindrical bore <6), which is smaller in diameter than the inlet bore 3. Nozzle according to claim 2, characterized characterized in that the cylindrical bore (6) has the same diameter as the bore of the outlet pipe (7). 4. Nozzle according to claim 1, characterized in that the complementary Truncated cone surface (12) is attached to one end of the outlet tube (7). 5. Nozzle according to claim 4, characterized in that the bore of the Inlet pipe (2) is equal in diameter to the bore of the outlet pipe (7). 6. Nozzle according to claim 4, characterized in that the bore of the Inlet pipe (2) is smaller in diameter than the bore of the outlet pipe (7). description