KR20150059233A - Device for Draining Back-washing Fluid and Filter Apparatus - Google Patents

Abstract

The present invention relates to a back washing fluid discharge apparatus and a filter apparatus, comprising a plurality of discharge members installed to be located in the interior of a filter member to discharge back washing fluid moving into the filter member, wherein the discharge members are formed having different diameters to form a plurality of inlet holes through which the back washing fluid is introduced and are formed having different lengths to locate the inlet holes at different heights. According to the present invention, suction force to perform a back washing process for the filter member and uniformity for velocity of flow of the given fluid are improved, thereby increasing efficiency of back washing for the filter member while having an effect of enhancing filtering performance.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a backwashing fluid-

The present invention relates to a filter device used for filtering foreign matters contained in a fluid.

Generally, the filter device performs a filtering process for removing foreign matter from a fluid by filtering foreign matters contained in a fluid supplied to a ship or the like.

For example, when the filter device is installed on a ship, the filter device may perform a filtering process to remove foreign matter from the fluid supplied to the ship so that the ballast water is stored on the ship in a state that the foreign matter is removed. The ballast water is to control the balance and draft of the ship by controlling the amount stored in the ballast tank installed in the ship according to the volume of cargo loaded on the ship. The process of controlling the amount of ballast water stored in the ballast tank may be accomplished by discharging the ballast water stored in the ballast tank to the outside of the ship or supplying the ballast tank with fluid such as seawater or fresh water located outside the ship .

In this process, the filter device installed on the ship removes foreign matter such as gravel, sand, mud and the like from the fluid supplied to the ballast tank and foreign substances such as fish and shellfish, crustaceans, plankton, Disturbance, harmful pathogenic bacteria, and the like. In this connection, the technology which is a background of the present invention is disclosed in Korean Patent Registration No. 10-0769834 (published on Oct. 24, 2007).

FIG. 1 is a conceptual view showing a state in which a conventional filter device performs a filtering process, and FIG. 2 is a conceptual diagram showing a state in which a conventional filter device performs a back washing process.

1, a filter device 10 according to the prior art performs a filtration process on a fluid by moving the fluid through the through-holes 12 formed in the filter member 11. As shown in Fig. The fluid is supplied to the interior of the filter member 11 through the through hole 13 and then moved in the direction from the lower side to the upper side of the filter member 11, To the outside of the filter member (11). The through-holes 12 are formed in a size smaller than the foreign matter to be removed from the fluid. Accordingly, in the course of the fluid moving from the inside of the filter member 11 to the outside of the filter member 11, the foreign matter mixed with the fluid is removed from the fluid by failing to pass through the through holes 12.

The foreign matter remaining in the interior of the filter member 11 is gradually adhered to the inner surface of the filter member 11 as the filtering process is performed as described above. Accordingly, the filter device 10 according to the related art is gradually reduced in the flow rate of the fluid passing through the filter member 11, thereby deteriorating the function of the filtering process.

In order to prevent this, the filter device 10 according to the prior art performs a backwashing process for the filter member 11 as shown in Fig. In this case, the fluid moves from the outside of the filter member 11 to the inside of the filter member 11, thereby separating the foreign matter adhering to the inside surface of the filter member 11 from the filter member 11. That is, the fluid moves in a direction opposite to the direction in which the filtering process is performed, thereby separating the foreign matter from the filter member 11. The foreign matter separated from the filter member 11 moves together with the fluid moving in the direction from the upper side to the lower side of the filter member 11 and is discharged to the outside through the through hole 13. [

When the backwashing process is performed, the filter device 10 according to the related art has a problem that as the distance from the through hole 13 to the filter member 11 is increased, The suction force for moving the fluid located in the filter member 11 into the filter member 11 is reduced. The flow velocity of the fluid located outside the filter member 11 toward the inside of the filter member 11 increases with distance from the through hole 13 in the filter member 11 . That is, the backwashing efficiency is lowered in a portion located on the upper side of the filter member 11. Accordingly, after the backwashing process is performed, the filter device 10 according to the related art remains in a state where the foreign matter adheres to a portion located on the upper side of the filter member 11, There is a problem that the filtering function is deteriorated due to the clogging of the filters 12.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a backwashing fluid drainage device and a filter device capable of reducing the rate of decrease in filtering function due to foreign matters remaining after a backwashing process.

In order to solve the above-described problems, the present invention can include the following configuration.

The backwashing fluid drainage device according to the present invention may include a plurality of drainage members positioned inside the filter member to discharge the backwash fluid that has migrated into the interior of the filter member. The drainage members may be formed to have different diameters so that a plurality of inflow holes for introducing the backwash fluid are formed. The drain members may be formed to have different lengths so that the inlet holes are located at different heights.

A filter device according to the present invention comprises: a filter member for removing foreign matter from a fluid; A main body in which the filter member is installed; A backwashing unit coupled to the main body and adapted to move fluid from the outside of the filter member to the inside of the filter member so that foreign matter is separated from the filter member; And a drain device coupled to the body to be positioned within the filter member. The drainage device may include a plurality of drainage members coupled to the body for discharging the backwash fluid that has flowed into the interior of the filter member from outside the filter member. The drainage members may be formed to have different diameters so that a plurality of inflow holes for introducing the backwash fluid may be formed, and may be spaced apart from each other. The drain members may be formed to have different lengths so that the inlet holes are located at different heights.

A filter device according to the present invention comprises: a filter member for removing foreign matter from a fluid; A main body in which the filter member is installed; A filtering unit coupled to the body and adapted to move the fluid from the inside of the filter member to the outside of the filter member to remove foreign matter from the fluid; A backwashing unit coupled to the main body and adapted to move fluid from the outside of the filter member to the inside of the filter member so that foreign matter is separated from the filter member; And a drain device coupled to the body to be positioned within the filter member. The drainage device includes a plurality of inflow holes for introducing the backwash fluid so that the backwash fluid moved from the outside of the filter member to the inside of the filter member passes through the through holes formed in the main body and is discharged to the backwash section can do. The inlet holes may be formed at different heights so that backwash fluid may flow at different heights.

