FI124913B - Gas filtration apparatus and method for manufacturing a gas filtration apparatus - Google Patents

Description

A gas filter device and a method of making a gas filter device.

The invention relates to a gas filter device according to the preamble of claim 1 and to a method of manufacturing a gas filter device according to the preamble of claim 5.

A gas filter device is known in the art, comprising a substantially gas-tight roof member and a base member of the frame structure, between which a plurality of planar filtering elements are arranged obliquely relative to the main gas flow direction, such that the filtering elements form wedge-closing parallel opening on the base and on the other hand the filtering elements. This type of gas filter device is known e.g. from US4129429.

WO 9420193 A1 discloses a known gas filtration device comprising a frame structure consisting of a substantially gas-tight ceiling and a base portion, between which are arranged planar filtration elements such that the filtration elements form a plurality of parallel-flowing outlets parallel to the outlet. wedge-shaped parallel spaces having adjacent filter elements interconnected in a gas flow direction with a first end portion extending from the first edge to the ceiling portion, and a second end portion having a second portion extending from the second portion to the roof portion, the width separating the filter elements of the first end portion.

Several devices that use air as a working material or in which air participates in the process carried out in the device place limits on the amount of impurities in the air used. For example, gas turbine installations where the unit is arranged to rotate at very high speeds are very sensitive to the presence of combustion air solids. This is also true for many other thermal power plants. Therefore, such devices typically have large combustion air filtration devices in which the airborne particles are removed as required.

Particularly when filtering large volumes of air flow, the importance of the pressure drop is significant, since the effect of the pressure drop on the efficiency is also significant. The pressure loss of the filter elements increases as impurities accumulate on the filter surface, whereby the force applied to the filter element also increases. Since the filter elements are only replaced at certain intervals, for example, when the pressure difference reaches a certain permissible upper limit, it is advantageous if the accumulation of impurities has a minimal effect on the pressure loss of the filter element.

On the other hand, the filter element must also withstand the additional force exerted by the increase in the pressure difference caused by the accumulation of impurities which is inevitably applied to the filter element during use. The thicker filter element is better able to withstand said additional force, but the problem may be increasing pressure drop.

It is an object of the invention to provide a gas filter for purifying hateful air from impurities which cause a lower pressure drop without substantially reducing the impurity resolution.

It is also an object of the invention to provide a method of making a gas filter device which provides a gas filter for purifying hate air from impurities which causes less pressure loss without substantially reducing impurity separation.

The above objects are mainly achieved by the solution set forth in claims 1 and 5.

Other additional features of the invention will be apparent from the appended claims and from the following description of embodiments of the figures.

According to a preferred embodiment of the invention, the gas filtering device comprises a substantially gas-tight roof part and a base part, between which planar filtering elements are arranged such that the filtering elements form a plurality of gently closing parallel spaces on the inlet side of the flowing gas and spaces, and adjacent filtering elements are interconnected by a first end portion extending from the first end edge to the base portion in a gas flow direction and a second end portion extending from the second end portion to a second end portion the width separating the filter elements, wherein the attachment of the filter elements to the frame structure and the end portions of the roof and base members is arranged to form a cohesive whole.

Such a gas filter device, wherein the separation distance between the filter elements at the second end portion is greater than at the first end portion, simultaneously achieves a relatively low pressure drop and yet improved rigidity to withstand the effect of the force exerted on the filter element due to the pressure difference.

According to a preferred embodiment, the width of the second end portion separating the filter elements is from 4 to 10% of the length of the filter element. In this way, the operation of the filter device is particularly advantageous. It is to be understood in this connection that the end portion is preferably wider than its width separating the filter elements, which defines the distance between the surfaces of the filter elements at the ends of the filter elements, since the end portion also functions in attaching the filter element.

Preferably, the filter element consists of a planar element formed by pleating of the filter material and having a thickness greater than 10% of the length of the filter element.

[0015] The filter device in the flow direction of the gas inlet side and the outlet side of the front faces, and the input side of the front surface portion of the first end portion of the covered surface area is smaller than the outlet side of the front surface portion of the second end portion of the area covered.

