DE2628612A1 - Nozzle for high energy gas blast - uses two orthogonally positioned jets to introduce blast material under pressure - Google Patents

Abstract

The combined blast nozzle aims at increasing the concentration of blast material in the energy carrier jet. The blast nozzle assembly consists of chamber (1) into which jet is terminated. The chamber continues in accelerating tube (3) with a centreline coaxial with that of the jet. The chamber is further fitted with inlet connection (4) for the blast material feed. The connection is fitted with jet (2) with a centreline perpendicular to that of jet (2). Jet (2) serves for the supply of the energy carrying stream, chamber (1) serves as mixing chamber for steam and e.g. sand and the accelerating effect in the restricted part of the connection (14) and results in a priming action on the sand particles. The jet (2) is provided to act as an adjustable auxiliary jet to the main jet (2) to accelerate any medium entrained in form of secondary flow through the chamber (14).

Description

JET NOZZLE FOR SPRAY DEVICES

The present invention relates to jet nozzles which are often used as jets and in jet mills, sand and crushing blasting machines, in compressed air and flushing conveyor equipment, in compressed air cannons, atomizers, reactors, dryers and other blasting machines that are used for comminution and mixing and material handling, for cleaning the surface of products and others Operations are provided.

The invention can also be used in all branches of industry using these systems (such as construction and building materials industry, mining, metalworking industry, metallurgical industry, chemical industry, food industry).

A jet nozzle is already known, consisting of a mixing chamber, in which the incoming material with a Energy carrier (gas or Liquid) is mixed under an excess pressure, which from the in the chamber built-in nozzle flows out, and an acceleration tube, which is attached to the Nozzle opposite side of the chamber connects to Bb in which the to be conveyed Material is accelerated to the required speed (cf., the book by Akunow W.I. "Strahlnthlen", Verlag "Maschinostrojenije", M., 1967, p.

104, 105, 140, 141).

The main disadvantage of the known jet nozzle is a free, pressureless Introduction of the material to be conveyed through the jet nozzle into the out of the nozzle outflowing beam of the energy carrier, including a weakly intense one Introduction of free material by falling from a certain height.

The low concentration of the material in the in The energy carrier introduced by the jet nozzle does not allow the kinetic energy the latter for the transport and acceleration of material particles in acceleration pipe to be used by more than 30%.

The aim of the invention is to eliminate the above-mentioned disadvantage.

The invention is based on the object of developing a jet nozzle, the structure of which makes it possible to absorb a larger part of the kinetic energy of the in to use the same imported energy source, i.e. <-> enables <es>, in the same volume of the energy carrier flowing out of the nozzle into the chamber one to introduce a much larger amount of the material to be conveyed through the jet nozzle.

This problem is solved in that in the jet nozzle £ ur jet devices, consisting of a chamber for the penetration of the material to be conveyed with an energy carrier, which flows out into the rammer under excess pressure, and an acceleration tube connected to the chamber for the discharge of the material to be conveyed from the chamber at a predetermined speed, according to the invention the means for introducing the energy carrier under an overpressure at least is formed by two nozzles which open into said chamber in such a way that the rays of the energy carrier formed by these interact in the chamber cavity.

The jets of the energy carrier flowing out of the nozzles are expedient orthogonal to each other.

Another embodiment variant is also possible in which the nozzle axes coincide, and the jets of the energy carrier flowing out of them cooperate with the same occupancy.

In addition, another variant is also provided, in which the jet nozzle has three nozzles in the chamber in different Altitudes are arranged with the axes of the upper and the middle nozzle to each other run parallel and the axis of the lower Nozzle under a pointed Angle to the axes of the aforementioned two upper nozzles in the direction of material flow is inclined.

The invention consists essentially in the following. The creation a jet nozzle, in which the energy carrier into the chamber by means of at least two nozzles is stirred in, it allows the material particles into the chamber under pressure if e.g.

accelerated to introduce the energy carrier jets flowing out of the nozzles are orthogonal to each other.

This gives the possibility of adding to the volume of the energy source, which ejects from the nozzle in a unit of time; mt, a far larger amount of the to be conveyed material than with the known jet nozzles, i.e. the to reduce the specific consumption of the energy carrier for material transport.

By increasing the material concentration in the acceleration tube the resistance of the flow around the energy carrier around the material particles increases, and there is increased piston-like action on the particles.