According to the present invention, the following effects can be obtained.

The present invention improves the uniformity of the suction force and the flow velocity of the fluid to perform the backwashing process on the filter member, thereby improving the backwashing efficiency of the filter member as well as enhancing the filtering performance. .

The present invention can be implemented so as to increase the number of maintenance cycles required to perform replacement or the like with respect to the filter member, thereby reducing the replacement cost and operating cost of the filter member.

The present invention can reduce the flow rate of the fluid consumed in performing the backwashing process on the filter member and shorten the time taken to perform the backwashing process on the filter member.

1 is a conceptual diagram showing a state in which a filter device according to the prior art performs a filtering process.
2 is a conceptual view showing a state in which the filter device according to the related art performs a backwashing process
3 is a schematic side cross-sectional view of a filter device according to the invention
4 is a schematic side cross-sectional view of the drainage device according to the invention
5 is a schematic perspective view of a drainage device and a filter element according to the present invention;
6 to 8 are schematic side cross-sectional views of a drainage device according to a modified embodiment of the present invention

Hereinafter, embodiments of the filter device according to the present invention will be described in detail with reference to the accompanying drawings. Since the backwashing fluid drainage device according to the present invention is included in the filter device according to the present invention, the description of the embodiment of the filter device according to the present invention will be described together.

3 and 4, the filter device 1 according to the present invention is for performing a filtering process for removing foreign matter from a fluid by filtering foreign matters contained in the fluid. The filter device (1) according to the present invention can be installed on a ship. In this case, the filter device 1 according to the present invention can perform a filtering process for removing foreign matter from seawater, fresh water, and the like, which is supplied to the ship so that the ballast water is stored in the ballast tank of the ship in a state where foreign matters are removed .

The filter device 1 according to the present invention comprises a main body 2, a filter member 3 provided on the main body 2, a filtering part 4 (shown in Fig. 4) for performing a filtering process on the fluid, A backwashing unit 5 (shown in Fig. 3) for performing a backwashing process on the filter member 3, and a drainage device 6 coupled to the main body 2. [

The filter element 3 may include a plurality of through holes 31 (shown in FIG. 4) for passing a fluid therethrough. The filtering unit 4 moves the fluid so that the fluid moves through the through holes 31 to the outside of the filter member 3 inside the filter member 3. In this case, the foreign matter mixed with the fluid does not pass through the through holes 31 and remains in the filter member 3, so that the filtering process for the fluid is performed.

The backwashing unit 5 moves the fluid so that the fluid moves from the outside of the filter member 3 to the inside of the filter member 3. Accordingly, the fluid moving from the outside of the filter member 3 to the interior of the filter member 3 separates the foreign matter from the filter member 3, thereby performing the backwashing process on the filter member 3 do. The backwashing fluid that has moved into the filter member 3 is discharged to the outside through the through hole 21 formed in the main body 2. The backwashing fluid comprises a fluid and foreign matter separated from the filter member (3).

The water drainage device (6) is coupled to the main body (2) so as to be positioned inside the filter member (3). The drainage device (6) includes a plurality of inflow holes (61) through which the backwashing fluid is introduced so that the backwashing fluid is discharged through the through holes (21). The inflow holes 61 are formed at different heights so that the backwash fluid flows at different heights. Here, the height means a position based on the direction in which the filter member 3 protrudes from the through hole 21 (Z-axis direction, hereinafter referred to as 'height direction'). Accordingly, the inflow holes 61 are located at positions spaced upward from the through holes 61 in the height direction (Z-axis direction). Therefore, the filter device 1 according to the present invention can achieve the following operational effects.

First, the filter device 1 according to the present invention is characterized in that the backwashing fluid is introduced into the drainage device 6 through the inlet holes 61 at different heights and then discharged through the through- . Accordingly, the filter device 1 according to the present invention is provided with the filter member 3, which is separated from the through hole 21 by a distance from the through hole 21, through the inflow holes 61, The suction force for moving the fluid located outside the filter member 3 to the inside of the filter member 3 and the degree to which the flow rate of the fluid is lowered can be reduced. That is, the filter device 1 according to the present invention can reduce the suction force on the fluid and the degree of reduction of the flow rate of the fluid as the portion located above the filter member 3 in the height direction (Z-axis direction) have.

Therefore, the filter device 1 according to the present invention can improve the uniformity of the suction force for performing the backwashing process in the height direction (Z-axis direction) and the flow velocity of the fluid, The backwashing efficiency can be improved. Further, the filter device 1 according to the present invention prevents the foreign material from remaining on the upper portion of the filter member 3 after the backwashing process is performed, Can be strengthened.

Secondly, the filter device 1 according to the present invention improves the backwashing efficiency with respect to the filter member 3, so that the through holes 31 formed in the filter member 3 are replaced by foreign substances You can increase the maintenance cycle you need to perform. Therefore, the filter device 1 according to the present invention can reduce the operation cost by reducing the replacement cost and the like for the filter member 3.

Third, the filter device 1 according to the present invention can improve the uniformity of the suction force for performing the backwashing process in the height direction (Z-axis direction) and the flow velocity of the fluid, The flow rate of the fluid consumed in performing the backwashing process and the time taken to perform the backwashing process with respect to the filter member 3 can be reduced.

Hereinafter, the main body 2, the filter member 3, the filtering unit 4, the backwashing unit 5 and the drainage unit 6 will be described in detail with reference to the accompanying drawings.

3 and 4, the main body 2 supports the filter member 3. The main body 2 may be provided with a plurality of the filter members 3. In this case, the filter members 3 are coupled to the main body 2 so as to be spaced apart from each other.

