SE463543B - gas cleaning - Google Patents

Description

10 15 20 25 N 465 543 2 the radial gas flow direction changes abruptly to one axial gas flow direction, the gas flow being fed into the gas the discharge channel, while the dust particles under the influence of inertial forces, which are higher than the gas dynamic forces thereby retaining the particles in the gas flow, maintaining their radial direction of movement so that they move past the gas discharge duct and is removed together with part of the gas flow from the housing of the gas purifier through the channel for discharge of pollutants.

The known gas purification device so designed provides low gas purity. capacity due to the fact that gas supply and discharge the cross-sectional area of the ducts is relatively small, namely because it must be considerably smaller than the surface of the disc so that the dust particles can be separated from the gas with using centrifugal forces. In this known gas purification device in addition, the flow direction of the gas flow changes abruptly two times, resulting in gas flow energy losses and further reduces the capacity of this known gas purifier.

It's known. that the degree to which the gas can purify gases from dust particles. is dependent those of the energy level of the movement in the radial direction, which the dust particles get in it next to the surface of the rotating disk horizontal boundary layer of gas. The higher this kinetic energy of the dust particles are, the higher the degree of gas purification. In turn the energy level of the motion of the particles in the radial direction is determined the final velocity obtained by the particles at the limit the layer of gas under the influence of the centrifugal forces. Particulate the final velocity of the lars becomes higher, the longer the distance traveled is over which the particles get their acceleration, which with in other words, the longer this distance is, the more the higher the degree of gas purification.

The above-described known gas purification device gives a low degree for the purification of gases from dust particles, since the distance over which the dust particles are assigned acceleration í 10 15 20 25 30 35 3 465 543 radial direction is limited by the radius of the disc. In addition, touch off the low gas purification rate of this known gas purifier that a zone of increased pressure (high pressure zone) is formed at the disc surface, partly because the rotor of this known gas purification device is designed in the manner described above, partly by the flow channels (gas supply and gas discharge channels- na) are arranged in the manner described above and partly by that the flow of the gas being purified is slowed down in these channels due to the insufficient cross-sectional area of the ducts large. This high pressure zone helps to generate one considerable resistance to the penetration of dust particles into the area of the boundary layer adjacent to the surface of the rotating disk gas, which penetration resistance is particularly high for fine and light dust particles, which have a low kinetic energy such as determined by the mass of the particle and the gas flow rate in the gas supply channel. Large and heavy particles therefore penetrate mainly into the area of the boundary layer of gas and separated from the gas. Fine and light dust particles thereby obtain do not receive - by turning them together with the gas flow in the zone of increased pressure at a considerable distance from the surface of the disc the necessary acceleration in the radial direction and is entered - without separating them from the gas - in the gas supply duct.

In addition, the so-called known gas purification device requires that gas is forcibly fed into the gas inlet duct by the pressure supply means, whereby the construction of the device becomes more complicated and its outer dimensions increase.

The main object of the present invention is to provide a gas purification device in which the rotor and gas flow the constructive design of the ducts and the gas flow the cross-sectional area of the ducts is so selected that the capacity of the device and gas purification rate increases.

This object is achieved according to the present invention by means of a gas purification device, the housing of which contains a rotor comprising takes a shaft with a disc attached thereto, and is provided with gas supply and gas discharge channels and a discharge channel 10 15 20 25 30 35 463 545 4 of pollutants, the gas purification device according to the present invention The present invention is characterized in that at least one further identical disk is attached to the shaft of the rotor in such a way that a gap is formed between this disc and each adjacent one plate, and the housing contains a gas flow direction partition wall, the gas supply and discharge The ducts are designed between the respective wall of the house and the partition wall and arranged tangentially to the discs, while the channel for discharging pollutants is formed in the gas discharge channel along the entire length of the rotor.

