EP2110447A2 - Lance holder with multiple tolerance chuck head - Google Patents

Abstract

The lance holder for lance pipe (2), comprises a clamping head (3), which comprises a fixing part (4) and a clamping part (5), to which a sealing sleeve (6) is arranged and clamped by the fixing part. The lance pipe is provided with a contact member, in which an adjustable pressure element is led to the longitudinal axis of the lance pipe in a right-angled manner and a pressure bevel of the clamping part is formed. The pressure bevel corresponds to the pressure elements, which are adjustably arranged over the pressure bevel against the wall of the lance pipe in a homogeneous manner. The lance holder for lance pipe (2), comprises a clamping head (3), which comprises a fixing part (4) and a clamping part (5), to which a sealing sleeve (6) is arranged and clamped by the fixing part. The lance pipe is provided with a contact member, in which an adjustable pressure element is led to the longitudinal axis of the lance pipe in a right-angled manner and a pressure bevel of the clamping part is formed. The pressure bevel corresponds to the pressure element. The pressure elements are adjustably arranged over the pressure bevel against the wall of the lance pipe in a homogeneous manner, and are produced in a point-type and/or line-type pressure load on the wall. Three balls are arranged as pressure elements. The fixing part comprises an intermediate external wall on the side opposite to the contact member, and starting wedge insertable in a protection housing (9). The clamping part comprises a locking sleeve, which surrounds the clamping part and is adjustably formed on an external thread of the protection housing. A ball bearing is arranged between the top wall of the clamping part and the clamping wall of the locking sleeve. A non-return valve is arranged between the sealing sleeve and a back fire protection, and over which the lance pipe inserted to a stop element is influenced and is releasably implemented to the gas flow in an open manner. An open return valve is intended on the side of the back fire protection, which is arranged with safety device housings detachably connected with the valves. The fixing part, the clamping part and the sealing sleeve are formed by 3-4 mm for metric and group dimensions.

Description

The invention relates to a lance holder for lance tubes used in metallurgical and steel industry with a chuck, which has a fixing part and a clamping part, which is associated with the inserted lance tube by means of the fixing part clamping and thus sealing sealing sleeve.

Lance holders with a clamping head and a slag return safety device or a burn back protection serve to keep the lance tube required for freshness safe and, on the other hand, for example, when a termination or interruption of the blowing process returning slag does not reach the oxygen access. After DE 23 27 595C a gas-permeable disc made of sintered metal is arranged just in front of the oxygen hose, which prevents the slag return. This mechanical shut-off of the slag return does not always meet the demands made, especially when larger amounts of oxygen must be enforced, because then a sintered metal disc naturally leads to difficulties. In this case, the upstream valve assembly also takes over a kind of slag return flow safety function, said valve closes when the seal arranged above is burned due to the slag return. The lance tube inserted into the lance holder is held over a clamping head with a collet arranged therein. By means of this collet, the inserted lance tube in the lance holder is determined by influencing the teeth of the collet. Behind this collet a sealing sleeve is arranged, which is influenced by the inserted tube and thereby deformed so that it rests close to the outside of the lance tube. This tight application by deforming the sealing sleeve has the first time Disadvantage that it may happen that the sealing sleeve cakes to the lance tube, so that when you open the collet, the rest of the lance tube is difficult or can be removed only by entrainment of the sealing sleeve. This problem and the special design of the collet brings with it the disadvantage that the respective lance holder must be adjusted with respect to its diameter pretty much the diameter of the inserted and to be held lance tubes. Currently, lance holders are in use that can accommodate and fix inch tubes, as well as those that can accommodate metric-sized lance tubes. Only very small tolerances by the movement of the collet and ultimately the sealing sleeve are possible, usually in the range of about 0.2 mm. As these lance tubes are consumables, factories are ultimately forced to buy both inch and metric tube diameters, which puts the workforce in trouble because they typically rely on only a few tube diameter accepting lance holders. This means that it always comes back to damage and accidents because when operated with the eingeschobnen too small or too large diameter for the fixation and sealing important items of the lance holder are damaged, so that then the lance holder is no longer functional , Since oxygen is introduced into the melt with these lance tubes and, to that end, the lance tubes generally have to be bent accordingly, the liquid steel of the operating crew can become dangerous especially when the lance tubes are slipping out or in the event of other problems. Unfortunately, even if the operating team has secured itself by suits and helmets, this is unfortunately not enough protection for the liquid steel, so that it can come again and again injuries and impairments.

