JP2012197920A - Wear suppression method and wear suppression device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a wear suppression method for protecting an object surface which wears due to collision of solid particles against an air flow containing the solid particles.SOLUTION: The wear suppression method is disclosed to protect an object surface 3 which wears due to collision of solid particles 1 against an air flow containing the solid particles 1. A protective solution introducing part 5 is provided in order to introduce a protective solution 4 onto the object surface 3. The protective solution 4 is introduced from the protective solution introducing part 5 in order to form a liquid film 6 on the object surface 3 and to reduce a collision energy of the solid particles 1 colliding with the object surface 3 via the liquid film 6, thereby suppressing wear of the object surface 3.

Description

  The present invention relates to a wear suppressing method and a wear suppressing device for protecting an object surface worn by collision of solid particles against an air flow including solid particles.

  In a pipe that flows a solid-gas mixed phase flow in which airflow and solid particles are mixed, such as a cyclone of a fluidized bed boiler, a pulverized coal burner pipe, or various powder transport pipes, for example, at a corner where the direction of the pipe changes, There is a problem that the object surface is severely worn by collision.

  As a method for protecting a portion where abrasion due to solid particles in an air stream is intense, there is a method for suppressing erosion of an object surface by blowing gas to the wear portion as described in Patent Document 1, for example.

JP 2003-56407 A

Hashimoto Kenji, “Wear due to granular material”, Industrial Technology Center, 1974, p. 108

  However, the method of Patent Document 1 is a method in which a coolant that is vaporized by the heat of a high-temperature airflow is charged in advance on the object surface, and the object surface is covered with a vaporized cooling gas layer, and the momentum of solid particles is sufficiently reduced. Thus, it was not possible to form a gas layer sufficient to cause the wear, and the wear on the object surface could not be reduced sufficiently.

  As described above, in the method of protecting the object surface from the solid particles widely dispersed in the air flow by the gas blowing, it is necessary to use a large amount of gas that affects the momentum of the solid particles in the air flow or the air flow. was there.

  The present invention has been made to solve the above problems, and provides a wear suppression method and a wear suppression device for protecting an object surface that is worn by collision of solid particles against an air flow including solid particles. Is.

  The present invention devised to achieve the above object is a wear suppression method for protecting an object surface worn by collision of solid particles against an air flow containing solid particles. Providing a protective liquid introduction part to be introduced, introducing a protective liquid from the protective liquid introduction part to form a liquid film on the object surface, and reducing the collision energy of solid particles colliding with the object surface with the liquid film; This is a wear suppression method for suppressing wear of the object surface.

  In addition, the present invention provides a wear control device for protecting an object surface that is worn by collision of solid particles against an air flow including solid particles, and further includes a protective liquid introducing portion that introduces a protective liquid into the object surface. Providing a protective liquid supply section for supplying a protective liquid to the protective liquid introducing section, introducing a protective liquid from the protective liquid introducing section to form a liquid film on the object surface, and using the liquid film on the object surface The wear suppression device is configured to reduce the collision energy of the solid particles that collide and suppress wear of the object surface.

  ADVANTAGE OF THE INVENTION According to this invention, the abrasion suppression method and abrasion suppression apparatus for protecting the object surface worn by the collision of the solid particle with respect to the airflow containing a solid particle can be provided.

It is the schematic explaining the abrasion suppression method which concerns on one embodiment of this invention. It is a schematic block diagram of the protective liquid introduction part which concerns on one embodiment of this invention. It is a principal part schematic diagram explaining the abrasion suppression method which concerns on one embodiment of this invention. It is the schematic explaining the abrasion suppression method which concerns on other embodiment of this invention.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

  FIG. 1 is a diagram showing a configuration of a wear suppressing device for carrying out the wear suppressing method according to the present embodiment. Here, as an example, a case will be described in which the wear of the corner portion of the pipe 2 through which the air flow including the solid particles 1 passes is suppressed. In this case, the position indicated by hatching in FIG. 1, that is, the inner wall located outside the corner portion of the pipe 2 becomes the object surface 3 that is worn by the collision of the solid particles 1.