The constructive design of the present invention The proposed gas purification device contributes to provide such a gas flow pattern as to enable partly to feed gas into the device tangentially in relation to landing to the boards, partly to evenly reverse the gas flow in the house and partly to discharge the gas tangentially in relation to the discs. In this case, the gas supply and gas discharge the cross-sectional area of the disc diameters and the axial lay the length of the rotor with several discs. This allows you to a predetermined disc diameter increase the transverse flow of the gas flow channels. section area by increasing the axial length of the rotor, which leads to an increase in the capacity of the gas purifier. By the gas flow direction in the device according to the present invention finding changes steplessly and evenly minimizes energy the losses of the moving gas flow, which increases gas purification capacity further.

The gas flow preset according to the present invention the pattern, which makes it possible to feed and discharge the gas gential in relation to the discs and to turn evenly the gas flow in the gas purifier housing, contributes to the energy is transferred to the dust particles over that section of the trajectory (the section), which is determined on average by half the length of the circumference of the discs, whereby the gas purification the degree increases. 10 15 20 25 30 35 5 46-3 545 In addition, the constructive, according to the present invention proposed design of the gas purifier, to ensure that the articles penetrate unhindered in the areas of the adjacent our surfaces lying boundary layers of gas, because the rotor with several discs act as a working member of a fan, lasting nom in the gaps between the discs of the rotating rotor and a reduced (low) pressure is set in the gas supply duct, which causes the gas to be purified to be sucked into the gas purification device.

This results in all the dust particles being independent of theirs size and mass are allocated to the energy required to the dust particles must be able to be separated from the gas, which also increases the degree of gas purification of the gas purification device.

Nor does the present invention require the gas purification device that the gas is forcibly fed into the gas supply channel by means of a pressure supply means, why the construction of the gas purification device is simplified and its dimensions are reduced, as the multi-disc rotor acts as a work organ in a fan.

It is suitable that the shaft and discs of the gas cleaning device are made of materials with high thermal conductivity and that the rotor shaft is connected to a means for performing one heat exchange process.

Such a constructive design of the gas purification device rotor contributes to the rotor being able to function as a working means in a fan and as a heat exchanger. This gives the gas purifier a The present invention provides a more comprehensive application advice, namely that, for example, by cooling the rotor with help of the means for carrying out heat exchange can sound water vapor condenses at the surfaces of the disks and by centrifugation galveran divert the condensed liquid to the channel for discharge of pollutants. At the same time, the gas is purified from gas miga, soluble impurities in the condensed liquid. One such a constructive design of the gas purification device according to The present invention makes it possible, on the one hand, to effectively 10 15 20 W 463 543 clean gases from atomized inclusions, and to conduct heat exchange. namely to use the gas purification device both as a fan and as a heat exchanger, and partly to dry gases and purify them from soluble gaseous purifications by means of a device of simple construction which is easy to produce.

It is further suitable that the shaft of the gas purifier rotor is hollow and that the ends of the shaft are provided with radial holes for the passage of a heat transfer medium. while the means for carrying out the heat exchange process consists of an impeller mounted on one end of the shaft for pumping heat the means of transmission through the cavity of the shaft.

Such an embodiment of the gas purification device according to the present invention The present invention makes it possible to - when heat transfer means of, for example, atmospheric air - pump heat the means of transmission through the cavity of the shaft by means of it to a centrifugal fan belonging to the running wheel mounted on one end of the shaft without the need for a special drive motor. Hereby will be the heat exchange as well as the gas drying and purification of gases from soluble gaseous pollutants more efficiently, at the same time which the body for carrying out the heat exchange gets easier construction.

It is also advisable to have one connected to a thermoregulator throttle valve for regulating the amount of heat transfer supplied means is arranged around the end of the shaft which is set the end which supports the impeller for pumping heat transfer the guide means through the shaft cavity. wherein the throttle valve is brought opposite the radial holes.

