JPH0341766Y2 - - Google Patents

Description

[Detailed Description of the Invention] (Field of Industrial Application) The present invention relates to a ceramic filter purifying device that removes deposits on the surface of a cylindrical ceramic filter to recover from clogging. The present invention relates to a ceramic filter purifying device suitable for purifying ceramic filters used for filtering exhaust gas.

(Prior art) When ceramic filters conventionally used to filter exhaust gas containing radioactive gases become clogged, workers wearing radiation protection equipment can The work involved manual brushing to remove surface deposits. However, this method creates an extremely poor working environment, and the brushing causes deposits on the filter surface to get inside the filter, making it difficult to fully recover from clogging.Additionally, in order to measure the state of clogging, the measuring device must be equipped with ceramics. There were many problems such as poor work efficiency because the filter had to be set.

(Problems to be solved by the invention) The present invention solves the above-mentioned conventional problems and sufficiently removes surface deposits without the operator coming into contact with the dust scattered from the filter surface. It was completed with the aim of creating a ceramic filter purifying device that can easily measure the clogging state.

(Means for Solving the Problems) The present invention includes a filter holder for holding both the upper and lower ends of a cylindrical ceramic filter and rotating it around the axis of the ceramic filter inside an airtight box; The filter holder is provided with a rotating brush mechanism that removes deposits on the outer surface of the ceramic filter while moving in the axial direction of the wire brush along the ceramic filter held by the filter holder. It is characterized by being equipped with a nozzle that can be inserted into the air.

(Examples) Next, the present invention will be explained in more detail with reference to illustrated examples.

In the figure, 1 is a vertical cylindrical airtight box made of a suitable material such as transparent plastic or glass.
An exhaust port 2 communicating with the dust collector is provided at the bottom, and a ceramic filter 3 is installed on the side of the exhaust port 2.
An airtight door (not shown) is provided for taking the 0 in and out. 3 and 4 are this airtight box 1
This is a filter holder installed inside the filter. The lower filter holder 3 is shaped to be able to receive the bottom of a ceramic filter 30 in the form of an elongated bottomed cylinder, and is provided with a motor 5 for rotating the ceramic filter at its lower part. The upper filter holder 4 has a rotatable tapered part 6 that is inserted into the open end of the ceramic filter 30, and has a structure in which it is raised and lowered via a link 8 by operating the handle 7 to hold the open end of the ceramic filter 30. It is becoming. With the above structure, the filter holder 3,
4 holds both the upper and lower ends of the ceramic filter 30, and can also rotate the ceramic filter 30 around its axis by the action of the ceramic filter rotation motor 5. Furthermore, two guide bars 9, 9 are fixed inside the airtight box 1 in parallel with the axis of the ceramic filter 30, and the rotary brush mechanism 10 is structured so as to be able to move along these guide bars 9, 9. It's summery. That is, the rotating brush mechanism 10 includes a frame 11 having sliding parts with guide bars 9, 9, a wire brush 13 rotated by a motor 12, and a wire brush 13 that is rotated horizontally toward the ceramic filter 30. The guide bar 9 is made up of a rotor 14 with a link 15 for pressing the airtight box 1 in the direction shown in FIG. , 9 can be moved up and down. Further, the rotating brush mechanism 10 is rotated while the end face of the wire brush 13 is pressed against the outer surface of the ceramic filter 30, so that deposits on the surface can be removed.

If the outer surface of the ceramic filter 30 is rubbed with the wire brush 13 in this way, there is a risk that the deposits on the surface will enter the inside of the ceramic filter 30. Therefore, in the present invention, the upper filter holder 4 is provided with the ceramic filter 30. A nozzle 18 is provided for blowing compressed air into the interior. Compressed air is blown into the nozzle 18 through a pipe 19, and this compressed air flows from the inside of the ceramic filter 30 to the outside and serves as air for backwashing surface deposits. In this case, compressed air may be introduced from either side of the filter holders 3, 4. Further, in this embodiment, the air pressure taken out by the detection end 20 of the pipe 19 and the detection end 21 of the side wall of the airtight box 1 is measured by the differential pressure gauge 22, and the ceramic filter 30
Measure the pressure loss passing through the ceramic filter 30.
It is now possible to know the recovery status of clogging. Note that 23 is a flow meter, and 24 is a V-shaped bottom plate.

(Function) In this structure, both the upper and lower ends of the clogged ceramic filter 30 are held by the filter holders 3 and 4 in the airtight box 1 and rotated, and the rotating brush mechanism 10 is rotated by the ceramic filter 30. When the wire brush 13 is rotated while moving along the filter 30, the wire brush 13 is rotated while being pressed against the outer surface of the ceramic filter 30 with an appropriate force by the rotor 14, thereby removing the surface deposits. It is something that can be done. At the same time, if compressed air is supplied to the inside of the ceramic filter 30 from the nozzle 18 provided on the upper filter holder 4, the separated surface deposits will be pushed out by the air flow flowing from the inside to the outside. The ceramic filter 30 is sufficiently purified without any intrusion into the interior. Since all such work is carried out inside the airtight box 1, there is no risk of dust scattering or of the worker coming into contact with dust. Furthermore, since the ceramic filter 30 is sealed inside the airtight box 1, by measuring the differential pressure between the air pressure on the nozzle 18 side and the air pressure inside the airtight box 1, the clogging state of the ceramic filter 30 can be determined by the passing pressure. This can be easily recognized as a loss, and the filter cleaning work can be performed more efficiently.

(Effects of the invention) As is clear from the above explanation, the present invention is capable of sufficiently removing deposits on the surface of a ceramic filter without the operator coming into contact with the dust scattered from the surface of the ceramic filter. There is, and the removal work is based on mechanical stripping action by a rotating brush mechanism and backwashing action by compressed air blown through a nozzle.
Even severely clogged ceramic filters can be completely purified. Moreover, since the clogging state of the ceramic filter can be easily measured in the same state, the work efficiency is significantly improved. As described above, the present invention is particularly suitable for regenerating ceramic filters for purifying exhaust gas containing radioactive dust, but it can also be used for regenerating a wide range of general ceramic filters, and its practical value is extremely high. It is something.

[Brief explanation of the drawing]

The drawing is a partially cutaway perspective view showing an embodiment of the present invention. 1: Airtight box, 3, 4: Filter holder,
10: Rotating brush mechanism, 13: Wire brush,
18: Nozzle, 30: Ceramic filter.

Claims (1)

[Scope of utility model registration request] Inside the airtight box 1, there are filter holders 3 and 4 that hold both the upper and lower ends of a cylindrical ceramic filter 30 and rotate it around the axis of the ceramic filter 30, and a filter holder 30 that is held by the filter holders 3 and 4. A rotary brush mechanism 10 is provided that moves along the ceramic filter 30 in the axial direction of the wire brush 13 and removes deposits on the outer surface of the wire brush 13. A ceramic filter purifying device characterized by being provided with a blowing nozzle 18.