JPH0513377Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Field of Application] This invention mainly relates to an air supply filter device for preventing clogging of dust in the air supply system of a burner or the like mounted on a boiler.

[Conventional technology]

Normally, when air is supplied to combustion equipment such as a burner installed in a boiler, the dirt and dust contained in the combustion air sent to the burner from the blower burns out along with the fuel, so this is not a problem. No. However, in ceramic burners that use ceramic particles, the gap through which the combustion gas mixture (fuel + combustion air) passes is very narrow, and dirt and dust in the combustion air can adhere and accumulate between the ceramic particles. It tends to get clogged with dirt.
As a result, not only can the burner's combustion performance drop significantly in a short period of time or cause misfires, but once clogged with debris, it takes a lot of effort to remove and clean the burner, and in some cases, Eventually, the entire ceramic burner will have to be replaced.

In addition, various proposals have been made for using various filter members to collect dirt and dust in the combustion air, but these collection filter members have only a very limited collection function. The collection function area is not fully utilized, and the collection filter member is required to be frequently cleaned and cleaned. As a result, it is not very effective in maintaining the combustion performance of the burner.

[Purpose and outline of the invention]

Therefore, in order to solve the above-mentioned problems, this idea was developed by installing a new air supply filter device to collect dirt and dust in the combustion air and prevent it from adhering to combustion equipment such as burners. , it is possible to prevent deposition, and furthermore, it is possible to fully utilize the collection function area of the filter member used here.

That is, this invention comprises a blower unit equipped with an air supply duct and a fan casing connected to the air supply duct, and the combustion air is formed in the front wall of the air supply duct and the fan casing. In the configuration in which air is supplied to the combustion device through the suction port and the fan in the fan casing, a first
A filter member is attached, an air volume adjustment plate for adjusting the opening of the suction port is attached to the front wall, and the first filter is installed between the first filter member and the air volume adjustment plate in the air supply duct. A second filter member that is denser than the air supply duct is attached, a detection space defined by the peripheral side wall of the air supply duct is formed between the second filter member and the front wall, and the detection space is defined by the peripheral side wall of the air supply duct. It is characterized by a wind pressure detection mechanism installed in the space.

〔Example〕

Hereinafter, specific embodiments of this invention will be described in detail based on the drawings.

The air supply duct 1 formed in a substantially cylindrical shape includes a fan casing 13 and a fan casing 13.
A motor 14 fixed to the motor 14 and a fan 1 in the fan casing 13 connected to the shaft of the motor 14.
5, and is connected to the suction port 11 side formed in the front wall 13a of the fan casing 13 via an appropriate connection means. Therefore, combustion air is supplied to the air supply duct 1, the suction port 11 formed in the front wall 13a of the fan casing 13, and the fan casing 1.
Air is supplied to the combustion equipment through a fan 15 in the combustion equipment 3.

A first filter member 3a is attached to the inlet of the air supply duct 1 on the suction side so as to cover the inlet from the outside. The first filter member 3a is fitted onto the outer surface of the peripheral wall 1a of the air supply duct 1 to cover the inlet,
It has a flat dome shape with a cylindrical portion, and a mesh of an appropriate size is formed over its entire surface. Therefore, the first mesh of an appropriate size
Since the filter member 3a also has a flat dome-shaped cylindrical portion as a collection function surface, its collection function area as a whole is larger than the inner diameter cross-sectional area of the air supply duct 1, and its collection function is It can be fully demonstrated over a long period of time.

The front wall 13a of the fan casing 13 includes:
An air volume adjustment plate 10 that adjusts the opening degree of the suction port 11 to adjust the intake amount of combustion air passing therethrough.
is installed. This air volume adjustment plate 10 is
It is rotatably supported by a set screw 12 on the front wall 13a. This makes it possible to adjust the amount of combustion air supplied.

In the air supply duct 1, an appropriate distance is maintained between the first filter member 3a and the air volume adjustment plate 10, and an appropriate distance is maintained between the first filter member 3a and the air volume adjustment plate 10. A second filter member 3b which is also dense is attached. This second filter member 3b is fixedly attached by a pair of locking pieces 7, 7' provided on the inner peripheral surface of the peripheral side wall 1a of the air supply duct 1. A specific example of the second filter member 3b is shown in FIGS. 3 and 4, and the second filter member 3b is designed to be denser than the first filter member 3a. 1
It consists of a net-like member 5 with a mesh of an appropriate size smaller than the mesh of the filter member 3a and a fiber aggregate 6 of polyester or the like with an appropriate thickness, and these are overlapped and integrally constructed by a support frame 16. It has a two-layer structure. When the second filter member 3b having such a configuration is installed in the air supply duct 1, it is installed so that the mesh member 5 is located on the upstream side, that is, on the side of the first filter member 3a. Therefore, the combustion air passing through the air supply duct 1 passes through the first filter member 3a.
Then, it passes through this second filter member 3b in sequence.

A detection space 19 defined by the peripheral wall 1a of the air supply duct 1 is formed between the second filter member 3b and the front wall 13a of the fan casing 13. This detection space 19
is for efficiently utilizing the collection function area of the second filter member 3b, and maintains a volume of an appropriate size according to the surface area of the second filter member 3b. The filter member 3b and the front wall 13a are connected to the air supply duct 1.
The peripheral side wall 1a is spaced appropriately in the longitudinal direction.
The image is shaped by Therefore, the suction force of the fan 15 in the fan casing 13 is applied not only to the second filter member 3b in the portion corresponding to the suction port 11 formed in the front wall 13a, but also to the entire surface of the second filter member 3b. Therefore, the entire collection function area of the second filter member 3b is utilized.