Such a constructive design of the gas purification device The present invention makes it possible, if the means of transmission consists of, for example, atmospheric air, whose temperature changes irregularly with time - maintaining the temperature the gas purified gas, within predetermined limits and 10 15 20 25 30 35 40 7,463,545 at the same time automatically reducing the amount of heat transfer when the temperature of the heat transfer medium drops. or increase the amount of heat transfer agent added when its temperature temperature increases. In addition, in this case you can change the heat growth conditions in accordance with a predetermined program.

In yet another possible embodiment of the gas purification device according to In the present invention, the channel for discharging contaminants consist of at least one row of holes included in the wall of the house.

Such a constructive design of the device according to the present invention the present invention helps to reduce the pollutants separated by centrifugal action can be removed from the gas outlet channel along the entire length of the rotor.

In yet another embodiment of the gas purification device according to the present invention, the channel is for abduction of pollutants of at least one slit-shaped, in the wall of the house taken holes.

Such a constructive design of the gas purification device The present invention contributes to better output conditions. for the pollutants to be separated, by the channel for discharging pollutants is continuous along the entire rotor length.

It is advisable to enter the gas discharge duct, after the duct for discharging pollutants seen in the direction of gas flow, arranges a diverter plate, which slopes towards the gas discharge duct the center line of the system and extends along the entire gas discharge channel length.

This results in a higher degree of gas purification by diverting The separating plate partly separates the part of the gas flow which has the maximum concentration of pollutants including fine and light particles which - due to the fact that they have an clear mass - does not have time to be brought closer to the wall of the house, and on the one hand, the gas flow is directed towards the channel for discharging pollutants. nings. 10 15 20 463 545 8 In yet another embodiment of the gas purifier according to the present invention According to the present invention, the channel for discharging pollutants be formed between the wall of the housing and an additional gas outlet. partition wall.

The so-called channel for discharging pollutants contributes that this embodiment of the gas purification device according to the present invention has simpler construction compared to the embodiments of the device, where the channels for discharge of contaminants consists of at least one row of holes (or one column). which are housed in the wall of the house and lean towards the gas the center line of the feed channel.

In addition, such a constructive design of gas to a higher degree of gas purification by in this embodiment can separate and remove that part of the gas the flow showing the maximum concentration of pollutants, including fine and light particles.

It is furthermore suitable that the side surfaces of the discs in the gas purifier pure according to the present invention are corrugated.

Such a constructive design of the discs makes it possible to increase the gas purification capacity by the rotor in this case exhibits better aerodynamic properties.

The invention is described in more detail below with reference to attached drawings. in which Fig. 1 schematically shows a cross-section section through an embodiment of the gas purification device according to present invention, Fig. 2 shows a section along the line II-II in Fig. 1, Fig. 3 shows a partially sectioned, in direction for the arrow A in Fig. 1 taken view of an embodiment of the channel for discharging contaminants, Fig. 4 shows another embodiment form of the channel for discharging pollutants analogous to what as shown in Fig. 3. Fig. 5 schematically shows a cross section by a second embodiment of the gas purification device according to present invention, Fig. 6 shows a cross section through a 10 15 20 25 30 35 9 465 545 third embodiment of the gas purification device according to the present invention gande invention, fig. 7 shows a section along the line VII-VII in Fig. 6. fig. 8 shows a section along the line VIII-VIII in fig. 7 and fig. 9 in a partially extended form shows an annular transverse section along the line IX-IX in fig. l.

The gas purification device proposed according to the present invention the housing comprises a housing 1 (fig. 1) containing a rotor 2, which is provided with a shaft 3 and discs 4 attached to the shaft 3 (Fig. 2), which are so arranged that a gap is left between the discs 4. The housing 1 is provided with a gas supply duct 5 (Fig. 1), a gas discharge duct 6 and a duct 7 for discharge of pollutants. Channels 5 and 6 are formed between the housing 1 respectively walls and a partition wall 8, which is arranged in the housing 1 along the gas flow direction. Channels 5 and 6 are arranged tangential to the discs 4, while the channel 7 for the discharge of pollutants are contained in the gas discharge len 6 and extends along the entire length of the rotor 2.

