EP0913188A2 - Double boiler with impeller for the production of a gaseous mixture - Google Patents

Abstract

A gas mixing vessel basically consists of two superimposed tanks with a rotating paddle wheel in the upper section. The dual tank is assembled from a number of components; (b) the basic upper tank section (1) has a flat surface (3) which is closed by an overhead cover plate (2) and seal; (c) a paddle wheel (14) rotates horizontally within the upper tank section (1) turned by a motor (21); (d) the motor (21) is linked to the paddle wheel (14) by a drive shaft (17); (e) the drive shaft (17) ends in the overhead cover plate (2) where it rests in a bearing, and has an intermediate bearing in the lower cover plate (11); (f) the lower cover plate (11) is secured to the lower part (6) of the dual tank by sealing surfaces (10,12); (g) different gases are introduced to the gas vessels via inlets (13) drilled in the lower cover plate (11); (g) the incoming gases enter the lower tank together with a carrier gas at increased pressure, and rise through a constriction (15) and inwards-directed passage (9) towards the rotating paddle wheel (14); (h) the gases are mixed by the paddle wheel and migrate into the free space (16) above the wheel; (i) mixed gases are discharged through outlets (18) in the upper plate (2).

Description

The invention relates to a double boiler with an impeller, in which a gas mixture consisting of different chemically pure gases is generated, the basic chemical characteristics of the individual gases are retained.

Gases or gas mixtures are used in the various branches of industry.
The focus is less on gas mixtures than on gases in their basic chemical structure.
Due to extensive research, gas mixtures were of no importance, especially for gases that are harmful to health and have a dangerous impact on the environment.

In the aluminum industry, especially in the aluminum alloy smelting plant, chlorine and fluorine gases - also salts - used to be used for cleaning aluminum alloy melts in order to free the melts from aluminum oxides (Al ₂ O ₃ ).
These gases are also used to a very small extent. But then neutralization systems are required.

die Dauerstoffatome von Al₂O₃ werden von Chlor-bzw.Fluorgasen abgespalten und chemisch an Chlor - bzw. Fluor gebunden.

Es bilden sich durch das chemisch zerstörte Al₂O₃ dann 2( Cl₂O) und 2(F₂O).

Die Aluminium-Legierungsschmelze ist praktisch dann oxidfrei.The contamination of the aluminum alloy melt by Al ₂ O ₃ is split into the melt by blowing chlorine gas or fluorine gas or both;

the permanent atoms of Al ₂ O ₃ are split off from chlorine or fluorine gases and chemically bound to chlorine or fluorine.

The chemically destroyed Al ₂ O ₃ then forms 2 (Cl ₂ O) and 2 (F ₂ O).

The aluminum alloy melt is practically then oxide-free.

The big disadvantage of this absolute and safe cleaning is, however, that the Al ₂ O ₃ content in the aluminum alloy melt cannot be determined by calculation. The proportion is and will always remain unknown.
Inevitably, more chlorine or fluorine gas is blown into the melt, which ultimately means that excess harmful gas escapes from the melt surface and then exerts the harmful influences.
Appropriate neutralization systems can of course neutralize the harmful gases.
For cost reasons, however, gas purification is avoided.

Cleaning salts are used for this, but they cannot split the chemical compound Al ₂ O ₃ if these cleaning salts have no chlorine or fluorine salt compounds. The cleaning salts used, mainly rock salt, do not deserve their name as cleaning salts for the removal of Al ₂ O ₃ .

The use of normal cleaning salts indicates that the processors certainly do not have any metallurgical knowledge.
You live with the higher proportion of scrap because you don't know it better.

The object of the invention is in cleaning effective Chlorine or fluorine gas on the excess gas a minimum measure to reduce the the necessary neutralization of the harmful remaining Keep residual gases to a minimum.

In the characterizing part of claim 1 and the characterizing parts of the subclaims, the solution to the problem is indicated, but the invention is not limited to this
The invention is illustrated in exemplary embodiments with reference to drawings, to which the invention is not restricted. It is possible and quite conceivable that circumstances arise from the claims, the description and the explanations for the drawings that can be inventive in themselves or in various combinations.

