EP0141073A2 - Method of increasing the degree of separation in a cyclone, and cyclone for carrying out said method - Google Patents

Abstract

The separating efficiency of a cyclone separator used for removing solid particles from a gas stream (for example ash particles from the combustion gas which is passed to a gas turbine) is increased by retarding the particles before they arrive at the cyclone and thereafter accelerating them over a short distance before they enter the cyclone. In this way large particles will have a lower speed than small particles when entering the cyclone. Despite a high velocity of the transport gas and a high inlet velocity for small particles, it is possible to obtain an inlet velocity for larger particles which is desirably low from the point of view of reducing erosion of the cyclone separator. The separation of fine particles is improved. The retardation of the particles may take place in a T-shaped branch pipe, which has one branch connected to the cyclone, a second branch connected to a conveying pipe and a third branch which is formed as a blind space.

Description

The present invention relates to a method for increasing the degree of separation of a cyclone according to the preamble of claim 1 and a cyclone separator for performing the method.

The degree of separation of a cyclone depends to a large extent on the rate of entry into the cyclone and on the size of the particles. The greater the entry speed, the greater the degree of separation. Small particles are more difficult to separate than large ones. This is due to the fact that small particles have a low falling speed and are more easily entrained with the air flow into the central part of the cyclone.

• 1. Der Druckabfall wird größer.
• 2. Die Erosion an der Mantelfläche des Zyklons nimmt zu. Diese Erosion wird zum überwiegenden Teil durch die größeren Partikel verursacht.

In order to increase the degree of separation, it is obvious to increase the rate of entry into the cyclone. However, this has the following adverse effects in a system of known design:

• 1. The pressure drop increases.
• 2. The erosion on the surface of the cyclone increases. This erosion is mainly caused by the larger particles.

The increased pressure drop is often acceptable; on the other hand, the erosion leads to a drastic shortening of the lifespan of the cyclone when the flow velocity is increased. Therefore, entry velocities higher than 20 to 30 m / s are generally not used.

The invention has for its object to develop a method according to the preamble of claim 1 together with bushing arrangement, which has a significantly greater degree of separation, without the shortening of the service life due to increased entry velocities of the gas at the entry of the cyclone.

To achieve this object, a method is proposed according to the preamble of claim 1, which according to the invention has the features mentioned in the characterizing part of claim 1.

Advantageous embodiments of the method according to the invention are mentioned in claims 2 to 4.

A cyclone separator for performing the method is characterized according to the invention by the features mentioned in claims 5 and 6.

According to the invention, the particles in the transport gas are braked or brought to a standstill at a certain distance before entering the cyclone. Behind this braking point, the particles are accelerated again by the transport gas. The large, heavy particles are accelerated more slowly than the small, light particles. By arranging the braking point at a suitable distance from the entrance to the cyclone, a desired "speed profile" can be achieved for the particles at the entrance to the cyclone. This distance is chosen so that the particles, the size of which is above a certain value and which consequently have a large erosion effect, reach a speed which does not exceed approximately 20 m / s. The smallest particles are quickly accelerated to the speed of the transport gas. Due to the high entry speed, a better degree of separation for small particles and an equally good degree of separation for large particles are obtained compared to known cleaning systems. The total degree of separation is thus increased without increasing the erosion and the associated loss in the service life of the cyclone.

The particles can be braked in a T-shaped branch pipe, which is connected to the part of the cyclone corresponding to the vertical bar of the "T". The crossbar of the "T" is connected at one end to the transport line, while the other end is closed with a cover and forms a blind space. A "cushion" consisting of particles collects in this blind space, which forms a braking impact surface and prevents direct contact of the flowing particles with the material of the branch pipe and thus prevents erosion thereof. It is understood that the part of the branch pipe corresponding to the crossbar of the "T" may have ends of different lengths.

The invention can be used, for example, in an incineration plant with a pressurized fluidized bed (PFBC plant) and gas turbines that are driven by the combustion gases of the plant. Here it is necessary to thoroughly separate the particles following the combustion gases in order to prevent erosion damage in the turbines to prevent. When using the invention, one can either maintain the number of cleaning stages connected in series and thus obtain a higher degree of cleaning, or one can reduce the number of cleaning stages connected in series with the same degree of cleaning. In the latter case, fewer cyclones are required and less space is required for the cyclones. The pressure vessel can be made smaller. The investment costs are significantly reduced. The pressure drop caused by the deflection in the T-shaped branch pipes is compensated for by a smaller number of cyclones connected in series.