The shaft 3 of the rotor 2 is mounted in the housing 1 by means of bearing 9 (fig. 2) and is connected by means of a coupling 10 to an electric motor 11, which is attached to the housing 1 by means of a conical sleeve 12.

The channel 7 for discharging pollutants can consist of two rows of holes 13 accommodated in the wall of the housing 1 (Fig. 3).

The channel 7 for discharging pollutants can also consist of a slit-shaped. opening 14 in the wall of the house (fig. 4).

The gas discharge duct 6 contains a diverter plate 15, which is arranged after the channel 7 for discharging pollutants, seen in the gas flow direction shown by the arrow B in Fig. 1 and is inclined towards the center line of the gas discharge duct 6 01-01 with an angle d, the diverter plate 15 extends along the entire length of the gas discharge duct 6.

In this case, the inclination angle α varies between 0 ° and 90 °. About lut- angle α is greater than 90 °, the dust particles are caused to 10 15 20 W .65 545 10 strike the diverter plate 15 and bounce into the gas discharge channel 6, which in other words means that the gas is not purified from these dust particles in accordance with the treatment principle underlying the gas purification device according to present invention.

Yet another embodiment of the device is described below. for the purification of gases from particulate matter, moisture and soluble gaseous pollutants.

This embodiment of the gas purification device according to the present invention The present invention includes a housing 18 (Fig. 6), which is enclosed space a rotor 19, which comprises a shaft 20 and attached to it discs 21 (Fig. 7), which are arranged in such a way that a gap is left between the disks Z1. The house l8 is provided with a gas supply duct 22, a gas discharge duct 23 and a channel 24 for discharging pollutants. Channels 22 and 23 are formed between the walls of the house 18 and a partition wall 25, respectively, which is arranged in the housing 18 along the gas flow direction, wherein the channels 22 and 23 are arranged tangentially in relation to the discs 21, while the channel 24 for discharging contaminants is received in the gas discharge channel 23 and extends along the entire length of the rotor 19. The ends of the shaft 20 are passed through holes 26 and 27, respectively, which are accommodated in the end walls 28 and 28 of the housing 1, respectively 29, and projects beyond the housing 18, with the ends of the shaft 20 by means of bearings 30 and 31, respectively, are mounted in flanges 32 and 33, respectively, which are attached to the walls 28 and 29 of the housing 18 respectively 29 coaxially with the axis of rotation of the rotor 19 0 -0 The flanges 32 and 33 are provided with cavities 34 res: Bš and with radial holes 36 resp 27. The end of the shaft 20 facing the flange 33 is by means of a coupling 38 connected to a shaft of an electric motor 39, which by means of a sleeve 40 is arranged on the end surface of the flange 33. Axeln 20 and the discs 21 are made of high heat conforming material ductility. the shaft 20 being hollow. One of the shaft 20, in the flange- end 32 cavity 34 located end, is provided with radial holes 41, which are occupied in one and the same plane with the respective radial hole 36 in the flange 32, while the other of the shaft 20, in the flange The end of 33 cavities 35 is provided with radial holes 42, which ka are occupied in one and the same plane with respective radial holes 37 in 10 15 20 25 30 35 11 465 545 the flange 33. The shaft 20 is connected to one for carrying out a device intended for a heat exchange process. which consists of a to an impeller belonging to a centrifugal fan 43. which is arranged in the middle of the holes 41 in the cavities 34 of the shaft 20 in the flange 32 they end and are intended for pumping the heat transfer means through the cavity 44 of the shaft 20. The outside of the wall 29 of the housing 18 (fig. 8) supports - by means of a bracket arm fastened by means of a screw 46 45 - a thermoregulatory filled with a liquid working medium tor 47 of bellows TYPE. whose piston rod 48 by means of a shaft journal 49 is articulated to a lever 50, which is attached to a choke valve 51 for regulating the amount of heat transfer supplied average. The throttle valve 51 is in the form of a ring with radial holes 52. which are occupied in one and the same plane with the respective radial holes 37 in the flange 37 and with respective radial heels 42 in the shaft 20, the holes 52 and 37 having the same diameter. Number of holes 52 in the throttle valve 51 is equal to the number of holes 37 in the flange 33.