The invention also relates to a method for making a gas filter device, wherein a plurality of planar filtering elements are arranged between a substantially gas-tight roof part and the base part such that the filtering elements are arranged to form wedge-sealed parallel spaces on the inlet side of the flowing gas on the other hand, the filtering elements, wherein the filtering elements are arranged to form parallel spaces opening wedge-like on the outlet side of the flowing gas, and wherein the at least two adjacent filtering elements are interconnected connected to one another in the direction of flow of gas by the latter extending from one end of the roof to the bottom of the roof a end piece. In the method, the width separating the filter elements of the second end portion is arranged larger than the width separating the filter elements of the first end portion and the attachment of the filter elements to the frame structure and end portions of the roof and bottom portion is arranged.

Preferably, the two adjacent filter elements are connected to one another at a distance of 4-10% of the length of the filter element in the direction of flow of the gas at the other end.

In the following, the invention and its operation will be described with reference to the accompanying schematic drawings, in which Figure 1 schematically illustrates an embodiment of a gas filter device according to the invention, Figure 2 illustrates a gas filter device

Figures 1 and 2 schematically show a gas filtration device 10 according to a preferred embodiment of the invention, with Figure 1 showing a cross-sectional view of the gas filtration device I-1 and Figure 2 showing the gas filtration device of Figure 1 in front of it. The gas filtration apparatus disclosed herein is particularly an air filtration apparatus which is particularly suitable for filtering the combustion air of a gas turbine unit. Hereinafter, the gas filtration device 10 will be referred to as an air filtration device.

The air filtration device 10 comprises a frame structure 12 which is formed e.g. the roof part 12 'and the base part 12'. Plane filter elements 14 are provided in connection with the frame structure. The number of filter elements 14 may vary according to the application.

The filtering elements 14 are planar rectangular and are obtained by pleating a filter mat or the like into a so-called pleat stack. In this way, the filtration area of the pleat pack increases. At the same time, its thickness increases, which stiffens the structure and improves its ability to absorb the force caused by the differential pressure generated in use. The filtering elements are substantially the same size. The thickness s of the filtering element 14 is determined by many factors such as the allowable pressure drop and the required filtering capacity.

The filter elements are fixed on two opposite sides to the roof portion 12 "and the base portion 12 'so that the direction of the filter elements 14' deviates from the main longitudinal direction 12 '" of the frame structure in different directions.

The filtering elements 14 provide wedge-shaped spaces 20 on the inlet side 16 of the hating gas, which are bounded by both the roof portion 12 'and the base portion. The closure space 20 is delimited by two filter elements 14. In the gas flow direction of the filtering elements 14 to the other side, the outlet side 18, parallel spaces 22 which open in a wedge-like manner are formed.

Except for the outermost filter elements of the filter device 10, each of the two adjacent filter elements is interconnected in a gas flow direction from the first edge 14.1 by a first end portion 24. The first end portion extends between the roof portion 12 'and the bottom portion 12'.

Similarly, two adjacent filter elements of the filter device 10 are connected to one another in a gas flow direction from one edge 14.2 by a second end portion 26. Also, the other end portion extends between the roof portion 12 'and the base portion 12' so that the filter elements are substantially gas tight. In practice, the attachment of the filter elements to the frame structure 12 and the end portions is preferably made by gluing, whereby the filter device forms an integral unit. Both the first and second end portions are substantially gas-tight and their connection to the filter elements is substantially gas-tight.

The width L26 separating the filter elements of the second end portion is larger than the width I224 of the filter elements separating the first end portion. This affects the flow characteristics of the closure space 20 and the filter element 14, reducing the pressure drop. In this case, the thickness s of the filter element can be chosen sufficiently large without causing excessive pressure differential increase over the filter device. Preferably, the width L26 separating the filter elements of the second end portion is defined relative to the length Lu of the filter element. Preferably, the width L26 is 4 to 10% of the length of the filter element. By providing a width L26 separating the filter elements of the second end portion thus wider than the width separating the filter elements of the first end portion, the thickness of the filter element can be increased to provide greater rigidity without increasing excess pressure.