The body (2) includes the through hole (21). The filter member (3) is coupled to the main body (2) so as to be connected to the through hole (21). The through-hole 21 functions as a passage through which the fluid moves during the filtering process and the backwash process.

When the filtering process is performed, the fluid is supplied to the inside of the main body 2, and then passes through the through hole 21 and moves into the filter member 3. The fluid that has passed through the through hole (21) can pass through the drain device (6) and move into the filter member (3). The fluid that has moved into the filter member 3 is moved to the outside of the filter member 3 through the through holes 31. In this process, the foreign matter mixed with the fluid does not pass through the through holes 31 and remains in the interior of the filter member 3, thereby being removed from the fluid. The fluid moved to the outside of the filter member (3) can function as a ballast water by being stored in the ballast tank. When a plurality of the filter members 3 are coupled to the main body 2, the main body 2 may include a number of through holes 21 corresponding to the number of the filter members 3.

When the backwashing process is performed, the fluid located inside the main body 2 moves from the outside of the filter member 3 to the inside of the filter member 3 through the through holes 31, Thereby separating the foreign matter adhered to the inner surface of the member 3 from the filter member 3. The backwashing fluid moved into the filter member 3 passes through the through hole 21 and is discharged to the outside of the main body 2. [ The backwashing fluid moved into the filter member 3 may be discharged to the outside of the main body 2 after passing through the through hole 21 through the drainage device 6. [ The backwash fluid may be a mixture of the fluid stored in the ballast tank and foreign matter separated from the filter member (3).

The main body 2 may include a first main body 22 on which the filter member 3 is installed and a second main body 23 on which the backwashing unit 5 is installed.

The first body (22) supports the filter member (3). The first main body 22 is coupled to the second main body 23 at an upper side of the second main body 23. When the filtering process and the backwashing process are performed, the inside of the first body 22 may be filled with fluid.

The first body 22 may include a first connecting member 221. The first connection member 221 functions as a passage for moving the fluid between the inside of the first main body 22 and the outside of the first main body 22 when the filtering process and the backwash process are performed. do. When the filtering process is performed, foreign matter removed by the filter member 3 may be discharged to the outside of the first main body 22 through the first connecting member 221. When the backwashing process is performed, the fluid located outside the first body 22 may be supplied to the interior of the first body 22 through the first connection member 221. The first connecting member 221 may be connected to the ballast tank through a pipeline or the like. The filtering unit 4 may be installed between the first connecting member 221 and the ballast tank.

The second body (23) supports the first body (22). When the filtering process is performed, the inside of the second body 23 may be filled with fluid. The second body 23 may include a second linking member 231. The second linking member 231 functions as a passage for moving the fluid between the inside of the second body 23 and the outside of the second body 23 when the filtering process is performed. The second connection member 231 may be connected to a pipeline or the like so that seawater, fresh water or the like located in the vicinity of the ship can be supplied into the second main body 23. The backwashing unit 5 may be installed in the second body 23. The second body 23 may be filled with fluid when the backwashing process is performed. The remaining portion of the connecting portion of the second main body 23 and the first main body 22 except for the through hole 21 is closed so that the fluid can not move.

3 and 4, the filter member 3 is coupled to the main body 2 so as to be positioned inside the main body 2. The filter member 3 may be coupled to the first body 22 so as to be positioned inside the first body 22. The filter member (3) removes foreign matter from the fluid. To this end, the filter element 3 includes a plurality of through holes 31 for passing a fluid therethrough. The through holes (31) are formed through the filter member (3). The through holes 31 may be formed in the filter member 3 so as to be spaced apart from each other. When the passing process is performed, the fluid can pass through the through holes 31 and move outside the filter member 3 inside the filter member 3. On the other hand, the foreign matter mixed with the fluid does not pass through the through holes 31 and is blocked by the filter member 3, so that it remains inside the filter member 3. Accordingly, the filter member 3 can remove foreign matter from the fluid.

The filter member 3 may be coupled to the main body 2 such that one end thereof is connected to the through-hole 21. The filter member 3 may be coupled to the main body 2 such that the other end thereof is in contact with the main body 2. And the other end of the filter member 3 means an end opposite to one end connected to the through hole 21. [ The filter member 3 may be formed in a cylindrical shape having an empty interior as a whole. Although not shown, the filter member 3 may be formed in a truncated cone shape whose diameter decreases toward the upper side in the height direction (Z-axis direction). A plurality of filter members (3) can be coupled to the main body (2). In this case, the filter members 3 may be coupled to the main body 2 at a distance equal to each other.

3 and 4, the filtering unit 4 (shown in Fig. 4) is arranged so that fluid flows from the inside of the filter member 3 through the through holes 31 to the outside of the filter member 3 Move the fluid to move. Thereby, a filtering process is performed in which foreign matter is removed from the fluid. The filtering unit 4 may include a pump for generating a feed force for moving the fluid. The filtering unit 4 is coupled to the main body 2. The filtering unit 4 may be coupled to the first connection member 221 of the first main body 22. Although not shown, the filtering unit 4 may be coupled to the second connecting member 231 of the second body 23.

3 and 4, the backwashing section 5 is configured to move the fluid so that the fluid moves from the outside of the filter member 3 through the through holes 31 to the inside of the filter member 3 . Thus, a backwash process is performed in which foreign matter is separated from the filter member 3. The backwashing unit 5 is coupled to the main body 2. The backwashing unit 5 may be coupled to the second body 23.

The backwashing section 5 may include a rotating mechanism 51, a connecting mechanism 52, and an operating mechanism 53.