  As shown in FIG. 1, the wear suppression device 100 protects the protective liquid introduction unit 5 that introduces the protective liquid 4 from the vicinity of the object surface 3 in the pipe 2 and above the object surface 3, and the protective liquid introduction unit 5. A protective liquid supply unit 101 for supplying the liquid 4, a liquid film 6 formed of the protective liquid 4 is formed on the object surface 3, and the solid particles collide with the object surface 3 by the liquid film 6. 1 to reduce wear energy of the object surface 3.

  In the present embodiment, the protective liquid introducing portion 5 is formed in a nozzle shape and connected to the upper side of the object surface 3 so as to blow out the protective liquid 4 from the wall surface of the pipe 2. With this configuration, the protective liquid 4 introduced to the object surface 3 flows downward on the surface of the object surface 3 to form a liquid film 6 for protecting the object surface 3 from abrasion.

  As shown in FIG. 2 (a), the protective liquid introducing unit 5 is provided with an ejection plate 7 provided on the wall surface of the pipe 2 and serving as an ejection port for the protective liquid 4, and the protective liquid 4 from the protective liquid supply unit 101. An introduction pipe 8 to be sent to the ejection plate 7 is mainly provided.

  In the present invention, as the ejection plate 7, for example, a metal plate 7h provided with a large number of blowing holes 9 as shown in FIG. 2B, or a metal provided with a large number of slits 10 as shown in FIG. A plate 7s or the like can be used. By using such an ejection plate 7, the supply range of the protective liquid 4 from the protective liquid introducing unit 5 can be expanded, the area of the object surface 3 covered with the liquid film 6 can be expanded, and the solid particles 1 can be expanded in a wider range. It is possible to protect the object surface 3 from the collision. These ejection plates 7 are manufactured by punching or slitting a metal plate. In addition to these, a porous sintered metal formed so as to allow the protective liquid 4 to ooze out from the inside can also be used.

  In the present invention, as shown by a dotted line in FIG. 1, the protective liquid introducing portion 5a is provided above the object surface 3 (that is, inside the pipe 2), and its outlet is made to face the object surface 3 and the air flow. Further, the protective liquid 4 may be blown out toward the object surface 3. Moreover, you may comprise like the protective liquid introducing | transducing part 5b arrange | positioned facing the object surface 3 toward the downstream of an airflow, while making an ejection port oppose. In this case, the protective liquid 4 can be directly sprayed onto the solid particles 1 flying on the object surface 3 to coat the solid particles 1 with the protective liquid 4. However, since it is necessary to form the liquid film 6 with the protective liquid 4 on the object surface 3 in order to sufficiently suppress the wear, the shape and position of the protective liquid introducing portion 5a is the same as that of the sprayed protective liquid 4 It is assumed that the liquid film 6 can be formed on the surface 3.

  The protective liquid supply unit 101 of the wear suppression apparatus 100 includes a supply system 102 for supplying the protective liquid 4 to the protective liquid introducing unit 5 and a discharge for discharging the protective liquid 4 from the lower side of the object surface 3 to the outside of the pipe 2. A system 103.

  The supply system 102 includes a tank 11 that stores the protective liquid 4, a pump 12 that pumps the protective liquid 4 from the tank 11, and a supply valve that adjusts the supply amount of the protective liquid 4 to the protective liquid introduction unit 5. The tank 11, the pump 12, the supply valve 13, and the protective liquid introduction unit 5 are sequentially connected by a supply pipe 14. The supply system 102 adjusts the supply amount of the protective liquid 4 pumped from the tank 11 by the pump 12 by the opening degree of the valve 13, and introduces the protective liquid 4 from the protective liquid introduction part 5 to above the object surface 3. is there. The tank 11 is provided with a drain valve 15 for extracting the protective liquid 4, and a flow meter (not shown) for measuring the flow rate of the protective liquid 4 is provided in the supply pipe 14.