The throttle valve 51 is mounted on the flange 33 in such a manner that it can be rotated about the longitudinal axis of the gas purification device 02-02.

All versions of it for the discharge of pollutants channel 24 in the embodiment of the gas the purification device of the present invention is similar to those of Figs. 1 and 5 show the embodiments of the channels 7.

The side surfaces of the discs 4 (Figs. 1 and 4) and 21 (Fig. 7) may be As an example, Fig. 9 shows an embodiment of the plate 4 with corrugated, for example corrugated side surfaces.

The gas purification device of the present invention operates in the following way.

When the rotor 2 arranged in the housing 1 of the gas cleaning device by means of the electric motor ll is turned in the arrow C (fig. 1) direction, the gas flowing in the direction of the arrow D is carried away gas feed channel 5 - by viscosity frictional forces occurs at the surfaces of the discs 4 - in the direction of rotation of the rotor 2 the gas flowing along the inside of the housing cylinder wall so that its direction of flow is reversed to the 10 15 20 25 30 E 465 545 ” and then inserted into the gas discharge duct 6. The centrifuges bird forces, which are generated at the same time as the gas flow is reversed, so that dust particles and particles of other solid pollutants nings. which are present in the gas being purified, in the gaps between The plates 4 of the rotor 2 are displaced in the radial direction towards the housing 1 cylindrical wall and fed - together with part of the gas flow - in the canal intended for the discharge of pollutants len 7 in the direction of arrow E, while the purified gas is removed through the gas discharge channel 6 in the direction of the arrow B to the intended place.

In the embodiments of the gas purification device according to the present invention, according to the invention, where the channel 7 for discharging contaminants consists of the holes 13 (or gap 14), which are accommodated in the wall of the housing 1 separates the drain plate 15 in this case it part of the gas flow that has the maximum concentration of pollutants nings. including fine and light particles, which as a result of its insignificant mass does not have time to be carried to the house 1 cylindrical wall and diverts the gas flow in the direction of the duct 7 for discharging contaminants.

In a second embodiment of the gas purification device according to According to the present invention, the part of the gas flow which has maximum concentration of pollutants, including fine and light particles. which due to their insignificant mass do not has time to reach the cylindrical wall of the housing 1, by means of it additional partition wall 17 and is diverted through the channel 7 for discharge pollution.

The second embodiment of the gas purification device according to the present invention operates in the following manner.

When the rotor 19 arranged in the housing 18 of the gas purification device by means of the electric motor 39 is caused to rotate in the arrow K (fig. 6) direction, it is carried in the direction of the arrow S the gas from the gas supply channel 22 - under the influence of vid effective viscosity frictional forces of the 24 surfaces of the discs - i 10 15 20 25 30 35 13 463 545 the direction of rotation of the rotor 19, the gas flowing along the side of the cylindrical wall of the housing 18 so that its flow direction is changed to the opposite and then introduced into the gas outlet. supply channel 23. The centrifugal forces generated simultaneously as the gas flow is reversed, it appears that dust particles and particles of other solid particles, which are present in the gas which is cleaned, in the gaps between the discs 24 of the rotor 19 are displaced in radial joint against the cylindrical wall of the housing 18 and is inserted together with a part of the gas flow in it for the discharge of pollutants channel 24 in the direction of the arrow N, while the cleaning the gas is diverted through the gas discharge channel 6 in the direction of the arrow F to the intended place. At the same time as the rotor 19 rotates al- the impeller 43 belonging to the centrifugal fan, as in this embodiment of the gas purification device serves as one device for carrying out a heat exchange process. one low pressure (negative pressure) in the cavity 44 in the shaft 20. Cold atmosphere fresh air flows in through the radial, into the throttle valve 51 and the holes 52 and 37, respectively, are accommodated in the cavities 35 of the flange 33 and passed through the radial holes 42 received at the end of the shaft 20 and into the cavity 44 in the shaft 20. Air is sucked by the centrifugal the impeller 43 of the fan through the radial ones, at the other end of the shaft 20 the recessed holes 41 enter the cavity 34 in the flange 32 and are discharged from the same through the radial holes accommodated in the flange 32 36. At the same time as air flows through the cavity 44 in the arrow Z (Fig. 7) direction cools that shaft 20 and the skis attached thereto. 21 in that the shaft 20 and the discs 21 are made of materials with high thermal conductivity. The gas. which is pumped through of the rotating rotor 19, is cooled in the cavity of the housing 18 by heat exchange takes place over the considerable total contact area between the gas and the surface of the cooled discs 21 at a rather high temperature gradient, to a temperature equal to dew the point of water vapor present in the gas, whereby the the liquid phase of the gas condenses at the surface of the discs 21.