The rotating mechanism (51) is rotatably coupled to the main body (2). The rotation mechanism 51 may be coupled to the second body 23 such that a part of the rotation mechanism 51 is inserted into the second body 23 and a part of the rotation mechanism 51 protrudes outside the second body 23. The rotating mechanism 51 functions as a flow path for discharging the backwashing fluid supplied from the through-hole 21 to the outside. The rotating mechanism 51 may be a hollow pipe. The rotating mechanism 51 can be rotated by the driving mechanism 54. [ The driving mechanism 54 may include a motor or the like that generates a rotational force for rotating the rotating mechanism 51. The motor may be installed on the upper surface of the first body 22. In this case, the driving mechanism 54 may further include a shaft connecting the motor and the rotating mechanism 51. The shaft may be coupled to the first body 22 to penetrate the first body 22 to thereby connect the motor and the rotating mechanism 51. Although not shown, the motor may be installed on the lower side of the second body 23. In this case, the shaft may be coupled to the second body 23 to penetrate the second body 23.

One end of the connecting mechanism (52) is coupled to the rotating mechanism (51). Accordingly, the connection mechanism (52) can rotate about the rotation mechanism (51) as the rotation mechanism (51) rotates. As the connection mechanism 52 rotates about the rotation mechanism 51, the other end may be selectively connected to the through hole 21. [ When the other end of the connection mechanism 52 is connected to the through hole 21, the backwash fluid passes through the through hole 21 and is supplied to the connection mechanism 52, Can be supplied. The connection mechanism 52 functions as a flow path for transmitting the backwash fluid supplied from the through hole 21 to the rotation mechanism 51. The connection mechanism 52 may be a hollow pipe. When a plurality of filter members 3 are coupled to the main body 2, the connection mechanism 52 performs the backwashing process among the filter members 3 according to the angle at which the rotation mechanism 51 rotates. Can be selectively connected to the filter element 3 to be performed. Therefore, the filter device 1 according to the present invention performs a backwashing operation on the filter member 3 connected to the connection mechanism 52 among the filter members 3, The filtering process can be performed using the filter member 3 which is not connected.

The operating mechanism (53) is coupled to the rotating mechanism (51). The operating mechanism 53 may be coupled to a portion of the rotating mechanism 51 projecting from the second body 23. The operating mechanism (53) can open / close the rotating mechanism (51). In this case, the operating mechanism 53 may include a valve that opens and closes a flow path through which the backwash fluid flows in the rotating mechanism 51. When the operating mechanism 53 closes the rotating mechanism 51, the backwashing process is not performed even if the filter member 3 is connected to the connecting mechanism 52. When the operating mechanism 53 opens the rotating mechanism 51, a backwashing process is performed on the filter member 3 connected to the connecting mechanism 52. In this case, the backwashing process can be performed by generating a transfer force for moving the fluid from the difference between the internal pressure of the first main body 22 filled with the fluid and the external pressure connected through the rotation mechanism 51. Although not shown, the actuating mechanism 53 may include a pump or the like for generating a feed force for moving the fluid.

3 and 4, the drainage device 6 is coupled to the main body 2 so as to be positioned inside the filter member 3. The drainage device 6 may be coupled to the main body 2 such that one end thereof is connected to the through-hole 21. The drainage device 6 may be coupled to the main body 2 such that the other end thereof is spaced apart from the main body 2 by a predetermined distance. And the other end of the drainage device 6 means an end opposite to one end connected to the through hole 21. [ The other end of the drainage device 6 is located at a higher position than the one end of the drainage device 6 in the height direction (Z-axis direction). When a plurality of the filter members 3 are coupled to the main body 2, the filter device 1 according to the present invention may include a number of drainage devices 6 corresponding to the number of the filter members 3 have. The drainage devices (6) may be respectively coupled to the main body (2) so as to be positioned inside the filter members (3).

The drainage device (6) includes the inflow hole (61). The inflow hole 61 is formed at a position spaced upward from the through hole 21 in the height direction (Z-axis direction). Accordingly, the drainage device 6 can distribute the suction force provided from the backwashing unit 5 to a position spaced upward from the through-hole 21 by using the inflow hole 61. Accordingly, the drainage device 6 distributes the suction force provided from the backwashing section 5 to the portion located on the upper side in the height direction (Z-axis direction) in the filter member 3, It is possible to reduce the degree of decrease in the fluid suction force and the flow velocity of the fluid with respect to the portion located on the upper side in the height direction (Z-axis direction) in the member 3. [ Accordingly, the filter device 1 according to the present invention improves the uniformity of the suction force for performing the backwashing process in the height direction (Z-axis direction) and the flow velocity of the fluid, The backwashing efficiency can be improved.

The drain device (6) may include a plurality of the inflow holes (61). The inlet holes 61 may be formed at different heights in the height direction (Z-axis direction). Accordingly, the drainage device 6 can distribute the suction force provided from the backwashing unit 5 through the inflow holes 61 to more positions spaced upward from the through-hole 21. Accordingly, the backwash fluid is supplied to the inside of the drainage device 6 at different heights by the suction force transmitted through the inlet holes 61, and then moves along the inside of the drainage device 6, And can be discharged through the through hole (21). Accordingly, the filter device 1 according to the present invention can further improve the uniformity of the suction force for performing the backwashing process in the height direction (Z-axis direction) and the flow velocity of the fluid.

This is because when the backwashing process is performed on each of the filter member 3 in which the drainage device 6 is not installed and the filter member 3 in which the drainage device 6 is installed, And the flow rate of the fluid moving from the outside of the filter member 3 to the inside of the filter member 3 is measured. The graph shown in the comparative example in Table 1 below shows the measurement result for the filter member 3 in which the drainage device 6 is not installed and the graph shown in the first embodiment shows the filter member 3 in which the drainage device 6 is installed 3).

In the graph of the comparative example and the graph of the first embodiment, the ordinate is the height of the filter member 3, and the abscissa is the distance from the outside of the filter member 3 to the inside of the filter member 3 It is the flow rate of the fluid. The lower end in the vertical axis is a portion near the through hole 21 in the filter member 3 and a portion located on the upper side of the filter member 3 spaced apart from the through hole 21 with respect to the vertical axis . The longer the flow direction is, the longer the flow rate of fluid is.

