DE10241949A1 - Pipe cleaning nozzle - Google Patents

Abstract

The invention relates to a blasting device for cleaning the inside of a pipe (2), which comprises a nozzle (3) and a deflector (6), the deflector (6) being at least partially arranged in the widening section (5) of the nozzle (3) , The cross-sectional area (12) of the annular gap (11) formed between the deflecting body (6) and the nozzle (3) increases in the direction of flow.

Description

The invention relates to a blasting device for Cleaning the inside of a pipe, which comprises a nozzle and a deflector, being the nozzle a tapered one Has section in which the flow cross-section in the flow direction decreases, and downstream of the tapered Section has an expanding section in which the Flow area in the direction of flow increases. The invention further relates to a method for Internal cleaning of a pipe with an abrasive, which with a main flow direction into a nozzle enters the nozzle accelerated and from the main flow direction towards the Inner wall of the tube is deflected.

When blasting with dry ice is dry ice granules in the size of rice grains, so-called pellets, in dosed a stream of compressed air, accelerated in a jet nozzle and then aimed at the object to be blasted. The pellets cool when they hit on the object's surface at certain points and become brittle this. The embrittled surface layers are removed by subsequent pellets.

When cleaning the inside of pipes with dry ice, blasting devices are used, such as those in the EP 1 035 947 B1 are described. A compressed air jet, into which dry ice pellets have been dosed, is fed to a Laval nozzle and accelerated in it. An axially symmetrical, cone-like deflection body is arranged downstream of the nozzle, which deflects the axially extending jet in a conical shape to the outside. For pipe cleaning, the device is pushed, for example, with a rod through the pipe to be cleaned, the conical flow generated with the aid of the deflecting body striking the inner wall of the pipe and cleaning it.

The air dry ice jet is in the jet nozzle accelerated to speeds up to the supersonic range. When the accelerated dry ice granules hit the deflector the granules into a large one Part destroyed. Furthermore, seem upstream End of the deflector shock waves going out, which also destroy pellets that are not directly on the Tip of the deflector to meet.

This problem doesn't just occur the use of dry ice particles as an abrasive, but also when using other particles. With very hard abrasive particles can vice versa also damage of the deflector occur.

The object of the present invention is it, therefore, an apparatus and a method for blasting a To develop abrasive, the above problems as possible be avoided.

This object is achieved by a Device of the type mentioned solved in which the deflector at least partially located in the widening section of the nozzle is so that there is an annular gap between the deflector and the nozzle forms, the cross-sectional area of the annular gap increasing in the flow direction.

The internal cleaning method according to the invention a pipe with an abrasive, which with a main flow direction enters a nozzle, in the nozzle accelerated and from the main flow direction towards the Deflected inside wall of the tube is characterized in that the abrasive while or after it is distracted, accelerated.

According to the deflector in the widening section of the jet nozzle arranged. The abrasive strikes the deflector in an area where it is not yet maximum flow rate has reached. The kinetic energy of the blasting medium is corresponding lower, which, compared to the conventional arrangement in which the deflector of the jet is downstream, damage to the deflecting and the nozzle as well as destruction of the Abrasive particles can be significantly reduced.

The widening of the initially axial blasting media flow takes place in a gradually expanding Annular gap. The cross-sectional expansion of the annular gap causes one increase the blasting media speed and thus an improvement in the cleaning effect. The acceleration takes place simultaneously with the deflection of the abrasive flow in Direction of the inner pipe wall to be cleaned. With the previously known Devices, the blasting medium is first accelerated in a nozzle and subsequently by means of a deflector distracted. The problems described above when encountering of the highly accelerated beam appearing on the deflector are caused by the procedure according to the invention avoided. The invention is therefore particularly suitable for blasting with dry ice pellets.

Preferably, the deflector has on its upstream End up in the flow direction widening cross section to deflect the abrasive to the outside.

It is particularly favorable if the upstream end of the deflector in the rejuvenating Section of the nozzle located, that is in an area where the flow rate is still relatively low.

Further advantages can be achieved if means are provided upstream of the nozzle and / or in the tapering section of the nozzle, which impose a swirl flow component on the blasting medium. Depending on the type of impurities to be removed and the abrasive used, the cleaning effect can be significantly increased. In addition, because of the swirl flow, fewer abrasive particles will be in the center of the blast, so that even fewer abrasive particles will strike the deflector. The destruction of abrasive particles is further reduced.

The invention and further details The invention are described below with reference to the drawings illustrated embodiments explained in more detail. in this connection demonstrate:

1 a blasting device according to the invention,

2 a detailed view of 1 and

3 an alternative embodiment of the invention.

In the 1 and 2 A blasting device according to the invention is shown as it is used for cleaning the inside of pipes with dry ice pellets, in particular heat exchanger pipes of petrochemical plants. The device has a cylindrical sleeve 1 whose outer diameter matches the inner diameter of the pipe to be cleaned 2 is adjusted. In the sleeve 1 there is a jet nozzle 3 that have an upstream section 4 has, in which the flow cross section decreases. A section closes downstream 5 in which the cross-sectional area for the flow increases again. The direction of flow in the figures runs from left to right.