This leads to a reduction in the acceleration length of the particles up to the maximum speed, i.e. to reduce the length of the device, whose part is the jet nozzle. In jet mills, for example, the the latter circumstance in turn to reduce the length of pipelines for the Return of the semolina from the separator into the nozzles, which Length due to the conditions of free pouring of the semolina into the jet nozzles is conditional, as well as to reduce the height of the pipe, which is with the jet nozzles provided I.ahlteil connects with the separator. Thus the length, the height and the total mass of the jet mill as well as the amount of compressed air conveyance of the ground Material and thus correspondingly the energy expenditure for this is reduced.

Reducing the particle acceleration length with simultaneous A corresponding shortening of the acceleration tubes leads to the shortening of the expensive abrasion-resistant material lined section, a reduction the specific wear of this lining (resp.

the wear mass per one product unit) as well as to reduce the contamination of the jet nozzle product by the abraded lining material.

As a result of the above, the need and accordingly the price of the required energy source by 10 to 30%, the operating costs of the Jet nozzle e.g. when introducing the material into any volume with compressed air (especially when conveying compressed air) also by 10 to 30% and with the Use of the jet nozzles according to the invention in jet mills reduces the operating costs 15 to 4074, the consumption of abrasion-resistant lining by 10 to 25% <> and also the necessary building space for the building to accommodate the mills <decreased> decreased.

In order to better explain the invention, embodiments according to the invention are provided Rungs jet nozzles explained with reference to the drawings: it shows a Fig. 1 jet nozzle for jet mill with a means for introducing the energy carrier, which by two nozzles are formed whose jet directions are mutually orthogonal (longitudinal section); a jet mill at de @ Fig. 2 the means for introducing the enerei st gieträgers three nozzles, the jets of which are rectified.

The jet nozzle shown in the drawings is for jet mills for the comminution of abrasive material, e.g. sand from impact / its particles intended. The acceleration of these particles is due to the opposite Jet nozzles causes. Superheated steam with a pressure of 8 ata.

The jet nozzle (FIG. 1) consists of a nozzle opening into the chamber 1 the nozzle 2, an acceleration tube 3, whose longitudinal axis coincides with the axis of the nozzle 2 coincides, a nozzle 4 and a nozzle 2 ', which are transverse to the beam of the energy carrier is arranged, which flows out of the nozzle 2. The nozzle 2 is for the introduction of the Steam energy carrier in the jet nozzle and for the formation of the working jet Jet nozzle provided.

The chamber 1 is used to mix sand with the overheated Steam and dragging the sand through the latter into the acceleration tube 3. The acceleration tube 3 accelerates the sand particles in the rammer 1 the nozzle 4 are introduced. The nozzle 22 is arranged so that they have a adjustable auxiliary jet from the steam energy carrier or sucked in through the jet nozzle Air, exhaust steam, water and any gas or liquid for pre-acceleration the sand particles and energetic, intensive entry into the working steam jet directs. The energy carrier flows flowing out of the nozzles 2 and 2 can thereby be orthogonal to each other, and trap, when the axes of these nozzles coincide, the energy carrier flows work together when moving in one and the same direction.

The jet nozzle according to the invention (see FIG. 1) operates as follows. The sand, which is intended to accelerate the jet nozzle, enters the chamber 1 via the nozzle 4. The sand particles are in the chamber 1 from the nozzle 2 escaping steam jet entrained, through this into the acceleration tube 3 introduced and by the same steam jet energy vacuum, which as a working organ the jet nozzle is used, accelerated in the same tube 3. The acceleration takes place up to a speed suitable for the introduction of the crushing particles from the jet nozzle into the grinding chamber of the jet mill and its subsequent comminution in the collision with those flying out of the opposing jet nozzle Sand particles is required.

With the expansion of the energy carrier beam after its outflow A vacuum is created in the chamber 1 from the nozzle 2. This allows the To let air flow through nozzle 2 'e.g. outside air. The one flowing out of the nozzle 2 ' A jet of this air accelerates the sand particles in the nozzle 4 and in the chamber 1, this-jet pushing the particles into the expanding steam jet with force drives in, which flows out of the nozzle 2. This increases the concentration of the sand increased in the beam of the energy carrier.

