JPS5892438A - Electromagnetic filter - Google Patents

Abstract

PURPOSE:To attain to prevent the leakage of a filter element, by inserting a wedge wire element between a filter element at a condensed water outflow side and a support grid. CONSTITUTION:In a wedge wire element 18 provided between a filter element 13 and a support grid 14 in the downstream side of said filter element 13, at least a distance (d) between wedge wires 19 is adjusted to about 30-50mum because the diameter of the filter element is about 30-50mum. In addition, when the fine wire diameter of the filter element is 8-350mum in a ribbon form, the slit width of the wedge wire element 18 secures at least 8-350mum to prevent the outflow of the filter element perfectly.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an electromagnetic filter, and particularly to an electromagnetic filter used as a condensate purification treatment device in a nuclear power plant.

First, the role of electromagnetic filters in nuclear power plants.
This will be explained using figures. Figure 1 shows an overview of the primary system of a boiling water nuclear power plant. Nuclear pressure vessel 1
The steam generated in the main steam pipe 2 drives the turbine 3. This driving force is.

A generator connected to the turbine 3 is rotated to generate electricity. The steam exhaust from the turbine 3 becomes condensate in the main condenser 4,
It enters the condensate pump 6 via the condensate pipe 5.

A condensate filtration device 7 is installed on the outlet side of the condensate pump 6, which filters out insoluble corrosion products (crud) in the condensate.
etc. are removed. A condensate desalination device 8 is connected next to the condensate filtration device 7, and ionic impurities such as corrosion products and seawater are removed here. The purified condensate is sent to the feed water heater 10 by the condensate pressure boost pump 9 and heated, and then further pressurized by the feed water pump 11 to the reactor pressure vessel 1.
The turbine is operated by repeating the recirculation process. Here, the quality of the primary water of the atomic couplant mentioned above is as follows:
It is strictly controlled to prevent corrosion of piping and equipment, prevent damage to equipment due to corrosion products, and reduce radioactivity.

The condensate filtration device 7 is installed to capture crud in corrosion and corrosion-generated impurities, eliminate backwashing of the ion exchange resin in the condensate desalination device 8, and reduce the generation of radioactive waste. ing. A condensate pre-filter may be used as the condensate filtration device 7.

As a filter of this type, a powder ion exchange resin pre-coated type has been put into practical use. The cladding removal efficiency is as high as 95% or more.

However, this method has a problem in that ion exchange resin powder and Talarado sludge are generated as glycote auxiliary materials from the filter. As a method of eliminating the generation of filter sludge, electromagnetic filters are being used in place of powder resin precoated filters.

The electromagnetic filter has a structure as shown in FIG. Inside the electromagnetic filter container 12, a filter element 13 supported by a pair of support grids 14 arranged above and below is installed.

An electromagnet 15 is attached to the outer periphery of the container 12. The condensate flowing into the container 12 from the condensate inlet 16 passes through the filter tube 13.

At this time, when magnetic lines of force are generated in this portion by the electromagnet 15, the crud in the condensate is attracted to the filter element 13. Condensate drain with crud removed, condensate outlet 1
7 and enters the condensate demineralizer 8.

Next, the operating principle of the electromagnetic filter will be explained. The magnetic force F acting on the particles (cladding) during magnetic separation is expressed by the following equation.

d) ( F = V-X-H-... (1) d7゜ However, ■ is the particle volume, H is the strength of the magnetic field, and X is the body. In this equation (1), The shown magnetic force F causes the crud (particles) to be collected and adsorbed onto the filter element 13.The filter element 13 has a diameter of 8 to 35 mm.
It is preferable to randomly fill the wool with a ribbon-shaped cross section of 0 μm, for example, 5US430. Figure 3 shows the crud particle size and its concentration range in the condensate of boiling water type atomic couplant and iron ore wastewater. The crud in the condensate of the boiling water atomic couplant (a) is similar to the crud in the iron ore wastewater (b)
Lower concentration and smaller particle size. By the way, from equation (1), particles that are small, that is, particles with a small V, have a small magnetic force F and are difficult to be captured. As a countermeasure to this problem, it is possible to increase the strength H of the magnetic field, that is, to increase the strength of the electromagnet. However.

