KR100331480B1 - An apparatus for electronic descaling - Google Patents

Abstract

The present invention relates to a capstone removal device that suppresses and removes a capstone attached to a pipe wall by using a magnetic field. A wire is installed in a pipe through which a fluid flows, and when a current is applied to the wire, a magnetic field is formed. Since the direction is always formed perpendicular to the direction of the flow of the fluid, the capstone removal effect is superior to the conventional method, and the capstone can be effectively suppressed or removed even in the laminar flow in which the conventional method does not exhibit the capstone removal effect.

Description

Capstone removal apparatus using magnetic field {An apparatus for electronic descaling}

The present invention relates to a device for removing a capstone attached to an inner wall of a pipe, and more particularly, to a capstone removal device using a magnetic field that suppresses and removes a capstone attached to a pipe wall using a magnetic field caused by an induced current.

In general, industrial boilers, heat exchangers and general domestic heaters are pipes through which water is circulated. However, these piping systems are attached to the inner wall of the pipe by depositing and binding ions dissolved in the water in the long-term use, these attachments prevent the smooth flow of water and heat transfer. Sediments attached to the wall in this way is called capstone.

For example, heat exchanger pipes need to be replaced at intervals of three or five years due to deterioration in heat transfer due to capstone, and the thicker the capstone in a boiler, the higher the fuel consumption. If you remove these capstones effectively, their economic impact will be very large.

The most common capstone in water-based industrial equipment is calcium carbonite (limestone). Calcium carbonite has two grain structures, Calcite structure and Argonite structure, and double calcite structure is weak and easy to remove. On the other hand, the new stone structure has a strong adhesion and difficult to remove.

However, limestone contained in the water used in industrial boilers and heat exchangers is mostly attached to the new stone structure, attached to the wall, and gradually grows, causing a decrease in heat transfer and an increase in power loss. If the limestone is made of a weakly adherent calcite structure, it can be prevented from adhering to the tube wall, thereby suppressing the growth of the capstone on the wall surface.

As a method of removing a capstone, a method of removing by using a magnetic field (ED; Electronic Descaling) in addition to a mechanical method is known. This method is artificially applied by applying electric energy in the form of pulse, as shown in FIG. Calcium carbonite ions combine to form calcite.

Since the combination of the calcite structure is weak adhesion, it is not attached to the wall is discharged in a floating state in the water. In addition, the capstone already attached to the wall as a new stone structure is a method of removing the capstone attached to the wall by dissolving again in the water as the concentration of ions decreases as calcium carbonite contained in the water is combined into the calcite structure.

That is, when the conductor 102 is applied to the pipe 101 and a current is applied, a magnetic field is generated in the pipe. When water flows through this area, the ions in the water become electric charges, thereby inducing the electromotive force and the Lorentz force. Will receive. These forces act to provide energy for the ions to combine into the calcite structure, where charged particles moving in the magnetic field are subjected to Lorentz's force, which is represented by Equation 1 below. Equation 1] F = BIL sin θ Here, B is the strength of the magnetic field, I is the strength of the current, L is the length of the conductor, θ means the angle between the direction of the magnetic field and the current. It can be seen that when the angle (θ) formed by the direction of 0 becomes 0 °, the Lorentz force (F) becomes '0', and the maximum becomes 90 ° or the right angle. Flows along the streamline, but the higher the flow rate, the more individual particles flow with turbulent flow, and when the flow rate falls below a certain limit, ie, the limit Reynolds number, laminar flow in turbulence. (lam It turns out that these fluctuations do not occur in inar flow, that is, the flow of ions contained in the water in the pipe can be considered to behave like the flow of water. In other words, the flow of ions from the macroscopic point of view is the direction of water flow, and above the limit velocity, the ions flow as the microscopic fluctuations of the water occur. 1 and 2, the conductive wire 102 is wound around a cylindrical coil shape (solenoid form) on the outer peripheral surface of the pipe 101, and when a current is applied to the conductive wire 102, A magnetic field is formed inside the pipe 102, and the ions precipitated in the water are subjected to induced electromotive force through the region where the magnetic field is formed. Here, the magnetic field is generated in the longitudinal direction of the pipe 101, and this direction is macroscopic. It becomes the same as the flow direction (→ table direction) of the ions contained in the water in terms of phosphorus. That is, the direction in which the ions contained in the water flow (the direction of the current) and the direction of the magnetic field generated by the conducting wire 102 become parallel (θ = 0 °), and accordingly, Lorentz's force received from the macroscopic point of view (F) becomes 0. As described above, there is a momentary fluctuation of ions from the microscopic point of view by the turbulent motion above the limit velocity, and this fluctuation is a small but somewhat force because it forms a predetermined angle with the magnetic field. Will receive. By the induced electromotive force, the ions have energy that can be combined into the calcite structure.However, below the limit velocity, the flow changes to laminar flow so that these fluctuations do not occur and thus the ions are not subjected to the force, thus the ions are calcite. Since there is no energy to bind to the structure, the ions bind to the tube wall by binding to the nephrite structure, which is the original state of bonding. That is, the conventional method has a problem that can not suppress or remove the production of capstone below the limit speed.

