KR102652573B1 - Pipe filter for vessel - Google Patents

Abstract

A marine piping filter is disclosed. According to one embodiment of the present invention, a marine piping filter installed between pipes, comprising: a mesh net that filters foreign substances in the fluid; A perforated plate in the shape of a sheet material with a plurality of through holes formed thereon; and a filter flange that has a predetermined width and is installed on the circumferential surface of the mesh net and the perforated plate, and is fastened to correspond to the flanges of the pipes, wherein the mesh net is disposed upstream of the fluid and the perforated plate is disposed downstream of the fluid. A piping filter for ships that is installed in an arranged manner is provided.

Description

Pipe filter for vessel {Pipe filter for vessel}

The present invention relates to a piping filter for ships.

Ships are large structures and are built by dividing them into blocks. Steel materials such as iron plates are processed to fit the shape of the part of the hull where the blocks will be mounted, and they are combined at a small assembly plant. Then, the ship blocks are completed at the large assembly plant, and the completed ship blocks are moved to the dock and finally assembled into ships.

Each ship block is designed with pipes installed inside to transport various fluids such as purified water, sewage, and fuel, and these pipes are also connected to each other during the assembly process of the ship blocks.

Pipe filters may be installed in these pipes to filter out foreign substances in addition to fluid.

Figure 1 is a diagram showing a pipe filter installed in a pipe joint.

Referring to FIG. 1, a pipe filter 20 is installed between the first pipe 11 and the second pipe 12 at a point where they are joined.

This pipe filter 20 is formed in a cone shape to maximize the flow of fluid flowing from the first pipe 11 to the second pipe 12 while expanding the contact area with the fluid to effectively filter out foreign substances. It is done.

In the case of filters, after a certain period of time, the filtering effect is reduced due to filtered foreign substances, so replacement is required. In this case, the pipe filter 20 shown in FIG. 1 has the disadvantage of having to separate the pipe filter 20 after removing the second pipe 12.

In addition, there is a problem in that the cone-shaped pipe filter 20 cannot be used in the curved pipe 13 type shown at the bottom of FIG. 1 due to interference.

Korean Patent Publication No. 10-2016-0074884 (published on June 29, 2016) - Cone filter type harmful microorganism removal device

The present invention is intended to provide a marine piping filter that can be easily installed and removed at the joining point between pipes and can be applied regardless of the type of pipe such as a curved pipe.

The present invention is intended to provide a marine piping filter that can be expanded according to the piping diameter at the installation point, enabling adaptive installation and filtering.

Other objects of the present invention may be easily understood through the following description.

According to one aspect of the present invention, a marine piping filter installed between pipes, comprising: a mesh net that filters foreign substances in the fluid; A perforated plate in the shape of a sheet material with a plurality of through holes formed thereon; and a filter flange that has a predetermined width and is installed on the circumferential surface of the mesh net and the perforated plate, and is fastened to correspond to the flanges of the pipes, wherein the mesh net is disposed upstream of the fluid and the perforated plate is disposed downstream of the fluid. A piping filter for ships that is installed in an arranged manner is provided.

The internal space can be opened and closed, and a perforated filter with the filter flange fastened to the circumferential surface of the mesh net and the perforated plate is inserted into the mesh net and the perforated plate with the internal space open, and the perforated filter is inserted into the perforated filter with the internal space closed. It may further include a first expansion member that holds the peripheral surface.

The first extension member is rotatably coupled around a hinge and may include a first gripper and a second gripper having a semicircular ring structure.

One of the fitting groove and the fitting protrusion is formed on one of the inner surfaces of the first gripper and the second gripper and the outer surface of the perforated filter, and the other one of the fitting groove and the fitting protrusion is formed on the other, so that they are mutually fitted. can do.

or a second expansion member, which is a ring structure having a through hole corresponding to a perforated filter in which the filter flange is fastened to a circumferential surface of the mesh net and the perforated plate; And it may further include an O-ring interposed between the outer surface of the perforated filter and the inner surface of the second expansion member.

Other aspects, features and advantages in addition to those described above will become apparent from the following drawings, claims and detailed description of the invention.

According to an embodiment of the present invention, it can be easily installed and removed at the joining point between pipes, and can be applied regardless of the type of pipe such as a curved pipe.

In addition, it can be expanded according to the pipe diameter at the installation point, which has the effect of enabling adaptive installation and filtering.

1 is a diagram showing a pipe filter installed at a pipe joint;
Figure 2 is a view showing a marine piping filter and installation according to an embodiment of the present invention;
Figure 3 is a diagram showing the configuration and manufacturing of a first expanded pipe filter according to another embodiment of the present invention;
Figure 4 is a cross-sectional view taken along line AA of Figure 3;
Figure 5 is a diagram showing the configuration and manufacturing of a second expanded pipe filter according to another embodiment of the present invention.

Since the present invention can make various changes and have various embodiments, specific embodiments will be illustrated in the drawings and described in detail in the detailed description. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all changes, equivalents, and substitutes included in the spirit and technical scope of the present invention.

Figure 2 is a diagram showing a marine piping filter and installation according to an embodiment of the present invention.