At the inlet of the nozzle 3 are spring steel elements 30 appropriate. In operation of the device, a stream of compressed air and dry ice pellets is fed into the pipe 2 headed and in the nozzle 3 accelerated. This forms between the upstream and downstream of the nozzle 3 a pressure drop, creating the spring elements 30 to the inner wall of the pipe 2 be pressed.

The spring elements 30 provide a good seal on the nozzle 3 against the inner wall of the pipe 2 forth so that the abrasive does not pass through the annular gap between the nozzle if possible 3 and pipe wall 2 flows. The spring elements 30 also ensure that the nozzle 3 in the tube 2 is positioned centered and thus an even cleaning of the pipe 2 is achieved. This is particularly advantageous if the sleeve 1 not exactly on the inside diameter of the pipe 2 is adjusted.

A deflector 6 protrudes with its upstream end 7 partially in the expanding section 5 the jet nozzle 3 , The deflector 6 is designed in such a way that its cross-sectional area initially increases in the direction of flow (section 7 ) and then decreased again (section 8th ). The deflector 6 is with three holding pins 9 , which are at an angle of 120 ° to each other in a plane perpendicular to the direction of flow, at the jet nozzle 3 attached. Fastening with two or four retaining pins has also proven itself. To the axis of symmetry 10 of the blasting device, the holding pins each have an angle between 20 and 70 °, preferably between 30 and 60 ° and particularly preferably of 45 °.

The upstream part 7 of the deflector 6 is carried out in such a way that the desired flow angle of the dry ice-air jet onto the pipe wall 2 is achieved. The cross-sectional area of the deflector 6 extends from the upstream tip of the deflector 6 steadily, without any jumps or steps in the profile. This ensures that the dry ice-air jet gradually and gently in the direction of the pipe wall to be blasted 2 is redirected.

The downstream side of the baffle 6 is designed to minimize turbulence and pressure losses on the outflow side. Depending on the application, however, it may also make sense to use other designs of the deflector 6 to choose, which, for example, create special eddies or cause a swirl in the exhaust air flow.

The deflector 6 is on the axis of symmetry 10 the blasting device arranged so that between the exterior of the deflector 6 and the inner wall of the downstream widening nozzle section 5 an annular gap 11 forms. The profile of the nozzle section 5 is chosen so that the cross-sectional areas 12 of the ring gap 11 increase in the direction of flow. The expansion of the cross-sectional areas 12 corresponds to the expansion of the area ratio of conventional Laval nozzles. The expansion, ie the ratio of the maximum cross-sectional area to the initial cross-sectional area, is preferably 150 to 350%.

When dimensioning the deflector 6 and nozzle 3 it should also be noted that the annular gap 13 that is between the deflector 6 and the pipe to be cleaned 2 is at least as large as the maximum cross-sectional area 14 of the annular gap 11 between the deflector 6 and the expanding nozzle section 5 , This ensures that the dry ice-air mixture expands unchecked and reaches a maximum flow rate.

The nozzle body 2 and the deflector 6 are made of an abrasion-resistant material to prevent damage from the dry ice particles. Alloys such as Inconel or nitrided stainless steel have proven their worth here.

In 3 an alternative embodiment is shown in which the deflector 20 down to the upstream nozzle section 4 protrudes. The tip of the deflector 20 has shifted to an even slower flow region. Dry ice particles, the on top of the deflector 20 impact, have a relatively low kinetic energy, so that destruction of the dry ice particles are largely avoided.

Claims (10)

A blasting device for cleaning the inside of a pipe, which comprises a nozzle and a deflector, the nozzle having a tapered section in which the flow cross section decreases in the flow direction and downstream of the tapered section has a widening section in which the flow cross section increases in the flow direction , characterized in that the deflector ( 6 ) at least partially in the expanding section ( 5 ) the nozzle ( 3 ) is arranged so that between the deflector ( 6 ) and the nozzle ( 3 ) an annular gap ( 11 ) forms, the cross-sectional area ( 12 ) of the annular gap ( 11 ) increases in the direction of flow. Blasting device according to claim 1, characterized in that the deflecting body ( 6 ) at its upstream end ( 8th ) has a cross section widening in the flow direction. Blasting device according to one of claims 1 or 2, characterized in that the upstream end ( 7 ) of the deflector ( 6 ) at least partially in the tapered section ( 4 ) the nozzle ( 3 ) is located. Blasting device according to one of claims 1 to 3, characterized in that upstream of the nozzle ( 3 ) and / or in the tapered section ( 4 ) the nozzle ( 3 ) swirl generating means are provided. Blasting device according to one of claims 1 to 4, characterized in that the nozzle ( 3 ) and / or the deflector ( 6 ) have a surface made of abrasion-resistant material. Process for cleaning the inside of a pipe with an abrasive, which with a main flow direction into a nozzle enters the nozzle accelerated and from the main flow direction towards the Inner wall of the tube is deflected, characterized in that the abrasive while or after it is distracted, accelerated. A method according to claim 6, characterized in that the blasting agent by means of an at least partially in the nozzle ( 3 ) arranged deflector ( 6 ) is distracted. Method according to one of claims 6 or 7, characterized in that the blasting agent before entering the nozzle ( 3 ) a swirl flow is forced. Method according to one of claims 6 to 8, characterized in that that the blasting agent contains dry ice particles. Method according to one of claims 6 to 9, characterized in that that the abrasive is at supersonic speed is accelerated.