di(.In order to increase this magnetic gradient d7-, the radius of curvature of the magnetic pole of the filter element 13 can be made small. Such an electromagnetic filter is called a high gradient electromagnetic filter. This figure shows the relationship between the radius of the filter element 13 and the magnetic force.From this figure, it can be seen that in order to most effectively collect crud, the radius of the filter element 13 should be about three times the radius of the filter element 13. This means that the radius of the filter element needs to be made smaller when used for BWR condensate treatment with small particle sizes compared to iron ore with large particle sizes.
What is the particle size of the WR condensate cladding?

The radius of the filter element is 2 μm to 200 μm, and therefore, it is understood that the filter element having a radius of 10 μm to 350 μm can maximize the trapping force.

However, while this filter element is used for a long period of time, there is a concern that leakage may occur through the holes in the support grid 14, as shown in FIG. This is because a strong force is applied to the filter element 13 during the backwash operation to remove the collected crud, so the filter element 13 gradually deforms and breaks. If this filter element 13 leaks, it will be brought into the condensate demineralizer 8 or into the nuclear reactor if the demineralizer 8 downstream of the electromagnetic filter is operated. .

An object of the present invention is to provide an electromagnetic filter that takes measures to prevent leakage of a filter element.

The object of the invention is achieved by inserting a wedge wire element between the filter element and the support grid on the condensate outlet side. As described above, this wedge wire element is preferably a ribbon-shaped filter element having a fine wire diameter of 8 to 350 .mu.m, so if the slit is at least 8 to 350 .mu.m, outflow can be prevented.

An embodiment of the present invention will be described below with reference to FIGS. 6 and 7. FIG. 6 is a diagram showing an embodiment of a high gradient electromagnetic filter according to the present invention. A wedge wire element 18 is installed between the filter element 13 on the condensate outflow side and the support grid 14 to prevent leakage of the filter element.

FIG. 7 shows the detailed structure of the wedge wire element 18. As mentioned above, the diameter of the filter element 13 is
For example, the most efficient shape for BWR condensate is approximately 30~
Since it is 50 μm, in this case, leakage of the filter element 13 can be prevented at least by setting the distance d between the wedge wires 19 to 30 to 50 μm.

In addition, in cases other than the above, the element shape is 8 to 350 μm.
If the area in which the filter element is used is within the range m, the outflow can be prevented by providing a wedge wire having a slit of 8 to 350 μm.

According to the present invention, leakage of the filter element (DIIt) from the high-gradient electromagnetic filter due to the tearing phenomenon caused by dynamic vibration can be almost completely prevented, making it possible to extend the filter element replacement cycle.

Furthermore, the reliability of using a high gradient electromagnetic filter as a measure to reduce crud in condensate water is improved.

[Brief explanation of the drawing]

Figure 1 is a schematic diagram of a boiling water nuclear power plant, Figure 2 is a schematic diagram of a conventional high-gradient electromagnetic filter, and Figure 3 is a boiling water nuclear power plant. - Crud in secondary water and iron ore wastewater Figure 4 is a comparison diagram of the particle size and concentration of the cladding, and Figure 4 is a diagram of the relationship between the filter element diameter and magnetic force.
FIG. 5 is a schematic diagram of the filter element leaking from the support grid, FIG. 6 is a schematic diagram of a high gradient electromagnetic filter that is a preferred embodiment of the present invention, and FIG. 7 is the wedge wire of FIG. 6. It is an enlarged view of an element. 1... Nuclear pressure vessel, 4... Main condenser, 5...
Condensate pipe, 8... Condensate desalination device %10... Water supply heater, 12... High Figure 2 4m 0 0, Ib Ib tub
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Claims (1)

[Claims] 1. An electromagnetic filter having a container filled with a filter element and an electromagnet that excites the filter element from outside the container, characterized in that an outflow prevention element having a slit is provided downstream of the packed layer of the filter element. electromagnetic filter.