The centrifugal forces act as layers of condensed liquid continuously drains from the surfaces of the rotating discs 21 in substantially radial direction towards the cylindrical wall of the housing 18 and is continuously formed at the surfaces of the discs 21 by it moist gas. fed into the gas purifier by gas the input channel 22. is cooled. Soluble gaseous pollutants 10 15 20 14 463 545 present in the gas being purified, for example ammonia, is dissolved in layer of at the considerable total surface area of the discs 21 serated liquid. The dissolution of gaseous pollutants in liquids can be made more efficient by the mutual cross-directional flow of on the one hand, the gas which, in the housing 18 of the gas purifier at the flow is tangential, and the liquid which drains down from the surfaces of the discs 21 in a substantially radial direction. At the cylindrical wall of the housing 18 also dissolves the gaseous the purifications in the condensate layer which drains from said wall - under the influence of the gas flow - in the direction of rotation of the rotor 19 into the channel 24 for discharging contaminants. The one from fin- distributed inclusions and soluble gaseous pollutants purified gas with reduced (insignificant) water content and with reduced cerated (lower) temperature is diverted through the gas discharge duct 23 to the intended place (to gas consumers).

If the temperature of the heat transfer medium contained in this embodiment of the gas purification device according to the present invention finning consists of cold atmospheric air, changes, for example through that the current weather conditions change, the thermal the longitudinal dimension of the regulator 47 by the thermoregulator 47 responds to the temperature end of the medium 47 surrounding the controller resulting in the thermoregulator 47 by the piston rod 48, which is hingedly connected by means of the shaft journal 49 with the lever 50 attached to the throttle valve 51, the throttle the valve 51 around the flange 33. This displaces the radial ones. the holes 52 accommodated in the throttle valve 51 in relation to resp radial holes 37 in the flange 33, which leads to the holes 37 and 52 total flow areas are changed, thereby amount of cold atmospheric air fed into the cavity 20 of the shaft 20 changed accordingly. When the temperature of the atmospheric air decreases restricting valve 51 by means of thermoregulatory tower 47 the amount of cold air fed into the cavity 44 in the shaft 20. If the air temperature is raised, the throttle valve 51 increases by the thermoregulator 47 the amount of cold air fed into the cavity met 44. This automatically maintains the temperature of the rotor 19 the level required in order for water vapor to be able to condense at the surfaces of the disks 21 at different atmospheric air temperatures and partly to the temperature of the gas being purified 10 15 20 25 30 35 15 463 543 and dried, must always be able to be kept within predetermined borders.

Because the side surfaces of the discs 4 and 21 are corrugated, they become the aerodynamic properties of rotors 2 and 19, which acts as a working means in the fan of the gas purification device, significantly better, thereby increasing the gas purification capacity of the device.

The device proposed according to the present invention can pumped gases, clean them from atomized inclusions, cooling and drying gases and purifying them from soluble gaseous pollution, works very efficiently, provides great process capacity city, has simple construction and compact exterior dimensions.