As shown in the graph of the comparative example, the flow rate of the fluid gradually decreases in the upper part of the filter member 3 where the drainage device 6 is not installed. That is, the suction force on the fluid decreases as the filter member 3, on which the drainage device 6 is not installed, is located on the upper side. Therefore, it can be seen from the graph of the comparative example that the backwashing efficiency decreases as the distance from the through hole 21 to the filter member 3 where the drainage device 6 is not installed is far.

Meanwhile, as shown in the graph of the first embodiment, a portion of the filter member 3 in which the drainage device 6 is installed is formed at a portion where the flow velocity of the fluid increases at the height where the inflow holes 61 are located. That is, the filter member 3 provided with the drain device 6 has a portion where the suction force for the fluid increases at the height where the inflow holes 61 are located. Therefore, the filter device 1 according to the present invention is characterized in that it is possible to perform the backwashing process in the height direction (Z-axis direction) of the filter member 3 as compared with the case where the drainage device 6 is not installed It can be seen that the backwash efficiency can be improved by improving the uniformity of the suction force and the flow rate of the fluid.

3 to 5, the drainage device 6 may include a plurality of drainage members 62 for forming the inflow hole 61.

The drain members 62 are respectively coupled to the main body 2 so as to be positioned inside the filter member 3. The drain members 62 are coupled to the main body 2 such that one end thereof is connected to the through hole 21. The main body 2 may include a support member 24 (shown in Fig. 5) for supporting one end of the drainage members 62. The support member 24 may be coupled to the first body 22 so as to cross the through-hole 21. The drain members 62 are coupled to the support member 24 so that one end of the drain member 62 can be held connected to the through hole 21. [ 5, the support member 24 is illustrated as being formed in a cross shape. However, the support member 24 is not limited to the cross shape, and the support member 24 may have a shape that supports the drain member 62 while opening a part of the through hole 21, .

The drain members 62 are respectively coupled to the main body 2 such that the other ends thereof are located at a height spaced upward from the through holes 21. [ The drain members (62) function as a flow path for the backwash fluid to move to the through hole (21). The drain members 62 may be pipes having an empty interior.

The drain members 62 are formed to have different diameters. Accordingly, the drain members 62 may be spaced apart from each other. Therefore, an inlet hole 61 through which the backwashing fluid flows is formed between the drain members 62. Accordingly, the filter device 1 according to the present invention can implement the drainage device 6 having the inflow hole 61 without the step of processing the inflow hole 61 in the drainage device 6. Therefore, the filter device 1 according to the present invention can improve the easiness of the operation for manufacturing the drainage device 6 having the inflow hole 61. Further, the number of the inflow holes 61 can be easily changed by changing the number of the drain members 62 in the filter device 1 according to the present invention. Therefore, the filter device 1 according to the present invention can improve versatility, which can be easily applied to a product requiring a filter member 3 of various sizes and heights. The drainage device 6 may be implemented by being disposed inside the drainage member 62 having a small diameter. For example, the drainage device 6 may be implemented by installing a drainage member 62 having a second diameter smaller than the first diameter inside the drainage member 62 having the first diameter.

The drain members 62 may be formed to have different lengths in the height direction (Z-axis direction). Accordingly, the drain members 62 are coupled to the main body 2 such that the other ends of the drain members 62 are positioned at different heights with respect to one end connected to the through hole 21. [ Therefore, the inflow holes 61 formed between the drain members 62 are formed at different heights. Accordingly, the filter device 1 according to the present invention can improve the ease of operation for manufacturing the drainage device 6 having a plurality of inflow holes 61 spaced from each other in the height direction (Z-axis direction) have. Further, the height of the inflow hole 61 can be easily changed by changing the length of the drain member 62 in the filter device 1 according to the present invention. Therefore, the filter device 1 according to the present invention can improve versatility, which can be easily applied to a product requiring a filter member 3 of various sizes and heights. The water drainage device 6 may be implemented by being disposed inside the water drainage member 62 having a longer length. For example, the drainage device 6 may be implemented by installing a drainage member 62 having a second length that is longer than the first length inside the drainage member 62 having the first length.

3 to 5, the drainage device 6 may include a first drainage member 621 (shown in FIG. 4) and a second drainage member 622 (shown in FIG. 4).

The first drainage member 621 is coupled to the main body 2 so as to be positioned inside the filter member 3. The first drain member 621 is coupled to the main body 2 such that one end thereof is connected to the through hole 21. [ The first drain member 621 is coupled to the main body 2 such that the other end of the first drain member 621 is located at a height spaced upward from the through hole 21.

The first drainage member 621 includes a first insertion hole 6211. The first insertion hole 6211 is formed through the first drain member 621. The first insertion hole 6211 may function as a flow path for the backwash fluid to move to the through hole 21. [ The first drainage member 621 may be a hollow pipe.

The second drain member 622 is coupled to the main body 2 so as to be positioned inside the first drain member 621. The second drain member 622 is coupled to the main body 2 such that one end thereof is connected to the through hole 21. [ The second drainage member 622 is coupled to the main body 2 such that the other end thereof is located at a height spaced upward from the through-hole 21.

The second drain member 622 is installed inside the first drain member 621 by being inserted into the first insertion hole 6211. In this case, the first insertion hole 6211 is formed in the second drain member 621 so that the second drain member 622 is spaced from the first drain member 621, And is formed to have a larger size than the drain member 622. When the first drainage member 621 and the second drainage member 622 are cylindrical, the first insertion hole 6211 is formed to have a larger diameter than the second drainage member 622. The second drainage member 622 is formed to have a length longer than the first drainage member 621 so that the other end thereof protrudes above the first drainage member 621. Accordingly, a first inflow hole 611 (shown in FIG. 4) through which the backwash fluid flows between the second drainage member 622 and the first drainage member 621 is formed. The fluid supplied to the first inflow hole 611 is discharged through the through hole 21 after moving along the first insertion hole 6211. The first inflow hole 611 may be formed at the same height as the other end of the first drain member 621. That is, the first inflow hole 611 is formed at a height spaced upward from the through-hole 21.