The invention has for its object to provide a lance tubes for several while simultaneously as many dimensions simultaneously fully reliable and easy to handle lance holder.

The object is achieved according to the invention in that the inserted lance tube comprehensive fixing part is provided with a run-in, distributed in the distributed over the circumference at right angles to the longitudinal axis of the lance tube displaceable pressure elements and arranged on the one with the run-in slope corresponding pressure incline clamping part influenced influenced and formed are.

With the help of such a trained lance holder, it is first of all possible to hold the inserted lance tube accurately and safely when pressing the chuck, or especially the clamping part, which is pushed onto the fixing member by it is precisely fixed specifically targeted on the pressure elements. At the same time, the sealing sleeve is relieved. This ensures that once inserted lance tube can only be removed from it by deliberately pressing the clamping part. During the entire operation of the lance tube, but it is securely fixed, which is further protected by further measures, which are described below, the sealing sleeve from caking and is itself equipped with a diameter that allows the use of different sized lance tubes. The scope of different lance tube diameter is limited by the run-up slope and the corresponding trained clamping part, but a significant reduction of the Lanzenhalterbaugrößen is possible. The tolerance range is increased by the inventive design to about 0.5 - 3.00 mm depending on the structure of the lance holder. As a result, the number of lance tubes currently in use, for which a large number of lance holders were previously tailored to the required size, can now be reduced to 6-7. This is made possible by the fact that when sliding the provided for the respective lance holder sizes of the lance tube, the displaceable pressure elements are immediately active and effective, while at a lesser outer circumference having lance tube fixation is still possible because the sliding pressure elements then just after a corresponding Move effective and fix the lance tube.

According to an advantageous embodiment of the invention it is provided that the pressure elements are all simultaneously and uniformly slidably formed and arranged on the pressure ramp against the wall of the lance tube. With the insertion of the respective lance tube it comes with the lance tubes of the smallest possible diameter not to tilt or other problem because the individual pressure elements uniformly and simultaneously charged and pressed against the wall of the lance tube.

According to a further expedient embodiment, it is provided that the pressure elements are designed to generate a punctiform and / or linear load pressure on the wall. Thus, printing elements are used which do not press surface onto the lance tube, but point or line, so that a higher and more targeted pressure or load pressure can be generated.

According to a particularly advantageous embodiment, it is provided that the pressure elements are formed as balls, whereby the mentioned punctiform load pressure can be generated so that the lance tubes are optimally set, the lance tubes are usually made of mild steel, so for example ST 37, while the Balls are made of hardened material and can thus achieve long service life.

A particularly uniform and secure fixation of the lance tubes in the lance holder is given when evenly distributed over the circumference three balls are arranged as pressure elements in the starting slope of the fixing part. In this case, bores are expediently provided in the starting bevel, by means of which the respective ball can be pressed onto the surface of the lance tube, specifically from the pushed or displaced clamping part with its pressure bevel. For this purpose, the clamping part has, as mentioned above, an adapted pressure bevel, which runs uniformly, so that it is ensured that all three balls simultaneously in their bore on the inserted Lance tube are moved to keep this safe and so permanently to fix.

In order to avoid caking of the sealing sleeve during application to the inserted lance tube, a compression of the sealing sleeve in the longitudinal direction is therefore dispensed with. Especially with the larger tolerances of the lance tubes deformation would have to be done with considerable effort. This is avoided by the solution according to the invention, according to which the fixing part on the opposite side of the run-up slope has an insertable between the outer wall of the sealing sleeve and the surrounding protective housing wedge. This approach wedge acts on the sealing sleeve and ensures that it applies sufficiently tight to the outer wall of the lance tube and ensures a secure seal, and advantageously without having a compression in the longitudinal direction must be done. For this purpose, the neck wedge is displaced in the longitudinal direction and presses as desired, the sealing sleeve on the wall of the lance tube. If the fixing part is then withdrawn with its neck wedge when loosening again, the sealing sleeve is relieved, can deform back and detach from the residual lance tube, so that it can be easily removed from the lance holder. This uniform pressing against the lance tube also has the advantage that a continuous surface contact is possible, which would not be guaranteed in a compression of the sealing sleeve.