The present invention has been made to solve the problems described above, by using the magnetic field to increase the removal of the capstone by making the direction of the magnetic field is always perpendicular to the direction of the flow of fluid and to remove the capstone even in laminar flow It is an object of the present invention to provide a capstone removal device. In the capstone removal device of the present invention for achieving the above object, a conductor is installed in a pipe through which a fluid flows, and when a current is applied to the conductor, a magnetic field is formed. Since the direction of the magnetic field is always perpendicular to the direction of the fluid flow, it is possible to effectively remove the capstone even in laminar flow.

1 is a conceptual diagram showing a capstone removal apparatus using a general magnetic field,

Figure 2 is a block diagram showing a capstone removal apparatus using a conventional magnetic field,

Figure 3 is a perspective view schematically showing the installation state of the capstone removal apparatus using a magnetic field according to the present invention

Figure 4a is a plan view of the conductor installed in the pipe, Figure 4b is a longitudinal cross-sectional view of Figure 4a, Figure 5 is a graph showing the pressure difference between the inlet and outlet at RE = 1010, Figure 6 is a heat transfer coefficient at RE = 1010 7 is a graph showing the pressure difference between the inlet and the outlet at RE = 1650 as shown in FIG. 5, and FIG. 8 is a graph showing the heat transfer coefficient at FIG. 6 at RE = 1650. * 10: Piping 20: Conductor 30: Control box

Hereinafter, with reference to the accompanying drawings, the present invention will be described in detail.

Figure 3 is a perspective view schematically showing the installation state of the capstone removal apparatus using a magnetic field according to the present invention, Figure 4a is a plan view of a state in which a conductor is installed in the pipe, Figure 4b is a longitudinal cross-sectional view of Figure 4a, The capstone removal device is provided with conductive wires 20 on both sides of a pipe 10 through which a fluid such as water flows, and a power supply device (not shown) with a control box 30 interposed between the conductive wires 20. Is connected, and by controlling the current applied to the conductive wire 20 through the control box 30 to form a magnetic field in the pipe can be removed to remove the capstone.

Since the installation direction of the conductive wire 20 is not wound in the circumferential direction of the pipe 10, but the winding direction is formed in a predetermined angle with the longitudinal direction or the longitudinal direction of the pipe 10, the direction of the magnetic field is the pipe 10. ) Is always perpendicular to the longitudinal direction, and the magnetic field and the flow direction of the ion can be perpendicular (θ = 90 °) no matter what shape the pipe 10 cross section.

Therefore, since the flow of ions passing through the portion of the conductive wire 20 is always perpendicular to the direction of the magnetic field, the ions are subjected to the maximum Lorentz force, and may be forced even without microscopic fluctuations at a speed below the limit value. It becomes a state.