Accordingly, the drainage device 6 can distribute the suction force provided from the backwashing unit 5 to a height at which the first inflow hole 611 is located. Therefore, the drainage device 6 increases the fluid suction force and the flow rate of the fluid to the portion located at the height corresponding to the first inlet hole 611 in the filter member 3, The suction force for performing the backwashing process and the uniformity of the flow velocity of the fluid can be improved.

The second drainage member 622 includes a second insertion hole 6221. The second insertion hole 6221 is formed through the second drainage member 622. The second insertion hole 6221 may function as a flow path for the backwash fluid to move to the through hole 21. [ The second drainage member 622 may be a hollow pipe.

3 to 5, the drainage device 6 may further include a third drainage member 623 (shown in FIG. 4).

The third drainage member 623 is coupled to the main body 2 so as to be positioned inside the second drainage member 622. The third drainage member 623 is coupled to the main body 2 such that one end thereof is connected to the through-hole 21. The third drain member 623 is coupled to the main body 2 such that the other end of the third drain member 623 is located at a height spaced upward from the through hole 21.

The third drain member 623 is installed in the second drain member 622 by being inserted into the second insertion hole 6221. In this case, the second insertion hole 6221 is formed in the second drain member 622 so that the third drain member 623 is spaced from the second drain member 622, And is formed to have a larger size than the drain member 623. When the second drainage member 622 and the third drainage member 623 are cylindrical, the second insertion hole 6221 is formed to have a larger diameter than the third drainage member 623. Accordingly, a second inflow hole 612 (shown in FIG. 4) through which the backwash fluid flows between the third drainage member 623 and the second drainage member 622 is formed. The fluid supplied to the second inflow hole 612 is discharged through the through hole 21 after moving along the second insertion hole 6221. The second inflow hole 612 may be formed at the same height as the other end of the second drainage member 622. That is, the second inflow hole 612 is formed at a height spaced upward from the first through hole 611. In this case, the first drainage member 621 is formed to have a shorter length than the second drainage member 622 so that the second inlet hole 612 is located at a higher position than the first inlet hole 611 .

Accordingly, the drainage device 6 distributes the suction force provided from the backwashing unit 5 to a height at which the first inflow hole 611 is located and a height at which the second inflow hole 612 is located . Therefore, the drainage device 6 is provided at a portion of the filter member 3 located at a height corresponding to the first inflow hole 611 and at a portion located at a height corresponding to the second inflow hole 612 The suction force for performing the backwashing process in the height direction (Z-axis direction) of the filter member 3 and the uniformity of the flow rate of the fluid can be further improved by increasing the fluid suction force and the flow velocity of the fluid .

The third drain member 623 may be formed to have a longer length than the second drain member 622 so that the other end protrudes upward from the second drain member 622. The third drain member 623 includes a third insertion hole 6231. The third insertion hole 6231 is formed through the third drainage member 623. The third insertion hole 6231 may function as a flow path for the backwash fluid to move to the through hole 21. [ The third drainage member 623 may be a hollow pipe.

The third drainage member 623, the second drainage member 622, and the first drainage member 621 may be spaced apart from the filter member 3, respectively. That is, the water drainage device 6 may be coupled to the main body 2 so as to be spaced apart from the filter member 3. As a result, the backwashing fluid, which has moved into the interior of the filter member 3 through the through holes 31 positioned at the height corresponding to the second inlet hole 612, The second inflow hole 612, and the first inflow hole 611, respectively. The second inflow hole 612 and the first inflow hole 611 are connected to the second inflow hole 612 through the through holes 31 positioned at a height corresponding to the second inflow hole 612, So that the backwashing fluid moved to the inside can be shared and moved to the through hole (21).

Accordingly, the drainage device 6 can increase the area of the flow path for the backwashing fluid, which has moved into the filter member 3 through the through holes 31, to move to the through hole 21 have. The filter device 1 according to the invention is therefore characterized in that the filter element 3 is arranged in such a way that when compared with the embodiment in which the drainage device 6 is connected to the body 2 in partial contact with the filter element 3, The suction force for performing the backwashing process and the uniformity of the flow velocity of the fluid can be further improved.

This is because when the backwashing process is performed on each of the filter member 3 in which the drainage device 6 is partly contacted and the filter member 3 in which the drainage device 6 is installed so as to be spaced apart, The flow rate of the fluid moving from the outside of the filter member 3 to the interior of the filter member 3 is measured.

In the following Table 2, the graph shown in Example 1 shows the measurement result of the embodiment in which the drainage device 6 is partially in contact with the filter member 3 formed in the truncated cone shape. In the first embodiment, the drain members 62 are provided in such a manner that a portion where the inlet holes 61 are formed is in contact with the inner surface of the filter member 3, respectively.

In the following Table 2, the graph of Example 2 shows the measurement result of the embodiment in which the water drainage device 6 is installed on the filter member 3 formed in a truncated cone shape. In the second embodiment, the drain members 62 are provided in such a manner that a portion where the inlet holes 61 are formed is spaced apart from the filter member 3.

As shown in the graphs shown in Table 2, the second embodiment differs from the first embodiment in that the drainage device 6 is installed apart from the filter member 3, The flow velocity of the fluid increases at the height at which they are located. That is, in the second embodiment, as compared with the first embodiment, the suction force for the fluid is further increased at the height where the inflow holes 61 are located. The filter device 1 according to the present invention is characterized in that when the drainage device 6 is installed so as to be spaced apart from the filter member 3, It can be seen that the backwashing efficiency for the filter member 3 can be further improved by further improving the suction force for carrying out the process and the uniformity of the flow rate of the fluid.