A displacement of the clamping part on the fixing part is expediently characterized in that the clamping part of the clamping head has a clamping sleeve, which surrounds the clamping part and is displaceably formed on an external thread of the protective housing. So it can be ensured with little effort that the clamping part is pushed accordingly to the fixing part and thus the balls are pressed against the wall of the lance tube. This process is carried out by simply turning the clamping sleeve, which can be facilitated by roughened gripping surfaces and the like of this rotation.

The ease of movement of this displacement process is thereby selectively increased, that between the top wall of the clamping part and the clamping wall of the clamping sleeve, a ball bearing is arranged. This ball bearing between the clamping sleeve and clamping part reduces the friction occurring during this clamping operation, so that it can be performed without great effort.

The lance tube must be sufficiently far, d. H. be inserted through the sealing sleeve into the lance holder. To ensure this, it is provided that a check valve is arranged between the sealing sleeve and a burn-back fuse, which has a stop which limits the insertion possibility noticeably. The lance tube, which is inserted as far as the stop, then releases the gas flow during clamping. With the insertion of the lance tube into the lance holder, the operation can therefore only be started when the lance tube has been inserted sufficiently far and thus an accurate sealing over the sealing sleeve can be achieved. At the same time the check valve is opened. Through the lance tube then the check valve remains open until the lance tube is removed or must be removed, in which case the valve is automatically moved by a spring back into the closed position.

To secure the entire lance holder is further provided that on the opposite side of the burn back protection over the gas flow to be opened check valve is provided. This ensures that the gas flow with the necessary pressure can get into the lance holder and is shut off automatically when the pressure drops too much. An accurate and safe operation of the lance holder is guaranteed.

To install the actual lance holder downstream parts separately or even to wait, the invention further provides that the burn-back fuse with the valves one with the protective housing solvable associated fuse housing is associated. Preferably, both housings are screwed together.

Earlier it has already been pointed out that the number of required sizes can be substantially reduced by the lance holder according to the invention. According to the invention it is provided that fixing part, clamping part and sealing sleeve pipe tolerances of 3-4 mm for metric and at the same time for inch tubes permitting group dimensions are formed having formed. This makes it possible, as mentioned earlier, to make do with a total of about seven holder sizes, while today more than 15 such holder sizes must be taken into account in order to allow a reasonably safe operation of the lance holder. The new lance tube fixation ensures ever more secure operation.

The invention is characterized in particular by the fact that a lance holder is provided which can be used both in metallurgical and in the steel industry, without an unnecessary risk to the operating crew by possibly wrong operation or handling of the lance holder or by unacceptable lance tube diameter occur can. On the one hand, the inserted lance tube is optimally fixed in the lance holder, at the same time ensuring that the lance tube is always pushed far enough into the lance holder during operation, namely until it stops. Upon reaching the stop or just before when clamping the inflow of the gas blocking check valve is opened and the gas can flow through the lance holder into the previously established in the lance holder and sealed lance tube. The necessary sealing of the lance tube is no longer carried out by a deformed in its longitudinal direction sealing sleeve, but rather by the fact that the sealing sleeve is pressed down on an approach wedge uniformly and safely to the respective lance tube. This gives the possibility to use sealing sleeves with a larger diameter than the outer diameter of the lance tubes. The targeted training of the clamping head with a right angle to the longitudinal axis displaceable Pressure elements in the form of balls ensures above all a punctual application of the load pressure and thus an optimal fixation of the lance tubes within the lance holder. This ensures that the lance tube can not rotate in the lance holder, wherein the lance tube is fixed by the clamping head and the sealing sleeve, but just by the clamping head so sure that any impairment of the fixation of the lance tube is excluded. Even with bent lance tubes secure mounting is given because always sufficient power can be applied by the point or line-shaped fixation of the lance tubes in the lance holder. By appropriate labeling can be made visible and easily recognizable for the operator team, for which pipe diameter the respective lance holder is provided. Thus, any hazards are safely avoided.

Figur 1

einen Lanzenhalter mit einem angeformten Drehventil in Seitenansicht,

Figur 2

einen Schnitt des Lanzenhalter mit eingespanntem Rohr mit 13,2 mm Durchmesser,

Figur 3

eine perspektivische Wiedergabe des in Figur 2 gezeigten Lanzenhalters,

Figur 4

einen Schnitt eines Lanzenhalters mit eingespanntem Rohr mit 17,5 mm Außenumfang und

Figur 5

einen Lanzenhalter im Schnitt im entspannten Zustand ohne Lanzenrohr.