Here, the conductive wire 20 can adjust the strength of the magnetic field by adjusting the number of installation according to the size of the pipe 10, the shape can be varied, but it is preferable to have a spiral spring shape. .

In order to test the effect of the capstone removal apparatus according to the present invention was carried out for the round tube.

Solid particulates of CaCl ₂ and NaHCO ₃ were dissolved in water and used in order to make the condition that the capstone could be formed within a short time, respectively, for the conventional method, the method of the present invention, and when the conductor 20 was not installed. As a result, the speed obtained without the effect of removing the capstone was obtained by the conventional method, which is about 1010 when calculated as the Reynolds Number, a dimensionless number commonly used in the pipe 10 flow. FIG. 5 is a graph showing the pressure difference (ΔP) between the inlet and outlet when measured in three ways with Reynolds number 1010 (Re = 1010, laminar flow conditions). The pressure required to flow water from the inlet to the outlet of the pipe 10 increases as the resistance in the pipe increases, so the flow must overcome this resistance, so the relative pressure difference between the inlet and the outlet increases. From this point of view, the capstone attached to the wall can be expressed as a resistance to flow. At Reynolds number 1010 it can be seen that the pressure difference [Delta] P is nearly the same when there is no conductor 20 as in the conventional method. That is, it can be seen that there is no effect of removing the capstone. However, according to the present invention it can be seen that the pressure difference is about 17% smaller than the conventional method. That is, since the amount of capstone attached to the wall of the pipe becomes smaller (resistance becomes smaller), water can be flowed at a relatively smaller pressure than in the prior art. FIG. 6 is a graph showing experimental results on heat transfer performance. The effect is shown by the heat transfer coefficient (U). As the capstone on the wall interferes with the effective heat transfer, the more the capstone, the lower the heat transfer coefficient. As with the experimental results for the pressure difference, the conventional method is not effective at the speed below the limit, while the apparatus of the present invention It can be seen that the heat transfer coefficient is higher than that of the conventional method. That is, it can be seen that the heat transfer performance is improved. FIG. 7 is a graph showing the pressure difference between the inlet and the outlet measured when the three methods were tested for 1650, which is higher than the case of Reynolds in FIG. As a graph showing the results of the heat transfer performance, it can be seen that the removal of the capstone is better than that of the Reynolds number 1010. That is, the Reynolds number 1650 shows that the removal of the capstone is also achieved by the conventional method. However, the use of the device of the present invention shows that the force of Lorentz is greater than that of the conventional method, thereby increasing the capstone removal effect. From these experimental results, it can be seen that in the flow range where the conventional method is effective, the capstone removal effect of the apparatus of the present invention is further increased, and the capstone removal effect is excellent even in the flow range in which the conventional method does not exhibit the capstone removal effect. The present invention is not limited to the above embodiments, and various modifications can be made within the scope of the technical idea of the present invention.

According to the capstone removal apparatus of the present invention made as described above, the direction of the flow of ions contained in the flow fluid in the pipe and the direction of the magnetic field is perpendicular to each other, thereby maximizing the Lorentz force received by the ions in the magnetic field, the conventional method Compared with this, the capstone removal effect is increased and the formation of capstone can be effectively suppressed or removed even in laminar flow below the limit speed.

Claims (2)

In the capillary removal apparatus, in which a conducting wire 20 is installed in a pipe 10 through which a fluid flows, a current is applied to the conducting wire 20 to form a magnetic field, and the capstone attached to the inside of the pipe is removed by the magnetic field. A power supply for applying a current; And Consists of a wire wound in a circular or polygonal shape, is installed in the saddle shape on the outer surface of the pipe to remove the capstone, when the current is applied through the power supply device perpendicular to the flow direction of the fluid flowing through the pipe Capstone removal apparatus using a magnetic field, characterized in that consisting of a magnetic field forming means for forming a magnetic field. The apparatus of claim 1, wherein the conductor is wound in the form of a spiral spring.