A wind pressure detection mechanism 4 is provided in the detection space 19.
is provided. This wind pressure detection mechanism 4 detects the internal pressure in the detection space 19, and is provided with a pressure detection port 8 in the circumferential wall 1a, and is connected to the pressure detection port 8 via a connecting pipe 9. Therefore, by detecting the internal pressure in the detection space 19, it is possible to detect the regeneration timing of the second filter member 3b. In addition, in implementation, a display function and an alarm function can be added to the wind pressure detection mechanism 4, and if these are added, it will be even more effective.

Further, the wind pressure detection mechanism 4 includes the suction port 1
In order to avoid the influence of biased flow, eddy current, pulsating flow, etc. caused by the suction of the combustion air passing through the fan 15 and to perform reliable detection, as in the illustrated embodiment, a An effective configuration is to provide the circumferential wall portion on the opposite side (the lower portion in FIG. 2) to the circumferential wall portion on the opposite side (the upper portion in FIG. 2).

Next, the operation of this invention will be explained. In use, the fan 15 is powered by the motor 14.
is rotated to draw combustion air into the fan casing 13 from the suction port 11. At this time, the first filter member 3a attached to the inlet on the suction side of the air supply duct 1 removes large dust (for example, fibrous dust) contained in the combustion air, and then 2nd installed inside 1
The filter member 3b removes finer dirt, dust, etc. contained in the combustion air in stages. At that time, fibrous dust that could not be removed by the first filter member 3a is removed by the mesh member 5 of the second filter member 3b, and fine dust and dirt are removed by the fiber aggregate formed integrally with the mesh member 5. Remove by body 6. In other words, since three types of filter members are provided to remove dirt and dust contained in the combustion air in three stages, clean combustion air can always be supplied. Thereafter, clean combustion air from which dirt, dust, etc. have been removed is supplied from the discharge port 18 of the fan casing 13 to a burner section (not shown), which is a combustion device, as indicated by the arrow 17 in FIG.

When the combustion air passes through the second filter member 3b in the air supply duct 1, the second
Since the detection space 19 is formed on the downstream side of the filter member 3b, the detection space 19 does not pass through the second filter member 3b in a concentrated manner, but is almost uniform over the entire area of the second filter member 3b. Therefore, the collection function area of the second filter member 3b is fully utilized.

When implementing the filter device of this invention, it is desirable that the initial flow resistance (pressure loss) of the second filter member 3b is 4 mmAq or less at a predetermined air volume; if the flow resistance is too high,
It is necessary to increase the capacity of the motor 14 of the blower unit 2, which increases costs and increases the size of the entire device. The appropriate time to regenerate the second filter member 3b is when the flow resistance reaches approximately 10 mmAq;
The wind pressure detection mechanism 4 detects the internal pressure in the detection space 19 formed on the downstream side of the wind pressure detection mechanism 4 .

[Effect of idea]

Since this invention has the above-mentioned structural features, the following effects can be obtained.

By removing dirt, dust, etc. contained in the combustion air in stages, it is possible to significantly reduce the adhesion and accumulation of dirt, dust, etc. on the burner head, etc. As a result, the life of combustion equipment such as burners can be extended, and its combustion performance can be maintained in a stable state over a long period of time, and it can be put to practical use even in dusty environments. . In particular, by forming the detection space in the air supply duct, the collection function part of the second filter member is not concentrated in a very limited area, and the collection function area covers the entire area. It can be fully utilized and has an exceptional effect on maintaining the combustion performance of burners, etc.

In addition, a first filter member which is a main component,
Since the second filter member, the detection space, and the wind pressure detection mechanism are attached to or formed in the air supply duct, the structure is extremely simple and is extremely effective in making the blower more compact.

Furthermore, regarding inspection and maintenance, according to this invention, it can be easily washed with water and can be recycled many times.

[Brief explanation of the drawing]

The drawings show one embodiment of this invention; FIG. 1 is a front view of a blower equipped with a supply air filter device according to this invention, FIG. 2 is a sectional view taken along line A-A in FIG. 1, and FIG. FIG. 3 is a plan view of the second filter member;
FIG. 4 is a longitudinal sectional view of the second filter member. 1...Air supply duct, 1a...Surrounding wall, 2...
Air blower unit, 3a...first filter member, 3
b... Second filter member, 4... Wind pressure detection mechanism, 5... Net member, 6... Fiber aggregate, 10...
...Air volume adjustment plate, 11...Suction port, 13...Fan casing, 13a...Front wall, 15...Fan, 19...Detection space.

Claims (1)

[Scope of utility model registration request] A blower unit 2 is provided with an air supply duct 1 and a fan casing 13 connected to the air supply duct 1, and combustion air is formed in the air supply duct 1 and the front wall 13a of the fan casing 13. In the configuration in which air is supplied to the combustion apparatus through the suction port 11 and the fan 15 in the fan casing 13, a first filter member 3a is attached to the inlet of the air supply duct 1 to cover the inlet from the outside, An air volume adjustment plate 10 for adjusting the opening of the suction port 11 is attached to the front wall 13a, and the air supply duct 1
A second filter member 3b, which is denser than the first filter member 3a, is installed between the first filter member 3a and the air volume adjustment plate 10, and the second filter member 3b and the front wall 13a are A detection space 19 defined by the peripheral side wall 1a of the air supply duct 1 is formed between the detection spaces 19 and 19.
A filter device for supply air of a boiler, etc., characterized in that it is provided with a wind pressure detection mechanism 4.