Further details and advantages of the subject invention will become apparent from the following description of the accompanying drawings in which a preferred embodiment with the necessary details and individual parts is shown. Show it:

FIG. 1

a lance holder with a molded rotary valve in side view,

FIG. 2

a section of the lance holder with clamped tube 13.2 mm in diameter,

FIG. 3

a perspective view of the in FIG. 2 shown lance holder,

FIG. 4

a section of a lance holder with clamped tube with 17.5 mm outer circumference and

FIG. 5

a lance holder on average in the relaxed state without lance tube.

FIG. 1 shows a lance holder 1 in side view. From the front, a lance tube 2 is inserted into the clamping sleeve 25. The clamping sleeve 25 and the Clamping head 3 includes a fixing part 4, not shown here, and a clamping part 5. These interact with the sealing sleeve 6, which are accommodated together in the clamping head 3 designed as a protective housing 9. In the subsequent fuse housing 10, the required valves are housed, which will be discussed later. At this fuse housing 10, a rotary valve 11 is screwed, which has a manufacturer's advice 40.

The in FIG. 1 reproduced lance holder 1 is in FIG. 2 shown in section. Here it can be seen that the lance tube 2 is inserted far into the lance holder 1 through the clamping head 3. The already mentioned sealing sleeve 6 is pressed by a necking wedge 22 against the wall 18 of the lance tube 2 that a complete seal is made. The approach wedge 22 is pressed during actuation of the clamping head 3 and the clamping sleeve 25 between the outer wall 23 of the sealing sleeve 6 and the protective housing 9, so that the sealing sleeve 6 is deformed accordingly and applies to the wall 18.

While the opposite side 21 of the fixing part 4 is responsible for the deformation or for pressing the sealing sleeve 6 to the wall 18, the front side has a run-on slope 14, in which displaceable pressure elements 16 are arranged at right angles to the longitudinal axis 15 of the lance tube 2. These pressure elements 16 are influenced by the pressure bevel 17 of the clamping part 5, which is pushed onto the correspondingly formed run-on slope 14 when the clamping sleeve 25 or the clamping head 3 is rotated. The pressure elements 16 are formed as balls 20, which is made FIG. 2 and FIG. 3 shows, wherein the balls 20 are pressed directly onto the wall 18, so that a secure fixation of the lance tube is ensured. Distributed over the circumference 3 such balls 20, 20 'are provided, which are all uniformly and simultaneously influenced by the pressure ramp 17. In order to make this movement as uniform as possible, ie the displacement of the clamping part 5 via the clamping sleeve 25, is between the head wall 28 of the clamping part 5 and the clamping wall 29 of the clamping sleeve 25 and the clamping head 3 balls of a ball bearing 30 is arranged. As a result, the friction is minimized so that over the external thread 27 on the protective housing 9 and the internal thread 26 of the clamping sleeve 25, the necessary forces can be applied easily to a uniform and simultaneous sliding of the pressure ramp 17 to the pressure elements 16 and the balls 20 safely put.

With the insertion of the lance tube 2 in the lance holder 1, the arranged between the sealing sleeve 6 and the burn-back fuse 7 check valve 32 is opened. At this time, the outer wall 8 or 23 of the sealing sleeve 6 is not yet loaded by the approach wedge 22, so that the lance tube 2 can be easily inserted correspondingly far. As the stop 33 is reached, as described, the blocking valve 32 is displaced so far against the force of a spring that gas can now be introduced into the lance holder 1, although the fixing measures have yet to be carried out beforehand. Only then can the gas flow 34 be released, which opens the check valve 36 arranged on the opposite side 35 to the back-up protection 7. For this purpose, an opening and shut-off valve, not shown here, must be actuated in advance.

FIG. 3 shows the lance holder 1 with the lance tube 2 smallest diameter in working position, ie that check valve 36 can now be opened by the gas stream 34 to flow through the gas. The representation after FIG. 3 illustrates that the pressure elements 16 used as balls 20 are advantageously suitable to exert a punctiform pressure on the lance tube 2 and thus securely fix this.

FIG. 4 shows a lance holder 1 with an inserted lance tube 2 of the intended for this type lance holder largest possible diameter namely 17.5 mm. Compared to FIG. 2 It is clear that the special shape of the sealing sleeve 6 ensures that even with this essential larger diameter is still a safe seal. The approach wedge 22 is pushed accordingly far to achieve this, the balls 20 can already exert their fixing effect, although the pressure incline 17 acts only slightly on them. In the presentation after FIG. 2 However, it can be seen that the balls 20 have reached the safe position on the wall 18 only by a correspondingly wide displacement of the pressure ramp 17 of the clamping part 5.