• Figur 1 einen bekannten Zyklon im horizontalen Schnitt,
• Figur 2 einen entsprechenden Schnitt durch ein Ausführungsbeispiel eines Zyklons gemäß der Erfindung,
• Figur 3 ein Diagramm zur Veranschaulichung der Wirkungsweise der Erfindung.

The invention will be explained in more detail with reference to the exemplary embodiments shown in the figures. Show it

• 1 shows a known cyclone in horizontal section,
• FIG. 2 shows a corresponding section through an exemplary embodiment of a cyclone according to the invention,
• Figure 3 is a diagram illustrating the operation of the invention.

In the figures, 1 denotes a cyclone to which gas containing particles is fed through the transport line 2. The particles, for example dust, which are entrained by the combustion gases and which leave a pressurized fluidized bed of an incineration system, for example a power plant, have essentially the same speed in the transport line 2 as the transport gas. In the known embodiment according to FIG. 1, in which the transport line opens tangentially directly into the cyclone 1, gas and particles have the same speed when they enter the cyclone 1. Particularly coarse particles cause strong erosion at a high rate of entry in the 3 denotes section of the wall of the cyclone. For practical reasons, namely with regard to the service life, the limit for the entry speed is usually between 15 and 20 m / s. At this entry rate, the small particle separation achieved is unsatisfactory. In the embodiment of the cleaning system according to the invention, a T-shaped branch pipe 4 is connected with its part 5 corresponding to the vertical bar of the "T" s to the entrance of the cyclone 1, while the transport line is connected to part 6 of the branch pipe. Part 7 of the branch pipe is closed with a cover 8 and forms a blind space 9 which fills with particles which form a brake pad on which the particles located in the transport line are braked. After braking, the particles in the pipe branch 5 of the branch pipe are accelerated. Small particles are accelerated faster than large ones. By appropriately choosing the length x tube branch 5 in relation to the particle load, the particle size distribution, the particle density, the pressure of the transport gas, the temperature, the viscosity, etc., a suitable "velocity profile" for the particle mass in the gas stream can be obtained . This makes it possible to use gas speeds of 50 m / s and more, but at the same time limit the speed of the larger particles to less than 15 to 20 m / s, which is desirable in view of erosion.

The effect of the invention is clear from Figure 3. Line 10 shows the speed of the transport gas in transport line 2 and in the branch pipe. The particle speed is represented by curve 11, which shows a “speed profile” of the particles. It can be seen from the curve that the particle speed decreases with increasing particle size. The shape and the position of the curve are of the length x of the pipe branch 5 of the branch pipe dependent. With a longer length x, the curve is shifted to the top right, as shown by arrow 12. The dashed curves 11a and 11b show speed profiles with greater or smaller length x of the part 5 of the branch pipe 5. The dashed line 13 denotes the normal entry speed for gas and particles in a conventional cyclone design. As can be seen from curve 11, the entry speed of the larger particles is below line 13, which is desirable in terms of erosion and service life.

The cyclone separator according to the invention is extremely valuable for the separation of bed material or ash from the transport gas of a PFBC plant with a bed and ash discharge device of the type described in EP-A-83306073.4. The cyclone separator is arranged at the outlet end of the discharge device between the latter and a collecting container for separated material. When using ash extraction devices of the type mentioned, it is expedient to work at high transport speeds, for example 50-60 m / s. Direct introduction of the particle-containing gas into a cyclone at this high speed would result in unsustainable erosion and thus shorten the life of the cyclone. The invention achieves both an acceptable wear of the cyclone and a high degree of separation for fine particles.

Claims (6)

1. A method for increasing the degree of separation of a cyclone, characterized in that B the flow of a gas containing particles before the entry into the cyclone (1) is deflected such that the particles are braked, and that the particles are then on a transport route between the deflection point and the entry into the cyclone are accelerated in such a way that larger particles have a lower speed when entering the cyclone than smaller particles. 2. The method according to claim 1, characterized in that d a B the flowing particle-containing gas is deflected by approximately 90 °. 3. The method according to claim 2, characterized in that B the deflection takes place in a T-shaped branch pipe (4) which is provided with a blind space (9) in which a powder column is formed, which has a braking impact surface for the particles the deflection point forms. 4. The method according to any one of the preceding claims, characterized in that it is used in a bed and ash ejection device in a PFBC system for separating bed material or ash from the transport gas. 5. Cyclone separator for performing the method according to any one of the preceding claims, characterized in that B the supply line to the cyclone is provided with a T-shaped branch pipe (4) which corresponds to the vertical bar of the "T" s The corresponding part (5) is connected to the input of the cyclone (1). 6. Cyclone separator according to claim 5, characterized in that it belongs to a bed and ash ejection device in a PFBC system for separating bed material or ash from the transport gas.

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