The marine piping filter 100 according to an embodiment of the present invention has a flat structure and can be installed by simply pushing it into the gap between the joints between the pipes without removing the pipes at the installation point, and can be removed later. It is characterized in that it can be easily removed by pushing it out from the gap between the joints.

Referring to FIG. 2, the marine piping filter 100 according to this embodiment is a two-layer filter including a mesh network 130 and a perforated plate 110.

The pipe filter 100 is made up of a plurality of meshes having a predetermined size, a mesh network 130 that filters foreign substances contained in the fluid flowing along the pipe, and a plurality of penetrations into a plate having a shape corresponding to the shape of the pipe. It includes a perforated plate 110 in which a ball is formed, and a filter flange 120 formed to have a predetermined width around the perforated plate 110 and the mesh network 130.

The filter flange 120 is a part corresponding to the piping flanges of the first pipe 11 and the second pipe 12 disposed on both sides of the point where the filter is to be installed, and is sandwiched between the piping flanges on both sides, and is screwed. -The piping filter 100 is firmly fastened with a nut, etc.

The perforated plate 110 and the mesh network 130 are installed in the filter flange 120 in a stacked structure.

Assuming that the flow of fluid is in the direction from the first pipe 11 to the second pipe 12, the mesh network 130 is disposed toward the first pipe 11 (upstream of the fluid) and the second pipe 11 The perforated plate 110 may be placed on the (12) side (downstream of the fluid).

That is, in view F of FIG. 2, the mesh network 130 is visible in front, and in view B, the perforated plate 110 is visible in front.

The perforated plate 110 may be formed by evenly disposing a plurality of through holes having a predetermined inner diameter in a plate material having a predetermined thickness and rigidity equal to or greater than a critical value.

Since the piping used in ships has a large diameter, the diameter of the filter is also large. In this case, if the filter is manufactured using mesh rather than a perforated plate, there is a problem in that it cannot withstand the flow rate and is torn, preventing it from performing its function as a filter. Therefore, in this embodiment, in order to solve this problem, a perforated plate is applied to support the mesh network and prevent the mesh network from being damaged, but to manufacture a piping filter 100 that allows fluid to pass smoothly through the through holes formed in the perforated plate. and applied to piping.

FIG. 3 is a diagram showing the configuration and manufacturing of a first expanded pipe filter according to another embodiment of the present invention, and FIG. 4 is a cross-sectional view taken along line A-A of FIG. 3.

3 and 4 show a perforated filter 100, a first expansion member 210, a first gripper 220, a second gripper 230, a hinge 240, a locking portion 250, and a first expanded piping filter. (200) is shown.

In the case of a piping filter (perforated filter) using a perforated plate as shown in FIG. 2, the size is limited. Therefore, there is the inconvenience of having to manufacture a new perforated filter every time depending on the pipe diameter at the point where the filter is to be installed.

The first expandable piping filter according to another embodiment of the present invention is characterized in that the overall diameter can be expanded by fastening an expansion member to the circumferential surface of a standardized perforated filter to solve this inconvenience.

The first expanded pipe filter 200 includes a perforated filter 100 and a first expansion member 210 installed on the peripheral surface of the perforated filter 100.

The second expansion member 310 includes a first gripper 220 and a second gripper 230, which are semicircular ring chains rotatably coupled around the hinge 240. The first gripper 220 and the second gripper 230 may be rotated relative to each other to create a complete ring body with a closed interior, or may be rotated conversely to open the interior.

As shown at the top of FIG. 3, when the first gripper 220 rotates counterclockwise relative to the second gripper 230 to open the inside, the perforated filter 100 can be fitted and coupled thereto. .

When the perforated filter 100 is standardized to have one or more predetermined outer diameters, the first expansion member 210 is also configured so that the inner diameters of the first gripper 220 and the second gripper 230 correspond to the outer diameter of the perforated filter 100. It can be manufactured in a standardized manner. In this case, the inner diameters of the first gripper 220 and the second gripper 230 are standardized, but their outer diameters can be adaptively determined depending on the pipe diameter at the installation point.

That is, the expanded diameter of the perforated filter 100 can be varied by using the first expansion member 210 that has the same inner diameter but various widths (W1 can have various values), and this allows Compatible between pipes of various diameters.

As shown at the bottom of FIG. 3, the perforated filter 100 is fitted and coupled to the internal space created by the first gripper 220 and the second gripper 230, and the first gripper 220 and the second gripper 230 ) are rotated in a direction to close each other, the first gripper 220 and/or the second gripper 230 are connected using the locking portion 250 to prevent the first gripper 220 and/or the second gripper 230 from rotating in the opposite direction. The second gripper 230 can be integrally fastened.

The locking portion 250 is a part that prevents the two separated components from being separated after they are combined. For example, a locking protrusion is formed at the end of the locking portion 250 protruding from the first gripper 220, and a locking groove is formed at a corresponding position on the outer surface of the second gripper 230, so that the locking protrusion is By engaging the engaging groove in the locking groove, the interior formed by the first gripper 220 and the second gripper 230 can be closed.