Figure 3 shows a test example of the operation of a gas filter device according to the invention. Figure 4 shows the velocity (m / s) of air passing through the filter device on the horizontal axis and the pressure drop on the vertical axis. Reference numeral 40 denotes measurement results for a prior art gas filter device. Reference numeral 42 shows the measurement results for a filter element otherwise structurally prior art, with the difference that reference numeral 40 shows that the filter element has a thickness of about twice. The figure clearly shows the increase in the thickness of the filter element as the pressure difference between the measuring sets 40, 42 increases.

Reference numeral 41 denotes measurement results for a gas filter apparatus according to an embodiment of the invention, wherein the filter element has the same thickness as the filtering apparatus 42 which measures the second end portion separating the filter elements L2 from the first end portion. In the filter element providing the measuring set 41, the width separating the filter elements of the other end portion is about 5% of the length of the filter element.

Reference numeral 41 'shows the measurement results for a gas filter apparatus according to one embodiment, wherein the width L26 separating the filter elements of the other end portion is about 12% of the length of the filter element. In order that the effects of the invention are most advantageous, the width separating the filter elements at the other end of the filter element is 4-10% of the length Lu of the filter element.

In the practical tests depicted in Figure 3, it has been found that the width separating the filter elements of the other end portion is preferably from about 20 mm to about 40 mm.

It should be noted that only some of the most preferred embodiments of the invention have been described above. Thus, it is to be understood that the invention is not limited to the above embodiments, but can be applied in many ways within the scope defined by the appended claims. The features disclosed in various embodiments may also be used within the scope of the present invention in conjunction with other embodiments, and / or combinations of features other than those disclosed, if desired and technically feasible.

Claims (6)

A gas filter device comprising a frame structure (12) comprising a substantially gas-tight roof portion (12 ') and a base portion (12') between which are arranged planar filtration elements (14) such that the filtration elements provide a plurality of flowing gas inlet wedge-closing parallel spaces (20) and a plurality of parallel-opening parallel spaces (22) on the outlet side of the flowing gas, and wherein adjacent filter elements (14) are interconnected in the gas flow direction from the first edge portion of the roof portion (12 ”) a first end portion (24), and a second end portion (26) extending from the second end portion to the bottom portion (26), and having a width (26_2β) separating the filter elements (14) from the second end portion greater than the width (L24) ), characterized in that the filter data elements the attachment to the roof portion (12 ') and the base portion (12') and the end portions (24,26) of the frame structure (12) is arranged by gluing the filter device as a unit. Gas filter device according to Claim 1, characterized in that the filter element (14) consists of a planar element obtained by pleating the filter material, the thickness (S) of which is greater than 10% of the length (Lu) of the filter element. 3. The gas filtering device according to any one of the preceding claims, characterized in that the filter device has a gas flow direction from the inlet side (16) and an outlet side (18) end surfaces, and the input side of the front surface of the first end portion (24) to cover the area percentage is smaller than the outlet side of the front surface of the second end portion (26 ). Gas filter element according to one of the preceding claims, characterized in that the width of the second end portion (26) separating the filter elements is about 4 to 10% of the length (Lu) of the filter element. A method of making a gas filter device, comprising: arranging a plurality of planar filtration elements (14) between a substantially gas-tight roof portion (12 ') and a base portion (12') such that the filtration elements are arranged to form wedge-closable parallel spaces (20) bordering the roof and base members on the one hand and the filtering elements on the other hand, wherein the filtering elements (14) are arranged to form parallel spaces (22) opening wedge-like on the outlet side of the flowing gas, and wherein at least two adjacent filtering elements (14) at a first end portion (24) extending from the first edge portion (14.1) of the gas in the direction of gas flow, at least two adjacent filtering elements are connected to each other in the gas flow direction of the latter portion of the roof (14.2); a second end portion (26) extending to the bottom portion, the second end portion (26) separating the filter element width (Ι_2β) greater than the first end portion (24) filter element separating width (L24), characterized in that the filter elements are glued to the frame structure (12) to the roof section (12 ”) and the base section (12’) and the end sections (24.26) to form an integral whole. Method according to Claim 5, characterized in that the two adjacent filter elements (14) are connected to one another in a gas flow direction at a distance of 4-10% of the length (Lu) of the filter element at one end (14.2).