Fig.1

eine Aufsichtszeichnung des zusammengebauten Doppelkessels mit Flügelrad,

Fig.2

eine Querschnittszeichnung gemäss Schnitt A-A (Fig.1),

Fig.3

eine Aufsichtszeichnung des oberen Kessels als Einzelteil,

Fig.4

eine Querschnittszeichnung gemäss Schnitt B-B (Fig.3),

Fig.5

eine Aufsichtszeichnung des unteren Kessels als Einzelteil,

Fig.6

eine Querschnittszeichnung gemäss Schnitt C-C (Fig.5),

Fig.7

eine Aufsichtszeichnung der Abdeckplatte des oberen Kessels,

Fig.8

eine Querschnittszeichnung gemäss Schnitt D-D (Fig.7),

Fig.9

eine Aufsichtszeichnung der Abdeckplatte des unteren Kessels,

Fig.10

eine Querschnittszeichnugn gemäss Schnitt E-E (Fig.9),

Fig.11

eine Aufsichtszeichnung des Flügelrads,

Fig.12

eine Querschnittszeichnung gemäss Schnitt F-F (Fig.11).

First show:

Fig. 1

a supervision drawing of the assembled double boiler with impeller,

Fig. 2

a cross-sectional drawing according to section AA (Fig.1),

Fig. 3

a top drawing of the upper boiler as a single part,

Fig. 4

a cross-sectional drawing according to section BB (Fig.3),

Fig. 5

a top drawing of the lower boiler as a single part,

Fig. 6

a cross-sectional drawing according to section CC (Fig.5),

Fig. 7

a top drawing of the cover plate of the upper boiler,

Fig. 8

a cross-sectional drawing according to section DD (Fig.7),

Fig. 9

a top drawing of the cover plate of the lower boiler,

Fig. 10

a cross-sectional drawing according to section EE (Fig. 9),

Fig. 11

a top view drawing of the impeller,

Fig. 12

a cross-sectional drawing according to section FF (Fig.11).

The double boiler with impeller is made up of several components for manufacturing reasons. For reasons of accuracy and low warpage, castings, preferably made of gray cast iron, are recommended. Because the mechanical reworking is as low as possible, the individual parts are designed to be suitable for demoulding.
Figure 2 shows the overall cross-sectional drawing quite clearly the idea of the invention and the assembled components, which then form the double boiler with impeller.

The assembly parts are drawn as individual parts by Fig. 3 to Fig. 12. shown.

The upper double boiler base body 1 (Fig. 2,4) shows clearly the mold conicity required consistently in terms of shape the relatively long formed as a circle Exterior walls.

The upper double boiler base body 1 (Fig. 2,4) becomes a half boiler through the upper screwable cover plate 2 (Fig. 2,7,8).
The sealing surfaces 3, 4, 7 (Fig. 2) are machined and are sealed by the interposition of a sealing ring after tightening the fastening screws.
The through bores 5 (FIG. 1, 2, 3, 4, 7, 8) are provided for these fastening screws and are to be mechanically attached.

In addition to the sealing surface 8 to be machined (FIGS. 2, 3, 4), the lower double body shell 6 (FIGS. 2, 5, 6) has an inwardly bent cranked zone 9 (FIGS. 2, 5, 6).
In the lower double boiler body 6 (Fig. 2,5,6,), the sealing surfaces 8,10 (Fig. 2,5,6) are machined accordingly.
The lower double boiler base body 6 (FIGS. 2, 5, 6) is tightly closed by the lower cover plate 12 (FIGS. 2, 9, 10), the sealing surface 12 (FIGS. 2, 9, 10) likewise being machined.

Different flow through the bores 13 (Fig. 2,9,10) chemically pure gases such as chlorine, fluorine and nitrogen as carrier gas in the lower double boiler body 6 (Fig. 2,5,6) under a freely selectable one Pressure and quantity, then through the narrowed opening 15 (Fig. 2,5,6) on the impeller 14 (Fig. 2,11,12) in the upper free space 16 (Fig.2) of the upper double boiler body 1 (Fig. 2).

The impeller 14 (Fig. 2, 11, 12) is in constant rotation during the operation of a crucible or a casting system.
The gas inlet bores 13 (Fig. 2,9,10) of the lower cover plate 11 (Fig. 2,9,10) are provided with passage pressure valves, whereby the inflowing gases can be regulated in terms of pressure and quantity.

The gau outlet bores (18) of the upper cover plate also point 2 (Fig. 2,7,8) pressure regulating valves on, through which is the escaping gas that is used to purify the melt is determined to be regulated in every respect.

The assembled double boiler is fixed on a base, for example an angle iron construction.
The drive motor (21) (FIG. 2) intended for the impeller is also mounted on this underframe 19 (FIG. 2). The whole unit is attached to the floor 20 (Fi.2).

The gases flowing onto the rotating impeller become vigorously mixed and kicked by the rotation of the impeller then as a gas mixture through the gas outlet bores 18 upper cover plate.

In order to reduce the excess, but defective, but cleaning gases chlorine - fluorine gases to a minimum, but sufficient, about 80% nitrogen gas is blown in as carrier gas.
Due to the vigorous mixing of the gases via the impeller, a mixed gas can be continuously blown into the melt near the bottom of the crucible.
Most of the mixed gas - nitrogen gas emerges from the surface without causing any harmful effects.
The non-chemically consumed gases chlorine and fluorine gas also escape at the melt surface, but to an extent that can be disposed of relatively easily.

There are collecting screens above the melting and holding furnaces attached over which then all the escaped gas a disposal facility arrives.

Reference symbol overview

1

upper double boiler body

2nd

upper screwable cover plate

3rd

Sealing surface

4th

Sealing surface

5

Through holes

6

lower double boiler body

7

lower sealing surface of the upper double boiler body

8th

Sealing surface of the lower double body

9

cranked inner edge zone

10th

Sealing surface of the lower double body

11

lower cover plate

12th

Sealing surface of the lower cover plate

13

Inlet holes in the lower cover plate

14

Impeller

14a

Center vane hub

14b

wing

15

Narrow opening

16

free space

17th

drive shaft

18th

Outlet holes in the top cover plate

19th

Underframe

20th

ground

21

Drive motor

Claims (9)

Double boiler with impeller for generating a gas mixture in which gases are mixed with one another, characterized in that that the double boiler is composed of several components, the upper double boiler base body (1) has a machined surface (3) and is sealed by an upper screwable cover plate (2) with the interposition of a sealing ring by screwing in the upper part, an impeller (14), driven by the drive motor (21), rotates in the upper double boiler base body (1), the connection between the drive motor (21) and the impeller (14) takes place through the drive shaft (17), the drive shaft (17) ends in the upper cover plate (2) and is also stored accordingly, only temporarily stored in the lower cover plate (11) is
the lower cover plate (11) being firmly connected to the lower double boiler base body (6) via the sealing surfaces (10) and (12), Gases of various basic chemical structures flow in under pressure through the inlet bores (13) and valves in the lower cover plate (11), the gases which have flowed in, together with a carrier gas, ascend under pressure over a narrowed diameter (15) through an inwardly bent edge zone (9) into the region of the rotating impeller (14), are mixed by the rotating impeller (14) and reach the free space (16) above the impeller, From there, emerge from the double boiler via the outlet bores (18) of the upper cover plate (2) and are fed to a crucible, melting furnace, holding furnace with crucible, a casting furnace or a casting system. Double boiler according to claim 1
characterized, that the boiler walls (1), (6) are manufactured both in rectangular and mainly in round shape, preferably as castings, with gray cast iron being preferred because of low warpage. Impeller according to claim 1,
characterized, that the wing center hub (14a) is manufactured as an individual part and vertical or inclined longitudinal tapered grooves are milled into the outer diameter to the axis of rotation, into which the wing parts (14b) are firmly inserted. Impeller according to claims 1 and 3
characterized, that the wing center hub (14a) and the wing parts (14b) are made of thermoplastic, preferably polyacetal. Double boiler with impeller according to claims 1 and 6
characterized, that the upper and lower boiler (1) and (6) and the cover plates (2) and (11) are pressed together in a sealing manner by means of a number of one-piece, relatively long threaded screws via bores (5). Double boiler with impeller according to claim 1
characterized, that the gases flowing in through the bores (13) of the lower cover plate (11) under adjustable pressure and quantity from the chemically pure nitrogen gas as carrier gas and the gases cleaning the aluminum melt of Al ₂ O ₃ - chemically pure chlorine gas and chemically pure fluorine gas or nitrogen gas and Chlorine gas can flow in alone as a gas mixture. Double boiler with impeller according to claim 1
characterized, that the entire unit can be manufactured as a welded construction. Double boiler with impeller according to claim 1
characterized, that the assembled components are attached to a base (19) connected to the base (20). Double boiler with impeller according to claims 1 and 6
marked by that the gas mixture introduced into the respective aluminum alloy for cleaning Al ₂ O ₃ emerges at the bottom of the crucible in question and then rises.

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