Referring to FIG. 4, a cross-sectional portion along line A-A (the perforated filter 100 and the first expansion member 210 are separated) is shown.

Referring to (a), a fitting groove 260 is formed along the peripheral surface (outer surface) of the perforated filter 100. On the inner surface of the gripper (first gripper 220 or second gripper 230) that meets the outer surface of the perforated filter 100, a fitting protrusion 265 corresponding to the fitting groove 260 is formed to protrude.

Therefore, when the gripper is fastened along the circumferential surface of the perforated filter 100, the fitting protrusion 265 is fitted into the fitting groove 260, so that the first expansion member 210 is moved from the perforated filter 100 in the vertical direction. This prevents slipping and separation and ensures a firm connection.

Here, the cross-sectional shape of the fitting groove 260 and the cross-sectional shape of the fitting protrusion 265 may be the same. For example, the fitting groove 260 may have a rectangular cross-section with dimensions of horizontal x and vertical y, and the fitting protrusion 265 may also have a rectangular cross-section with dimensions of horizontal x and vertical y. In order to facilitate easy fastening in actual implementation, the cross-sectional size of the fitting protrusion 265 may be formed small within the error range.

The fitting groove and fitting protrusion may be positioned oppositely. That is, a fitting protrusion may be formed to protrude on the outer surface of the perforated filter, and a fitting groove may be formed on the inner surface of the gripper.

Referring to (b), the thickness T2 of the first expansion member 210 is formed to be larger than the thickness T1 of the perforated filter 100, and the inner surface of the gripper of the first expansion member 210 is attached to T1. The fitting groove 270 having a corresponding width may be formed as a recess type.

Therefore, the outer part of the perforated filter 100 is fitted into the fitting groove 270 of the gripper, so that the first expansion member 210 holds the circumferential surface of the perforated filter 100 to ensure a firm connection. .

Figure 5 is a diagram showing the configuration and manufacturing of a second expanded pipe filter according to another embodiment of the present invention.

Referring to FIG. 5, the second expanded pipe filter 300 includes a second expansion member 310, which is a ring structure made of a plate material with a through hole formed therein and having a predetermined width.

The inner diameter of the second expansion member 310 may have a size corresponding to the outer diameter of the perforated filter 100 to be inserted and installed.

The second expansion member 310 is provided with a number of products having various widths (W2), so that the width of the second expansion member 310 corresponds to the diameter of the pipe in which the second expansion pipe filter 300 is to be installed. By determining and installing it outside the perforated filter 100 whose size is fixed, the perforated filter 100 can have the effect of expanding its diameter.

An O-ring 320 may be installed between the second expansion member 310 and the perforated filter 100. Due to the installation of the O-ring 320, the perforated filter 100 can be more firmly fitted to the inside of the second expansion member 310. In addition, after installing the second expanded piping filter 300 at the piping installation point, the fluid passes through the gap between the second expansion member 310 and the perforated filter 100, not through the perforated filter 100. It is also possible to prevent the perforated filter 100 from being separated.

Although the present invention has been described above with reference to embodiments, those skilled in the art can modify the present invention in various ways without departing from the spirit and scope of the present invention as set forth in the claims below. and that it can be changed.

11: first pipe 12: second pipe
100: Piping filter 110: Perforated plate
120: Filter flange 130: Mesh net
200: First expanded pipe filter
210: first expansion member 220: first gripper
230: second gripper 240: hinge
250: Locking part 300: Second expanded piping filter
310: second expansion member 320: O-ring

Claims (4)

A marine piping filter installed between pipes,
A mesh net that filters foreign substances in the fluid;
A perforated plate in the shape of a plate laminated on the lower part of the mesh network and having a plurality of through holes formed thereon; and
It includes a filter flange that has a predetermined width and is installed on the circumferential surface of the mesh net and the perforated plate, and is fastened correspondingly to the flange of the pipes,
The mesh network is installed upstream of the fluid and the perforated plate is installed downstream of the fluid,
The internal space can be opened and closed, and the perforated filter with the filter flange fastened is inserted into the peripheral surface of the mesh net and the perforated plate with the internal space open, and the perforated filter is inserted into the perforated filter with the internal space closed. A marine piping filter further comprising a first expansion member that holds the circumferential surface. delete According to paragraph 1,
The first expansion member,
A piping filter for ships, which is rotatably coupled around a hinge and includes a first gripper and a second gripper having a semicircular ring structure. A marine piping filter installed between pipes,
A mesh net that filters foreign substances in the fluid;
A perforated plate in the shape of a plate laminated on the lower part of the mesh network and having a plurality of through holes formed thereon; and
It includes a filter flange that has a predetermined width and is installed on the circumferential surface of the mesh net and the perforated plate, and is fastened correspondingly to the flange of the pipes,
The mesh network is installed upstream of the fluid and the perforated plate is installed downstream of the fluid,
a second expansion member, which is a ring structure having a through hole corresponding to a perforated filter in which the filter flange is fastened to a peripheral surface of the mesh network and the perforated plate; and
A marine piping filter further comprising an O-ring interposed between the outer surface of the perforated filter and the inner surface of the second expansion member.