Referring to FIG. 6, the second inflow hole 612 may be formed to have a larger size than the first inflow hole 611. The second inflow hole 612 is formed in the second drainage member 622 and the third drainage member 622 in comparison with the interval 611D in which the first drainage member 621 and the second drainage member 622 are spaced apart. 623 may be formed to be larger than the first inflow hole 611 because the spacing 612D is larger. In this case, the diameter difference between the third drain member 623 and the second drain member 622 is larger than the diameter difference between the second drain member 622 and the first drain member 621 .

Accordingly, the filter device 1 according to the present invention is arranged such that the second inflow hole 612 is located farther from the through hole 21 than the first inflow hole 611, The backwashing fluid can be compensated for by increasing the flow rate of the backwashing fluid flowing into the second inlet hole 612 even if the suction force provided from the inlet 5 is distributed to a smaller size than the first inlet hole 611. [ Accordingly, the filter device 1 according to the present invention can further improve the uniformity of the suction force for the backwashing process and the flow velocity of the fluid in the height direction (Z-axis direction) of the filter member 3 .

6, the third drainage member 623 is spaced apart from the second drainage member 622 by a distance 623L shorter than the distance 622L protruded from the other end of the first drainage member 621 And may be coupled to the main body 2 so as to protrude from the other end of the second drain member 622. In this case, the difference in length between the third drain member 623 and the second drain member 622 is smaller than the difference in length between the second drain member 622 and the first drain member 621 .

Accordingly, the filter device 1 according to the present invention is arranged such that the second inflow hole 612 is located farther from the through hole 21 than the first inflow hole 611, The size of the area occupied by the second inflow hole 612 for introducing the backwashing fluid into the first inflow hole 612 is smaller than the size of the first inflow hole 612, The inflow hole 611 can be compensated for by reducing the size of the area it takes to introduce the backwash fluid. Therefore, the filter device 1 according to the present invention can further improve the suction force for performing the backwashing process in the height direction (Z-axis direction) of the filter member 3 and the uniformity of the flow rate of the fluid have.

The drainage device 6 includes two or three drainage members 62 but the present invention is not limited thereto and the drainage device 6 may include four or more drainage members 62 . For example, the drainage device 6 may be implemented to include six drainage members 62 as shown in FIG. In this case, the drainage device 6 may be embodied to include five inflow holes 61. The discharge member 62 protruding from the drainage members 62 in the height direction (Z-axis direction) is arranged at a predetermined distance from the main body 2 (shown in FIG. 3) 3). ≪ / RTI > Although not shown, the discharge member 62, which is the most protruded in the height direction (Z-axis direction) among the drain members 62, contacts the main body 2 (shown in Fig. 3) , Shown in Figure 3).

Referring to FIG. 8, the filter device 1 according to the present invention may further include a blocking portion 63.

The blocking portion 7 is coupled to the main body 2 so as to be positioned between the drainage device 6 and the filter member 3. The blocking portion 7 may be coupled to the support member 24 (shown in FIG. 5). The blocking portion 7 cuts off a part of the through hole 21 to prevent the through hole 21 from passing through the drainage device 6 and the filter member 3 without passing through the drainage device 6. [ The flow rate of the backwash fluid discharged into the backwashing fluid can be reduced. Since the gap between the drainage device 6 and the filter member 3 is located close to the through hole 21, a large suction force is not required to discharge the backwashing fluid into the through hole 21, This is to prevent the consumption of positive suction force.

Accordingly, the filter device 1 according to the present invention is configured such that the suction force provided from the backwashing section 5 is supplied to the through-holes 21 (21) through the drainage device 6 and the filter member 3 The amount of the suction force to be distributed to the inflow holes 61 can be increased. Therefore, the filter device 1 according to the present invention can further improve the suction force for performing the backwashing process in the height direction (Z-axis direction) of the filter member 3 and the uniformity of the flow rate of the fluid have.

This is because when the backwashing process is performed on each of the filter member 3 in which the blocking portion 7 is not provided and the filter member 3 in which the blocking portion 7 is installed, And the flow rate of the fluid moving from the outside of the filter member 3 to the inside of the filter member 3 is measured.

In the following Table 3, the graph shown in Example 2 shows the measurement results of the filter member 3 on which the blocking portion 7 is not provided. The graph of Example 3 in Table 3 below shows the measurement results for the filter member 3 in which the blocking portion 7 is additionally provided as compared with Embodiment 2. [

As shown in the graphs shown in Table 3, in the third embodiment, since the blocking portion 7 is provided to block a part of the through-hole 21, as compared with the second embodiment, 3) in the height direction (Z-axis direction), the uniformity of the suction force for the backwashing process and the flow velocity of the fluid can be further improved.

The blocking portion 7 is formed in the drain member 62 disposed at the outermost one of the drain members 62 of the drain device 6 and a part of the through hole 21 between the filter members 3 To the main body 2 for blocking. For example, the blocking portion 7 may be coupled to the main body 2 to block a portion of the through hole 21 between the first drain member 621 and the filter member 3.

The blocking portion 7 may include a blocking member 71. The blocking member 71 may be coupled to the main body 2 such that one side thereof contacts the inner surface of the filter member 3. The blocking member 71 may be coupled to the main body 2 such that the other side thereof is spaced apart from the first drain member 621 by a predetermined distance. The backwash fluid may be discharged to the through hole 21 through the other side of the blocking member 71 and the first drain member 621. The blocking member 71 may be formed in a circular ring shape as a whole.