The device according to the present invention is not complicated to produce.

In addition, one embodiment of the gas purification device can be provided. the order of the present invention, where instead for the thermoregulator uses an actuation mechanism of any another suitable type, which is connected to a throttle valve for regulation of the amount of heat transfer agent added and is controllable according to a predetermined program and which, like the controller can change the heat exchange conditions and establish maintain the desired temperature of the gas being purified. within predetermined limits when the temperature of the heat transfer medium is constant.

The device of the present invention can also be used for the purification of gases from dust and other suspended pollutants substances while simultaneously heating the gas being purified, by using a heat transfer medium, the temperature of which is higher than the gas temperature.

The gas purification device designed according to the present invention can be used in air conditioning systems in buildings and facilities of various kinds as well as in cinemas, theaters, metro stations, railway stations, etc. For example within 16 465 545 In agriculture, the device of the present invention can be used. in livestock breeding premises for the purification of air from dust, moisture content and removal of ammonia from air, when animals during the winter are kept in stalls.

Claims (9)

10 15 20 25 30 35 17 4-63 54š Patent claim A gas cleaning device, the housing (l; l8) of which contains a rotor (2; l9), which comprises a shaft (3; 20) and a disc (4; 21) attached thereto, the housing (l; l8) being provided with a gas supply duct (5; 22), a gas discharge duct (6; 23) and a duct (7; 24) for discharging contaminants, characterized in that at least one further identical disc (4; 21) is attached to the rotor ( 2; l9) shaft (3; 20) in such a way that a gap is formed between this disc (4; 21) and each adjacent disc (4221). and that a partition wall (8; 25) is arranged in the housing (18; 18) along the gas flow direction, the gas supply duct (5; 22) and the gas discharge duct (6; 23) being formed between the housing (18; 18) and the wall, respectively. and the partition wall (8; 25) and arranged tangentially with respect to the discs (4; 21), while the channel (7; 24) for discharging contaminants is received in the gas discharge channel (6; 23) and extends along the entire length of the rotor (2; l9). Device according to claim 1, characterized in that the shaft (20) and the discs (21) are made of material with high thermal conductivity, the shaft (20) being connected to a means for carrying out a heat exchange process. Device according to claim 2, characterized in that the shaft (20) is hollow. while its ends are provided with radial holes (41.42). through which a heat transfer means can flow, the means for carrying out the heat exchange process consisting of an impeller (43) arranged on one end of the shaft (20) for pumping the heat transfer means through the cavity (44) of the shaft (20). Device according to claim 3, characterized in that a throttle valve (51) connected to a thermoregulator (47) for regulating the amount of heat transfer means supplied is arranged around the end of the shaft (20) which is opposite its end which supports the impeller. (43) for pumping the heat transfer means through the cavity (44) of the shaft (20), the throttle valve (51) being arranged opposite the radial holes (42). 10 15 20 465 545 18 Device according to one of Claims 1 to 3, characterized in that the channel (7; 24) for discharging contaminants consists of at least one row of holes (13) accommodated in the wall of the housing (1; 18). Device according to one of Claims 1 to 3, characterized in that the channel (7; 24) for discharging contaminants consists of at least one slot-shaped hole (14) accommodated in the wall of the housing (1; 18). Device according to Claim 5 or 6, characterized in that the gas discharge channel (6; 23) contains a discharge plate (15) arranged after the channel (7; 24) for discharging contaminants, seen in the direction of gas flow. - the center line (01-01) of the discharge channel (6; 23) with an angle (a) and extending along the entire length of the channel (6; 23). Device according to one of Claims 1 to 4, characterized in that the channel (7) for discharging pollutants is formed between the respective wall of the housing (1) and an additional partition wall arranged in the gas discharge channel (6). (17). Device according to one of Claims 1 to 8, characterized in that the side surfaces of the discs (4; 21) are corrugated.