  The discharge system 103 is provided below the object surface 3 and has a discharge hole 16 for discharging the protective liquid 4 out of the pipe 2. The discharge system 103 is provided on the downstream side of the liquid film 6 with respect to the discharge hole 16 and leaks the protective liquid 4. And a filter 17 for filtering the discharged protective liquid 4 to separate it into the solid particles 1 and the protective liquid 4, and the discharge hole 16 and the filter 18 are connected to the discharge pipe. 19 is connected. In this discharge system 103, the cover 17 is formed so as to cover the upper side of the discharge hole 16 and the downstream side of the liquid film 6, and the protective liquid 4 flowing from the object surface 3 is dammed by the cover 17 to discharge the discharge hole 16. And discharged to the outside of the pipe 2. Further, the cover 17 is devised so that the air flow including the solid particles 1 does not directly enter the discharge hole 16.

  In a configuration in which the protective liquid 4 does not flow out from the object surface 3 such as when the corner portion of the pipe 2 is positioned at the lowermost position, the discharge hole 16 is connected to the lowermost position of the object surface 3. In such a case, since the introduced protective liquid 4 does not leak, the cover 17 may be omitted.

  In the present embodiment, the tank 11 of the supply system 102 and the filtration unit 18 of the discharge system 103 are connected by the circulation pipe 20, and the protective liquid 4 collected through the filtration unit 18 from the discharge hole 16 is returned to the tank 11 and recycled. I am trying to use it. In the present invention, the supply system 102 and the discharge system 103 may be independent.

  As shown in FIG. 3, the liquid film 6 is formed by a protective liquid 4 that flows downward from above the object surface 3. The liquid film 6 reduces the collision speed of the solid particles 1 flying toward the object surface 3 to suppress wear, and discharges the captured solid particles 1 downward to clean the object surface 3. Is.

  As the protective liquid 4 for forming the liquid film 6, it is preferable to use water from the viewpoint of economy and wear suppression.

  As described in Non-Patent Document 1, when about 10% by mass of water is normally attached to solid particles that collide with the object surface 3, contact between the collided solid particles 1 / object surface 3 is caused by moisture. Since it is lubricated, the solid particles 1 will grind the object surface 3 deeper, and the amount of wear increases. However, the amount of water contained in the colliding solid particles 1 is 20% by mass or more (in other words, the amount of water with respect to the total mass of the solid particles 1 and the water adhering to the solid particles 1 is 20% by mass or more. ) And the adhering water itself alleviates the collision between the solid particles 1 and the object surface 3, and the wear amount is reduced.

  That is, when water is used as the protective liquid 4 and the liquid film 6 is formed on the object surface 3 so that the amount of water contained in the solid particles 1 colliding with the object surface 3 is 20% by mass or more, the liquid film 6 The wear of the object surface 3 can be effectively suppressed by the first cushion effect that reduces the collision speed of the solid particles 1 and the second cushion effect that relaxes the collision of the solid particles 1 with the water adhering to the object surface 3. It becomes.

  In the present invention, in order to suppress heat transfer deterioration of the pipe 2, a heater or heat exchange means for supplying the protective liquid 4 after heating may be provided in the supply system 102.

  Further, in the present invention, besides using water as the protective liquid 4, the components of the protective liquid 4 can be appropriately changed depending on the material, shape, temperature, pressure, and the like of the pipe 2. For example, in an environment where the flow velocity of the airflow is fast and water as the protective liquid 4 is scattered and caught downstream of the pipe 2, an organic solution having a large specific gravity and viscosity can be used. Moreover, you may mix | blend the antirust agent for corrosion prevention of the piping 2 with water.

  Next, the wear suppression method according to the present embodiment will be described.

  When there is a concern about the wear of the object surface 3 due to the solid particles 1 contained in the air stream, the pump 11 is started and the supply valve 13 is opened to supply the protective liquid 4 in the tank 11 to the protective liquid introducing section 5.

  The protective liquid introduction part 5 is connected above the object surface 3, and the protective liquid 4 introduced from the protective liquid introduction part 5 flows downward on the object surface 3, and a liquid film 6 is formed by the protective liquid 4. Is done.

