FI98052B - Method and device for cleaning a gas or a liquid - Google Patents

Abstract

The invention relates to a method for cleaning of a gas or a liquid by means of an apparatus functioning by the so-called rod mill principle. The apparatus comprises a housing 10, a first rotor 11 arranged inside the housing and provided with collision surfaces, a second rotor 12 concentric with the first rotor and provided with collision surfaces adapted to rotate in an opposite direction relative to the first rotor, or a stator 13 concentric with the first rotor and provided with collision surfaces. The apparatus further comprises an opening 14 in the end wall of the housing and directed towards the centre of the rotors 11, 12 or the rotor 11 and the stator 13, as well as an opening 15 opening towards the mantle of the housing towards the outermost ring of the rotor or the stator, respectively. According to the invention, the collisions of the particles in the gas or liquid suspension flow against the collision surfaces are increased by rotating the rotor or the rotors in such a way that the outermost rotor ring or centrifuge ring moves in an opposite direction relative to the direction of the gas or liquid flow in the mantle opening 15 when said ring passes said mantle opening 15. The invention relates as well to an apparatus for working the method. <IMAGE>

Description

98052

METHOD AND APPARATUS FOR PURIFYING GAS OR LIQUID -FÖRFARANDE OCH ANORDNING FÖR RENING AV EN GAS ELLER VÄTSKA

The invention relates to a method for purifying a gas or a liquid. with a pin milling device. The invention relates to a device for cleaning a gas or a liquid, operating on the pin mill principle 5.

The cleaning of gases, such as flue gases and toxic exhaust gases, uses a wide variety of gaseous, liquid or solid additives to absorb, adsorb or chemically or otherwise react with the removable components present in the gases. Some additives react sensitively and rapidly with substances in the gas. Other additives require very close contact with the components in the gas before the desired reaction occurs, in which case microhomogeneity must be sought when mixing the additives and gases.

A pin mill is a device known per se, which is usually used for dispersing or mixing. The device comprises a cylindrical housing, a first rotor with abutment surfaces 20 or blades arranged in the housing, and a second rotor concentric with the first rotor, also with abutment surfaces, arranged to rotate in the opposite direction to the first rotor. Alternatively, the second rotor may be a stationary stator concentric with the first rotor and also provided with collision surfaces. According to a preferred embodiment, the rotors (or the rotor and the stator) are arranged on a vertical axis. The abutment surfaces of both rotors (or 30 rotors and stator) are arranged in concentric circumferences so that the circumferences of the first rotor and the circumferences of the second rotor (or stator) are interleaved. The end of the housing is provided with a material supply opening that opens into the center of the rotors 2 98052 (or the rotor and stator). A material outlet opening is made in the wall of the housing, which opens onto the circumference of the outer rotor or stator. The outermost rotor ring is also called a centrifuge ring. The centrifugal force caused by the rotation of the rotor 5 or rotors throws the material into the periphery of the housing. On the way to the periphery, the material is effectively dispersed / mixed due to collisions with the collision surfaces.

A pin mill type device is well placed to perform gas or liquid cleaning because the additive and gas or liquid are fed to the device in the correct proportions and this gas suspension at the inlet is divided by the rotor (or rotor and stator) collision surfaces (pins or blades) into ever decreasing gas or liquid parts where the ratio of additive to gas or liquid remains correct at all times.

Previously, for example, the Finnish patent FI 88879 proposed the purification of gases e.m. in a pin mill-20 device. In this case, the device is fitted to the flue gas duct so that the flue gas flows through the device. At the same time, lime particles are fed into the device, to which the grinding effect of the device creates a clean reactive surface, "in statu nascendi".

25 Reactive lime and sulfur dioxide in the flue gases will thus react effectively with each other in the flue gas stream.

A prerequisite for the success of the gas cleaning method described above is that the surface of the lime particles has time to grind clean as the lime flows through the mill and that the flue gases come into effective contact with these particles with a clean surface. In some cases, it would be advantageous to be able to extend the residence time of the gas suspension in the mill. Of course, the residence time is longer in the larger 35 devices, but it is not always possible to increase the 3 98052 devices due to lack of space or cost.

In gas or liquid purification, solid or liquid particles can be removed by combining, "squeezing together," these small particles into larger S agglomerates that can be removed from the gas by mechanical means. No medium may be needed here. In the purification of gases, for example, water or another liquid can be used as the medium, which helps the particles to adhere to each other. A prerequisite for the success of the 10 "cursing" is that as many small particles as possible are made to collide with each other. Solids such as activated carbon can also be used to purify gases of gaseous impurities.

15 The pin mill provides very efficient mixing and the collision of small particles with each other.

However, depending on the amount of gas or liquid and the number of particles and the number of impingement surfaces of the device, it may sometimes be desirable to be able to increase the residence time of the gas or liquid suspension in the device so that all particles agglomerate or come into contact with each other.

It is therefore an object of the present invention to provide an improved method and apparatus for purifying gases or liquids by the pin mill principle. In particular, it is an object to provide a method and apparatus for maximizing collisions between different components of a gas or liquid suspension in order to achieve the desired effects.

In order to achieve the above objects, the method and the device according to the invention are characterized by what is defined in the characterizing part of the independent claims set out below.

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4,98052

The invention will be described in more detail below with reference to the accompanying drawings, in which

Figure 1 shows in vertical section a pin mill used in the method according to the invention, in which the gas or liquid to be cleaned is passed through the device in a conventional direction

Fig. 2 shows a pin mill of Fig. 1 in which the gas or liquid to be cleaned is passed in the opposite direction through the device. Fig. 3 shows a second embodiment of the device of Fig. 1. Fig. 4 shows the device of Fig. 1 in a horizontal section.

Fig. 5 shows the device of Fig. 2 in a horizontal section

Fig. 6 shows the device of Fig. 1 connected to a fan

Fig. 7 shows the device of Fig. 2 connected to a fan 15. Fig. 8 shows the device of Fig. 1 with the preferred dimensions marked

Fig. 9 shows the device of Fig. 4 according to a second embodiment, and

Fig. 10 shows the device of Fig. 5 according to a second embodiment 20.

Figure 1 shows a vertical section of a pin mill used in the method according to the invention, comprising a housing 10 in which a rotor 11 is provided, which is provided with abutment surfaces 1a, Ib ..., 3a, 3b ... etc. (the individual abutment surfaces are shown in more detail e.g. and 5). In the solution of Figure 1, the upper cover of the housing 10 forms a stationary stator 13 concentric with the rotor 11 and also provided with abutment surfaces 2a, 2b ..., 4a, 4b ... etc. The abutment surfaces 1a, Ib .. ., 2a, 2b ..., 3a, 3b ... are arranged in concentric circumferences 1, 2, 3 ... so that the circumferences 1, 3, 5 ... of the rotor 11 and the circumferences 2, 4, 6 of the stator. .. are interlaced. In this case, the stator 13 with its collision surfaces allows the rotor 11 to rotate about its vertical axis 35. At the end of the housing there is an opening 14 opening in the center of the rotor 11 and the stator 13, which can act as a supply or discharge opening for the gas or liquid to be cleaned. An opening 15 is provided in the wall of the housing for opening to the outermost collision surface, which alternatively acts as an inlet or outlet for the gas or liquid to be cleaned. Figure 3 shows an alternative pin mill structure 5, in which the stator 13 of Figure 1 has been replaced by a second rotor 12 concentric with the first rotor 11. The second rotor 12 is also not provided with abutment surfaces 2a, 2b ..., 4a, 4b ... etc. The abutment surfaces 1a, Ib ..., 2a, 2b ..., 3a, 3b .. of the first rotor 11 and the second rotor 12 is arranged in concentric circles 1, 2, 3 ... so that the circumferences 1, 3, 5 of the first rotor 11 and the circumferences 2, 4 of the second rotor 12 are arranged interleaved. In this case, the rotors 11 and 12 with their collision surfaces can rotate freely in different directions.

cleaned solution, 15 of Figure 1, a gas or a liquid together with any additives are fed in the direction of the arrow in the central opening 14 and out of circumferential slot 15. Figure 4, which shows the device of Figure 1 the horizontal section, seen in the behavior of the device according to the invention. Collisions of particles of gas or. * · * 20 liquid suspension stream with the impact surfaces of the device * · .. are increased by rotating the rotor 11 ·; · (or rotors 11 and 12) in the direction of the arrows so that the outer * · ·. ·. rotor ring or centrifugal ring 7 when passing the circumferential opening 15 * · • · ·. moves in the opposite direction to the direction of gas or liquid flow prevailing in the circumferential opening 15. This • · • · * driving mode significantly increases the collisions of gas or liquid suspension particles flowing through the device with the impact surfaces of the device compared to the conventional driving mode in which the rotor (s) are driven in the opposite direction »·;. ·; 30 direction so that the outer rotor ring or centrifugal ring »·»:: * passes the circumferential opening in the same direction as the material flowing in the circumferential opening. Increased flow resistance naturally requires higher fan or pump power • ·. . than in the conventional mode of operation of the device, but correspondingly 35 also provides a considerably better cleaning result.

The device can also be driven according to Fig. 2 so that the surface area A2 of the casing formed by the height h of the collision surfaces 1a, 1b, ... located 78052.

It will be apparent to those skilled in the art that the various embodiments of the invention may vary within the scope of the 5 claims below.

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Claims (12)

1. A process for the purification of a gas or liquid with an apparatus operating in accordance with the so-called pin mill principle - a housing (10) 5. one provided in the housing with collision surfaces (1a, 1b ... 3a, 3b ...) first rotor (11), - arranged in the housing - with the first rotor concentric, with collision surfaces (2a, 2b ... 4a, 4b ...) provided with second rotor (12) arranged to rotate in the opposite direction compared with the first rotor, or - with the first rotor concentric, with collision surfaces (2a, 2b ... 4a, 4b ...) provided with stator (13), the collision surfaces (1a, 1b ..., 2a, 2b). .., 3a, 3b ...) are arranged in concentric rings (1, 2, 3 ...) such that the rings of the first rotor (11) (1, 3, 5 ...) and the second rotor or the stator rings (2, 4, 6 ...) are placed between each other, - an opening (14) which opens against the end of the housing against the rotors (11, 12) or the rotor (11) and the stator (13) · Center, and *. - an opening (15) which opens against the casing of the housing against the ring of the outer rotor or stator, and there. " apparatus and caused to flow as gas or liquid suspension current via the collision surfaces arranged within one another or the interior of the rotor and stator arranged as collision surfaces: particles with the collision surfaces of the apparatus by rotating the rotor or rotors such that the outermost rotor ring or pivot ring (7), where it is in alignment with the ...... .......- m., 98052 passing past the ring opening (15) moves in the opposite direction compared to the direction of the gas residing in the ring opening (15) or vätskeströirmien. 2. A method according to claim 1, characterized in that the disc-shaped collision surfaces of the outer rotor or stator ring are rotated about their vertical axis so as to provide the greatest possible flow resistance for the gas or liquid flow in the ring opening. Method according to claim 1 or 2, characterized in that the number of rotors (11, 12) or rotor (11) and stator (13) is increased. 4. A method according to claim 1, 2 or 3, characterized in that the holding time of the gas or liquid stream is extended in the apparatus by increasing the volume of the casing in relation to a certain gas or liquid flow. 5. A process according to any one of claims 1-4, characterized in that the gas or liquid to be purified and the additive possibly used in the gas or liquid purification are introduced into the apparatus via • j * 20. the center opening (14) and out through the ring opening (15). • · • · · • · · · · · ·: 6. Process according to any one of claims 1-4, characterized in that the gas or liquid to be purified and the additive, which may be used in the gas or liquid purification, are introduced into the apparatus via the ring opening. (15) and out through the center opening (14). 7. A process according to claim 6, characterized in that the · gas or liquid to be purified and the additive, which may be used * in the gas or liquid purification,] ···. is started in the apparatus that is turned so that the center opening • · T. 30 (14) opens downwards. * • · · · · · ··· Process according to any one of the preceding claims 98052, characterized in that the gas to be purified contains solid and / or gaseous impurities and that the additive is a liquid, liquid solution, solid, gas or mixture thereof. Method according to any of the previous claims, characterized in that the gas to be purified is transported through the apparatus with a fan (30) mounted after the outlet opening for the gas stream. A device suitable for purifying a gas or liquid, according to the principle of the pin milling principle, comprising - a housing (10) - a first rotor (11) provided in the housing with collision surfaces (1a, 1b, 3b ...). ) - a housing arranged in the housing 15 with the first rotor concentric, with collision surfaces (2a, 2b ... 4a, 4b ...) provided with second rotor (12) arranged to rotate in the opposite direction compared to the first the rotor, or - with the first rotor concentric, with collision surfaces. · 1 (2a, 2b ... 4a, 4b ...) provided with stator (13), the collision surfaces (1a, 1b ..., 2a, 2b) ..., 3a, 3b ...) are arranged in concentric rings (1, 2, 3 ...) so that the rings of the first rotor (11) (1, 3, 5 ...) and the other • · .·. the rings of the rotor or stator (2, 4, 6 ...) are placed between each other, • 9 m · - an opening (14) which opens against the end of the housing towards the rotors (11, 12) or the rotor. (11) and the center of the stator (13), and - an opening (15) which opens against the casing of the housing against the outer ring of the outer rotor or stator, characterized in that: 1 1 the outermost rotor ring or hose ring (7) as it passes through the ring opening (15) in the opposite direction «« ·· Γ. direction towards the direction of the gas or liquid stream rescuing in the ring opening (15). 98052 11. Apparatus as claimed in claim 10, characterized in that the disc-shaped collision surfaces of the outer rotor or stator ring are rotated about their vertical axis, so as to provide the greatest possible flow resistance to the gas or liquid flow stream in the ring opening. 12. Apparatus according to claim 10 or 11, characterized in that the surface (AI) of the center opening is smaller than the surface (A2), which is the sheath formed by the inner circumference (20) of the inner ring (1) of collision surfaces and the height. (h) at the collision surfaces located therein (1a, 1b, ...). ·· ♦ · «·· • · * 1 2 3« 1 ·· # • 1 ·· • · • · • · · »·· · • - • ·« Φ • «· · • · • · • · ♦ «• · • 1 ···» • ♦% · • «2 • · · ♦ · • · ·% 1 • · 3