Is the energy of the suction air jet for an effective introduction of the sand in the energy carrier insufficient, or temperature difference of the Energy source and the outside air are not <allowed> to use the latter, in this way, used hot energy carrier or heated air or the same energy source as that of the nozzle 2 fed to. With certain technological conditions, e.g. when combining technological processes during jet grinding, at a high temperature of the energy source, etc. cold resp.

hot water or any liquid or chemical Reagent are supplied.

The jet nozzle shown in Fig. 2 consists of the same components like the jet nozzle shown in Fig. 1, arrangement and accordingly the constructive Solution have been changed and added a little.

The jet nozzle consists of a chamber 1, three in various Altitude in the chamber 1 arranged nozzles (2.2 ', 2 "), an acceleration tube 3, a nozzle 4, distribution chambers 6 and 7 and those in communication Nozzles 8 and 9.

The nozzles 2, 2 ', 2 "are for directing the jets in the same direction the energy source or the air, the water or

an auxiliary gas or liquid (in accordance with the conditions) provided in the rammer. The axis of the upper nozzle is 2 'and the middle one Nozzle 2 is arranged parallel to one another, while the axis of the lower nozzle 2 "is closed the axes of the nozzles a and 2 'at an acute angle in the material conveying direction is inclined. The distribution chambers 6 and 7 are -for the supply of the above named auxiliary gas or -zu - liquid / the nozzles 2 ', 2 "and the nozzle 8 and 9 are provided for receiving the gas or the liquid.

The operation of the jet nozzle shown in Fig. 2 is as follows. The sand enters the chamber 1 via the nozzle 4. Its particles are from the entrained steam jet flowing out of the nozzle 2, by means of this jet in the acceleration tube 3 inserted and accelerated visit with the same steam jet. At the end of the acceleration tube 3, the sand particles have a speed which is required for their entry into the grinding chamber of the Stralilmühle.

Under the action of the pressure or vacuum that is in the chamber arises during the operation of the nozzle 2, flow au; 3 the nozzles 2 'and 2 "in the Chamber 1 emits the air jets or the jets of steam as an energy source. The jets entraining the sand particles emerging from the nozzle 4 lead the material to be ground in the expanding, flowing out of the nozzle 2 Beam of the energy carrier. The concentration of the material to be ground in the accelerator tube 3 increases by 15 to 40% compared to the usual pipe. Beyond that in the described mode of operation of the means for introducing the energy carrier in the jet nozzle according to the invention losses in the mutual frictional work the sand particles present in the chamber 1 or losses when they are fed into the Removed acceleration tube 3, which occurs when the working nozzles 2 ' and 2 "are missing and a significant part of the sand particles <to the ground> in the chamber 1 <> falls. The air or the steam reaches the nozzles 2 'and 2 "via the Distribution chambers 6 and 7 with their receptacles 8 and 9.

The overall efficiency of the jet nozzle according to the invention is as mentioned above, from a reduction in the total consumption of the energy source by 10 to 40% and the abrasion of the lining for the acceleration tubes by 10 up to 25%, a reduction in the dimensions and mass of the jet nozzles and the size of the operating rooms intended to accommodate the juas armor.

L e r s e i t e

Claims (4)

P A T E N T A N S P R Ü C H E: 1st jet nozzle for jet devices, consisting of a chamber for the mixing of the material to be conveyed with one from the same under an overpressure, escaping energy carrier and one the acceleration pipe connected to the Eammer for the discharge of the to treating material from the chamber at a predetermined rate thereby not indicated that the means to introduce the energy carrier under an overpressure is formed by at least two nozzles (2, 2) which enter the chamber (1) open in such a way that the rays of the energy carrier formed by them cooperate in the cavity of the chamber (1). 2. Jet nozzle according to claim 1, characterized in that g e k e n n -z e i c h n e t, that the jets of the energy carrier flowing out of the nozzles (2 ', 2 ") are relative to one another are orthogonal. 3. Jet nozzle according to claim 1, characterized in that g e k e n n -z e i c h n e t, that the axes of the nozzles (2, 2 ') coincide and those flowing out of the same Rays of the energy carrier interact in the same direction of movement. 4. Jet nozzle according to claim 1, characterized in that g e k e n n -z e i c h n e t that they have three nozzles arranged at different heights in the chamber (1) (2,2 ', 2 "), the axis of the upper nozzle (2') and that of the middle Nozzle (2) run parallel to each other while the axis of the lower Nozzle (2 ") at an acute angle to the axes of the named nozzles (2.2 ') in Material conveying direction inclined isj.