Also in the in FIG. 4 shown position can now be opened by opening the gas path, the check valve 36 to allow the gas stream 34 to pass through the lance holder 1 and entry into the lance tube 2.

FIG. 5 Finally, there is a section of a lance holder 1 again, which is relaxed because a lance tube 2 is not yet inserted.

The check valve 32 is placed on the associated spring in the blocking position and the stop 33, which is influenced by the lance tube 2 to be inserted, is correspondingly pushed far back here. Up to this stop 33, the lance tube 2 is inserted through the insertion channel 37, and then the entire component is displaced such that the stop valve 32 opens.

In FIG. 5 It can be seen that the balls 20 are mounted in bores 38 in such a way that they are displaceable perpendicular to the longitudinal axis 15 of the lance tube 2. About this particular training an accurate fixation of the inserted lance tube 2 is possible and even if lance tubes with the diameter after FIG. 4 or FIG. 2 should be introduced. For differently deviating lance tubes trained lance holder must be used, as stated earlier on the advantage of it lance holder according to the invention is to be seen above all in that pipe tolerances of 3 - 4 mm are safe to handle. It is also advantageous that the oxygen or the gas can flow only when the lance tube 2 is inserted into the lance holder 1 up to the stop 33. The lance holder 1 has a total of a significantly reduced weight and a very compact design. The chuck 3 is hardened and can provide long service life. A further advantage is that the lance holder 1 can be easily assembled and disassembled and is therefore particularly well suited for use in the steelworks or in the metallurgical industry.

Claims (12)

Lance holder for lance tubes (2) used in metallurgical and steel industry with a clamping head (3) having a fixing part (4) and a clamping part (5) to which a lance tube (2) inserted by means of the fixing part (4) and thus sealing sealing sleeve (6) is assigned,
characterized,
that the inserted lance tube (2) comprising fixing part (4) with a run-on slope (14) is distributed in the distributed over the circumference at right angles to the longitudinal axis (15) of the lance tube (2) displaceable pressure elements (16) and guided over the one with the Starting ramp (14) corresponding pressure ramp (17) having clamping part (5) are arranged influenced and formed. Lance holder according to claim 1,
characterized,
that the printing elements (16) are all simultaneously and uniformly via the pressure ramp (17) against the wall (18) of the lance tube (2) are slidably formed and arranged. Lance holder according to claim 2,
characterized,
that the printing elements (16) comprises punctiform and / or linear loading pressure generating formed on the wall (18). Lance holder according to one of the preceding claims,
characterized,
that the printing elements (16) are designed as balls (20). Lance holder according to one of the preceding claims,
characterized,
that over the circumference uniformly distributed three balls (20, 20 ') as a pressure element (16) in the run-on slope (14) of the fixing part (4) are arranged. Lance holder according to one of the preceding claims,
characterized,
that the fixing part (4) (9) on the side opposite the run-on slope (14) side (21) an intermediate outer wall (23) of the sealing sleeve (6) and surrounding protective housing insertable approach wedge (22). Lance holder according to one of the preceding claims,
characterized,
in that the clamping part (5) of the clamping head (3) has a clamping sleeve (25) which is designed to be displaceable on the clamping part (5) and slidable on an external thread (27) of the protective housing (9). Lance holder according to claim 7,
characterized,
that between the head wall (28) of the clamping part (5) and the clamping wall (29) of the clamping sleeve (25), a ball bearing (30) is arranged. Lance holder according to one of the preceding claims,
characterized,
that between the sealing sleeve (6) and a burn back (7) a check valve (32) is arranged, which affects over the up to the stop (33) inserted lance tube (2) and open the gas flow (34) is made releasing. Lance holder according to one of the preceding claims,
characterized,
that on the opposite side (35) of the rear fire safety (7) via the gas stream (34) is provided to check valve opening (36). Lance holder according to one of the preceding claims,
characterized,
in that the burn-back fuse (7) with the valves (32, 36) is associated with a fuse housing (10) releasably connected to the protective housing (9). Lance holder according to one of the preceding claims,
characterized,
that fixing part (4), clamping part (5) and sealing sleeve (6) pipe tolerances of 3-4 mm for metric and at the same time for inch pipes permitting group dimensions are formed having formed.

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