The blocking portion 7 may further include a protruding member 72. The protruding member 72 protrudes upward from the other side of the blocking member 71. The protruding member 72 is spaced apart from the first drain member 621 by a predetermined distance. The backwashing fluid that has moved into the interior of the filter member 3 through the through holes 31 located adjacent to the through holes 21 moves by bypassing the protrusions 72, And can be discharged to the ball 21. Therefore, the projecting member 72 is rotated by the backwashing fluid, which has moved into the interior of the filter member 3 through the through holes 31 positioned adjacent to the through hole 21, through the through hole 21 The suction force for performing the backwashing process in the height direction (Z-axis direction) of the filter member 3 and the uniformity of the flow rate of the fluid can be further improved by reducing the discharged flow rate. The protruding member 72 may be formed in a cylindrical shape having an empty interior as a whole.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Will be clear to those who have knowledge of.

1: Filter device 2: Body
3: filter member 4: filtering member
5: backwashing unit 6: drainage unit
61: inflow hole 62: drainage member

Claims (14)

A filter member for removing foreign matter from the fluid;
A main body in which the filter member is installed;
A filtering unit coupled to the body and adapted to move the fluid from the inside of the filter member to the outside of the filter member to remove foreign matter from the fluid;
A backwashing unit coupled to the main body and adapted to move fluid from the outside of the filter member to the inside of the filter member so that foreign matter is separated from the filter member; And
And a drain device coupled to the body to be positioned within the filter element,
The drainage device includes a plurality of inflow holes for introducing the backwash fluid so that the backwash fluid moved from the outside of the filter member to the inside of the filter member passes through the through holes formed in the main body and is discharged to the backwash section Wherein the inflow holes are formed at different heights so that the backwash fluid flows at different heights. The method according to claim 1,
The drain device includes a first drain member coupled to the body so as to be positioned inside the filter member, one end of the drain member being connected to the through hole, and a second drain member positioned inside the first drain member, And a second drain member coupled to the body;
Wherein the first drain member includes a first insertion hole into which the second drain member is inserted,
Wherein the first insertion hole is formed such that the second drainage member is spaced apart from the first drainage member such that a first inflow hole is formed between the second drainage member and the first drainage member, And is formed so as to have a larger diameter,
Wherein the second drain member is formed to have a longer length than the first drain member so that the other end protrudes above the first drain member. 3. The method of claim 2,
The drainage device includes a third drainage member coupled to the body to be positioned inside the second drainage member so that one end thereof is connected to the through-hole;
The second drain member includes a second insertion hole into which the third drain member is inserted,
Wherein the second insertion hole is formed such that the third drainage member is spaced apart from the second drainage member so that a second inflow hole is formed between the third drainage member and the second drainage member, And is formed so as to have a larger diameter,
Wherein the second inflow hole is formed to be positioned higher than the first inflow hole. The method of claim 3,
Wherein the second inflow hole is formed to have a larger size than the first inflow hole. The method of claim 3,
And the third drain member is coupled to the main body such that the second drain member protrudes from the other end of the second drain member at a distance shorter than the distance protruded from the other end of the first drain member. The method according to claim 1,
And a blocking portion coupled to the body to be positioned between the drainage device and the filter member,
Wherein the blocking portion is coupled to the body to block a portion of the through-hole to reduce the flow rate of the backwash fluid exiting the through-hole through the drainage device and the filter element. A filter member for removing foreign matter from the fluid;
A main body in which the filter member is installed;
A backwashing unit coupled to the main body and adapted to move fluid from the outside of the filter member to the inside of the filter member so that foreign matter is separated from the filter member; And
And a drain device coupled to the body to be positioned within the filter element,
The drainage device including a plurality of drainage members coupled to the body for discharging backwash fluid that has migrated from the outside of the filter member into the interior of the filter member,
The drainage members are formed to have different diameters so as to form a plurality of inflow holes for introducing the backwashing fluid, and are spaced apart from each other. The inflow holes are formed to have different lengths so that the inflow holes are located at different heights / RTI > 8. The method of claim 1 or 7,
Wherein the drainage device is coupled to the body so as to be spaced apart from the filter element. And a plurality of drainage members disposed inside the filter member for discharging the backwash fluid moved into the interior of the filter member,
Wherein the drainage members are formed to have different diameters so as to form a plurality of inflow holes for introducing the backwashing fluid, and the inflow holes are formed to have different lengths so that the inflow holes are located at different heights. Device. 10. The system of claim 9, wherein the backwash fluid drain
A first drain member installed inside the filter member so as to be connected to a through hole through which the backwash fluid is discharged; And
And a second drain member disposed inside the first drain member such that one end of the second drain member is connected to the through hole,
The second drain member is formed to have a longer length than the first drain member so that the other end protrudes above the first drain member,
Wherein the first drain member includes a first insertion hole into which the second drain member is inserted,
Wherein the first insertion hole is formed such that the second drainage member is spaced apart from the first drainage member such that a first inflow hole is formed between the second drainage member and the first drainage member, Wherein the backwash fluid drainage device is formed to have a larger diameter than the backwash fluid drainage device. 11. The system of claim 10, wherein the backwash fluid drain
And a third drain member positioned inside the second drain member such that one end thereof is connected to the through hole;
The second drain member includes a second insertion hole into which the third drain member is inserted,
Wherein the second insertion hole is formed such that the third drainage member is spaced apart from the second drainage member so that a second inflow hole is formed between the third drainage member and the second drainage member, And has a large diameter,
Wherein the second inflow hole is formed at a higher position than the first inflow hole. 12. The method of claim 11,
Wherein the second inflow hole is formed to have a larger size than the first inflow hole. 12. The method of claim 11,
Wherein the third drain member is installed such that the second drain member protrudes from the other end of the second drain member at a distance shorter than the distance protruded from the other end of the first drain member. 10. The method of claim 9,
Wherein each of the drainage members is installed separately from the filter member.

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