  Here, when water is used for the protective liquid 4 that becomes the liquid film 6, the amount of water contained in the solid particles 1 that collide with the object surface 3 based on an instruction value of a flow meter (not shown) in the middle of the supply pipe 14. The amount of the protective liquid 4 supplied from the protective liquid introducing unit 5 is adjusted so that the amount becomes 20 mass% or more. The supply amount of the protective liquid 4 is adjusted by the opening degree of the supply valve 13.

  As shown in FIGS. 1 and 3, the liquid film 6 formed on the object surface 3 significantly reduces the collision speed of the flying solid particles 1 on the object surface 3 and suppresses wear of the object surface 3. . Further, the captured solid particles 1 are moved downward to prevent the solid particles 1 from adhering to and depositing on the object surface 3.

  The solid particles 1 that have moved to the lower side of the object surface 3 together with the protective liquid 4 are discharged out of the pipe 2 from the discharge hole 16 and filtered by the filtering unit 18, and only the protective liquid 4 is returned to the tank 11.

  When the concern about the wear of the object surface 3 decreases due to a decrease in the concentration of the solid particles 1 in the airflow, the pump 11 is stopped and the supply valve 13 is closed, and the operation of the wear suppression device 100 is terminated.

  In short, in the wear suppressing method of the present invention, the liquid film 6 is formed on the object surface 3 to be protected from wear, and the collision energy of the solid particles 1 that collide with the object is reduced by the liquid film 6 to reduce the wear of the object surface 3. I try to suppress it.

  According to the present invention, since the collision speed of the solid particles 1 is reduced by the liquid film 6, the deceleration effect (cushion effect) of the solid particles 1 is large, and wear of the object surface 3 can be further suppressed.

  Further, it is not necessary to introduce a large amount of air as in the gas blowing method, and wear can be suppressed with a small amount of the protective liquid 4.

  Furthermore, since the solid particles 1 can be discharged out of the pipe 2 together with the protective liquid 4, the solid particles 1 do not adhere to and accumulate in the pipe 2.

  The present invention is not limited to the above embodiment, and various modifications can be made.

  For example, as shown in FIG. 4, a protective liquid header 42 is provided in a cyclone 41 for separating the solid-gas mixed phase airflow into the solid particles 1 and the gas, and the protective liquid 4 is introduced from the protective liquid header 42 to introduce the cyclone 41. The inner wall is covered with a liquid film 6, and the collision speed of the flying solid particles 1 is reduced by the liquid film 6 to suppress wear, and the captured solid particles 1 are discharged downward together with the protective liquid 4. You may do it.

  Even in the configuration as shown in FIG. 4, the wear suppressing method according to the present invention can effectively suppress wear due to collision of solid particles.

  Further, a plurality of protective liquid introducing portions 5 for introducing the protective liquid 4 may be provided to protect a wider range of the object surface 3 from collision of the solid particles 1.

  Further, the ejection plate 7 (7h, 7s) is not limited to metal. Of course, it is possible to appropriately change the material of the ejection plate 7 in accordance with the pressure, temperature, airflow, and type of the protective liquid.

DESCRIPTION OF SYMBOLS 1 Solid particle 2 Piping 3 Object surface 4 Protective liquid 5 Protective liquid introduction part 6 Liquid film 100 Wear suppression apparatus 101 Protective liquid supply part 102 Supply system 103 Discharge system

Claims (2)

In the wear suppression method for protecting the object surface worn by collision of the solid particles against the air flow containing the solid particles,
A protective liquid introduction section for introducing a protective liquid into the object surface is provided, a protective liquid is introduced from the protective liquid introduction section to form a liquid film on the object surface, and the solid collides with the object surface with the liquid film A method for suppressing wear, comprising reducing collision energy of particles and suppressing wear of the object surface. In the wear suppression device for protecting the object surface worn by the collision of the solid particles against the air flow containing the solid particles,
While providing a protective liquid introduction part for introducing a protective liquid into the object surface,
Providing a protective liquid supply section for supplying a protective liquid to the protective liquid introduction section;
A protective liquid is introduced from the protective liquid introducing portion to form a liquid film on the object surface, and the liquid film reduces the collision energy of solid particles that collide with the object surface, thereby suppressing wear of the object surface. A wear suppressing device characterized by comprising: