KR102577336B1 - rust filter system - Google Patents

Abstract

The present invention relates to a rust removal filter system.
The rust removal filter system according to the present invention includes a first filter means for filtering liquid introduced into the interior, and an inflow device provided on one side of the first filter means and allowing the liquid to flow into the first filter means. a tube, a discharge pipe provided on the other side of the first filter means and allowing the discharge of the liquid filtered by the first filter means, and a discharge pipe provided on the other side of the first filter means and containing fluid therein. It includes a first chamber means that allows this to be achieved, and a first back tubule provided on one side of the first filter means and allowing the discharge of impurities or foreign substances filtered from the inside of the first filter means, a second filter means provided on one side of the first filter means and filtering liquid introduced therein; a second chamber means provided on one side of the second filter means and configured to accommodate fluid therein; A first connection pipe connected to the inlet pipe and allowing liquid to flow into the second filter means, and a first connection pipe connected to the discharge pipe to allow discharge of the liquid filtered by the second filter means. It further includes two connection pipes and a second back tubule provided on the other side of the second filter means and allowing discharge of impurities or foreign substances filtered from the inside of the second filter means.
According to the present invention, backwashing can be performed using operating pressure by the chamber means, and a high cleaning effect is achieved during backwashing by the filter unit.
In addition, when each pair of filter means and chamber means is provided, filtration can be continuously performed even during the backwashing process.

Description

Rust removal filter system {rust filter system}

The present invention relates to a rust removal filter system, and more specifically, to allow the gas contained inside the chamber means to be compressed by operating pressure, and to backwash the filter means through this compressed gas. It relates to a rust removal filter system that improves cleaning efficiency by backwashing by means of a filter unit.

In addition, the rust removal filter system according to the present invention may be comprised of a pair of filter means, through which filtration can be performed even during the backwashing process.

Ships are equipped with various mechanical devices such as engines and generators, and these mechanical devices generate heat.

Accordingly, ships are equipped with cooling systems for cooling mechanical devices.

In this regard, in Korean Patent No. 10-2411481, Korean Patent No. 10-1390495, Korean Patent Publication No. 10-2021-0129434, Korean Patent Publication No. 10-2019-0034883, etc., the cooling system of the ship is It begins.

Here, in the case of a cooling system using fresh water, fresh water is circulated through a closed loop.

Since fresh water is difficult to replace at sea, it continues to circulate in a closed loop, and there is a problem in that cooling efficiency is reduced or pump performance is deteriorated due to rust generated in this process.

Korea Registered Patent No. 10-2411481 Korea Registered Patent No. 10-1390495 Korean Public Patent No. 10-2021-0129434 Korean Public Patent No. 10-2019-0034883

Therefore, the purpose of the present invention is to solve the problems of the prior art as described above, and to allow the gas contained inside the chamber means to be compressed by the operating pressure, and to allow the gas contained in the chamber means to be compressed by the filter means through this compressed gas. The aim is to provide a rust removal filter system that enables backwashing and improves cleaning efficiency by backwashing through the filter unit.

In addition, the rust removal filter system according to the present invention may be comprised of a pair of filter means, thereby providing a rust removal filter system that allows filtration to be performed even during the backwashing process.

According to the features of the present invention for achieving the above-described object, a first filter means for filtering liquid introduced into the interior, and a first filter means provided on one side of the first filter means, the liquid flows into the first filter means. an inlet pipe that allows this to be achieved, a discharge pipe that is provided on the other side of the first filter means and allows the discharge of the liquid filtered by the first filter means, and is provided on the other side of the first filter means. a first chamber means to accommodate fluid therein, and a first back tubule provided on one side of the first filter means to discharge impurities or foreign substances filtered inside the first filter means. It is characterized by being composed of a.

a second filter means provided on one side of the first filter means and filtering liquid introduced therein; a second chamber means provided on one side of the second filter means and configured to accommodate fluid therein; A first connection pipe connected to the inlet pipe and allowing liquid to flow into the second filter means, and a first connection pipe connected to the discharge pipe to allow discharge of the liquid filtered by the second filter means. It is characterized by comprising two connection pipes and a second back tubule provided on the other side of the second filter means and allowing the discharge of impurities or foreign substances filtered from the inside of the second filter means.

A first valve member is provided on one side of the inlet pipe to selectively block the inflow of liquid into the first filter means, and on one side of the first connection pipe is provided to selectively block the inflow of liquid into the second filter means. A second valve member is provided to enable the liquid to be discharged, and a third valve member is provided on one side of the discharge pipe to selectively block the discharge of liquid from the first filter means, and on one side of the second connection pipe. A fourth valve member is provided to selectively block the discharge of liquid from the second filter means, and a fifth valve member is provided on one side of the first back tubule to selectively block the discharge of fluid from the first filter means. A valve member is provided, and a sixth valve member is provided on one side of the second back tubule to selectively block discharge of fluid from the second filter means.

A seventh valve member is provided on one side of the first chamber means to adjust the discharge flow rate of the fluid compressed inside the first chamber means, and on one side of the second chamber means is provided on the inside of the second chamber means. It is characterized in that an eighth valve member is provided so that the discharge flow rate of the compressed fluid can be adjusted.

Between the discharge pipe and the second connection pipe, a part of the liquid discharged from the first filter means can be diverted to the second filter means, or a part of the liquid discharged from the second filter means can be diverted to the first filter means. It is characterized by being provided with a bypass pipe that allows.

On one side of the bypass pipe, a ninth valve member is provided to adjust the amount of fluid supplied through the bypass pipe.

A first sensor member is provided on one side of the inlet pipe to measure the pressure of the liquid flowing into the interior through the inlet pipe, and a second sensor member is provided on one side of the discharge pipe to measure the pressure of the liquid discharged through the discharge pipe. It is characterized by being provided.

A control means is provided on one side of the first filter means to control the first to ninth valve members, and the control means automatically receives information from the first sensor member and the second sensor member. It is characterized in that it is programmed so that backwashing of the first filter means or the second filter means can be performed, or the backwashing of the first filter means or the second filter means can be performed according to a user's selection or a preset cycle.

The first filter means and the second filter means include a filter housing that has an external shape and allows fluid to be accommodated therein, a partition provided inside the filter housing and dividing the interior of the filter housing, and the partition. At least one coupling part is formed on one side of the unit and allows the filter member to be coupled, and is provided on one side of the coupling part to enable filtration of liquid flowing into the inside of the filter housing from the inflow pipe or the first connection pipe. It is characterized in that it includes a filter unit.

The filter unit includes a filter tube that has a hollow interior so that a plurality of parts can be accommodated therein, and a filter member that is provided inside the filter tube and allows filtration of fluid flowing into the filter tube. And, it is formed to extend from one end to the other end along the inner ring of the filter tube and is characterized by including a rotational flow inducing member that allows rotational flow to be generated during the backwashing process.

The inner diameter of the rotational flow inducing member gradually increases from one end to the other end, the separation distance between the screw threads gradually increases from one end to the other end, and the contact surface in contact with the fluid during the backwashing process is formed at an angle of 40 to 50 degrees from the filter tube. It is characterized by

A distribution member is provided inside the filter member to distribute the flow rate of the fluid from one end to the other end in the process of supplying fluid from one end to the other end of the filter member for backwashing.

One end of the filter tube is provided with a first coupling member that can be inserted into the coupling portion, and the other end of the filter tube is provided with a second coupling member that can be inserted into the interior of the prevention portion, and one side of the filter portion It is characterized by being provided with a prevention part that prevents the flow of the filter part by being combined with a plurality of filter parts.

The rust removal filter system according to the present invention has the following effects.

The present invention has the advantage that the cleaning effect of the filter member by backwashing can be maximized by providing a rotating flow inducing member and a distribution member.

The present invention has the advantage of allowing a uniform cleaning effect to be achieved throughout the filter member by gradually increasing the separation distance between the inner diameter of the rotational flow inducing member and the screw thread.

The present invention has the advantage that filtration can be continuously performed even during the backwashing process by providing a pair of filter means.

The present invention has the advantage of being able to backwash the filter unit through operating pressure as the chamber means is provided.

In the present invention, by providing a bypass pipe, there is an advantage that rinsing of another filter unit can be performed even during the filtration process of one filter unit.

The present invention has the advantage of being able to automatically perform backwash according to the user's selection or a preset cycle by providing a control means.

In the present invention, since the first sensor member and the second sensor member are provided, there is an advantage in that backwashing can be automatically performed through the pressure difference between the inlet pipe and the discharge pipe.

1 is a cross-sectional view showing the configuration of a preferred embodiment of the rust removal filter system according to the present invention.
Figure 2 is a cross-sectional view showing filtration by a first filter means constituting a preferred embodiment of the rust removal filter system according to the present invention.
Figure 3 is a cross-sectional view showing the closure of the first valve member, third valve member, and fifth valve member before backwashing by the first chamber means constituting a preferred embodiment of the rust removal filter system according to the present invention.
Figure 4 is a cross-sectional view showing backwashing by the first chamber means constituting a preferred embodiment of the rust removal filter system according to the present invention.
Figure 5 is an enlarged view showing the configuration of a partition part constituting a preferred embodiment of the rust removal filter system according to the present invention.
Figure 6 is a schematic diagram showing the configuration of another preferred embodiment of the rust removal filter system according to the present invention.
Figure 7 is a cross-sectional view showing filtration by the first filter means and backwashing by the second chamber means constituting another preferred embodiment of the rust removal filter system according to the present invention.
Figure 8 is a cross-sectional view showing filtration by the first filter means and rinsing of the second filter means through a bypass pipe, constituting another preferred embodiment of the rust removal filter system according to the present invention.
Figure 9 is a cross-sectional view showing backwashing by the first chamber means and filtration by the second filter means constituting another preferred embodiment of the rust removal filter system according to the present invention.
Figure 10 is a cross-sectional view showing filtration by the second filter means and rinsing of the first filter means through a bypass pipe, constituting another preferred embodiment of the rust removal filter system according to the present invention.
Figure 11 is an internal perspective view showing the configuration of the filter part constituting a preferred embodiment of the rust removal filter system according to the present invention.
Figure 12 is a cross-sectional view showing the configuration of the filter part constituting a preferred embodiment of the rust removal filter system according to the present invention.

Hereinafter, a preferred embodiment of the rust removal filter system according to the present invention will be described with reference to the drawings.

1 to 12 show an embodiment of a rust removal filter system according to the present invention. That is, Figure 1 shows a cross-sectional view showing the configuration of a preferred embodiment of the rust removal filter system according to the present invention, and Figure 2 shows a first filter means constituting a preferred embodiment of the rust removal filter system according to the present invention. A cross-sectional view showing filtration is shown, and Figure 3 shows a first valve member, a third valve member, and a fifth valve member before backwashing by the first chamber means, which constitutes a preferred embodiment of the rust removal filter system according to the present invention. A cross-sectional view showing the closure of the valve member is shown, Figure 4 shows a cross-sectional view showing backwashing by the first chamber means constituting a preferred embodiment of the rust removal filter system according to the present invention, and Figure 5 shows the present invention. An enlarged view of the main part showing the configuration of a partition constituting a preferred embodiment of the rust removal filter system according to the present invention is shown, and Figure 6 shows a schematic diagram showing the configuration of another preferred embodiment of the rust removal filter system according to the present invention. 7 is a cross-sectional view showing filtration by the first filter means and backwashing by the second chamber means, which constitutes another preferred embodiment of the rust removal filter system according to the present invention, and FIG. 8 shows the present invention. A cross-sectional view showing filtration by the first filter means and rinsing of the second filter means through a bypass pipe constituting another preferred embodiment of the rust removal filter system according to the present invention is shown, and Figure 9 shows the rust removal filter according to the present invention. A cross-sectional view showing backwashing by the first chamber means and filtration by the second filter means constituting another preferred embodiment of the system is shown, and Figure 10 shows another preferred embodiment of the rust removal filter system according to the present invention. A cross-sectional view showing filtration by the second filter means and rinsing of the first filter means through a bypass pipe is shown, and Figure 11 shows the configuration of the filter unit constituting a preferred embodiment of the rust removal filter system according to the present invention. An internal perspective view is shown, and Figure 12 shows a cross-sectional view showing the configuration of the filter unit constituting a preferred embodiment of the rust removal filter system according to the present invention.

As shown in these drawings, the rust removal filter system according to the present invention includes a first filter means 100 for filtering liquid flowing into the interior, and is provided on one side of the first filter means 100 and has a first filter means 100. An inflow pipe 110 that allows liquid to flow into the filter means 100, and an inflow pipe 110 provided on the other side of the first filter means 100 and the liquid filtered by the first filter means 100. A discharge pipe 120 that allows discharge, a first chamber means 200 provided on the other side of the first filter means 100 and capable of receiving fluid therein, and the first filter. It is provided on one side of the means 100 and includes a first back tubule 130 that allows discharge of impurities or foreign substances filtered inside the first filter means 100.

The first filter means 100 includes a filter housing 140 that has an external shape and allows fluid to be accommodated inside, and is provided inside the filter housing 140 and divides the interior of the filter housing 140. a partition 150, at least one coupling part 160 formed on one side of the partition 150 and allowing the filter member 172 to be coupled, and a coupling part 160 on one side of the coupling part 160. It is provided and configured to include a filter unit 170 that allows filtration of liquid flowing into the inside of the filter housing from the inlet pipe 110 or the first connection pipe 310.

The filter housing 140 is a part that forms the outer shape of the first filter means 100 or the second filter means 300, and has a hollow interior so that a plurality of parts can be accommodated therein.

The filter housing 140 may be provided with a separate cap 142 so that it can be opened and closed.

Liquid flows into the filter housing 140 through the inlet pipe 110.

And, a partition 150 is provided inside the filter housing 140.

The partition 150 is provided inside the filter housing 140 and is used to partition the inside of the filter housing 140.

The partition 150 is preferably configured to form a support end 141 inside the filter housing 140 and to be selectively coupled to the support end 141 so that combination and separation can be achieved. .

In this way, the partition 150 and the support end 141 may be joined by bolting or the like.

And, a coupling portion 160 is formed in the partition portion 150.

The coupling portion 160 is formed to penetrate downward from the upper surface of the partition 150 (in FIG. 5) and is a portion that allows the filter portion 170 to be inserted therein.

At least one such coupling portion 160 may be formed, and through this, the filter portion 170 may be provided in a number corresponding to the coupling portion 160.

The filter unit 170 can be inserted by the coupling part 160 configured in this way.

In addition, the filter unit 170 is coupled to the coupling unit 160.

The filter unit 170 includes a filter tube 171 that is hollow on the inside so that a plurality of parts can be accommodated therein, and is provided inside the filter tube 171 and has an inside of the filter tube 171. a filter member 172 that allows filtration of fluid flowing into the filter, and a rotary flow induction system that extends from one end to the other along the inner ring of the filter tube 171 and allows rotational flow to be generated during the backwashing process. It is composed of a member 173, etc.

The filter tube 171 forms the outer shape of the filter unit 170 and is a part that allows multiple components to be accommodated and supported therein.

This filter tube 171 has a long length in the longitudinal direction and has a shape similar to a circular pillar with a hollow interior.

In addition, a first coupling member 175 is provided at one end of the filter tube 171 to allow insertion into the interior of the coupling portion 160, and a prevention portion 174 is provided at the other end of the filter tube 171. A second coupling member 177 is provided so that it can be inserted inside.

The first coupling member 175 is provided at the right end (in FIG. 12) of the filter tube 171, and closes a portion of the open right end of the filter tube 171 and is located inside the coupling portion 160. This is the insertion area.

This first coupling member 175 is coupled to the filter tube 171 by having the left portion (in FIG. 12) having a diameter corresponding to the right end of the filter tube 171, and the right portion (in FIG. 12) having a coupling hole. By having a diameter corresponding to (161), it has a shape that is inserted into the interior of the coupling hole (161).

That is, the first coupling member 175 is formed to be stepped.

Of course, it is preferable that the first coupling member 175 be hollow on the inside so that the liquid filtered by the filter member 172 can be discharged to the outside.

In addition, among the first coupling members 175, the right side (in FIG. 12), which has a relatively small diameter so that it can be inserted into the coupling hole 161, has an O-ring groove that allows the O-ring member 180 to be inserted. (176) is formed.

The O-ring groove 176 is recessed inward from the outer ring on the right side, which has a relatively small diameter among the first coupling members 175, and is a portion that allows the O-ring member 180 to be coupled.

The O-ring member 180 is coupled to the O-ring groove 176.

The O-ring member 180 is coupled to the O-ring groove 176, and serves for coupling the coupling portion 160 and the first coupling member 175 and sealing between the coupling portion 160 and the first coupling member 175. It is to ensure that this can be achieved.

And, a second coupling member 177 is provided at the left end (in FIG. 12) of the filter tube 171.

The second coupling member 177 is provided at the left end of the filter tube 171 and is inserted into the interior of the prevention portion 174 while closing a portion of the open left end of the filter tube 171.

This second coupling member 177 is coupled to the filter tube 171 by having the right side (in FIG. 12) having a diameter corresponding to the left end of the filter tube 171, and the left side (in FIG. 12) prevents It has a diameter corresponding to the hole formed in the portion 174 and is inserted into the interior of the prevention portion 174.

That is, the second coupling member 177 is formed to be stepped.

Of course, it would be desirable for the second coupling member 177 to have a hollow interior to allow liquid to flow into the filter tube 171.

As such, a filter member 172 is provided inside the filter tube 171.

The filter member 172 is provided inside the filter tube 171 and is a part that allows filtration of liquid flowing into the filter tube 171.

This filter member 172 has a form in which filtration is performed by external pressure.

That is, the filter member 172 is configured to filter impurities from the outside while supplying liquid from the outside to the inside.

Accordingly, a plurality of filtering holes (not shown) may be formed in the filter member 172 to allow the inflow of liquid while preventing the inflow of impurities.

These filtering holes preferably have a diameter of 0.01 μm to 0.1 μm.

For example, the filter member 172 is made of PP (polypropylene) or PVDF (polyvinylidene fluoride).

In this way, liquid is filtered by the filter member 172.

Meanwhile, a rotational flow inducing member 173 is formed on the inner ring of the filter tube 171.

The rotational flow inducing member 173 is a filter tube ( This is a part where the cleaning effect of the filter tube 171 can be improved by allowing the liquid supplied into the inside of the filter tube 171 (in the backwash direction, from the top to the bottom in FIG. 7) to rotate.

This rotational flow inducing member 173 has a shape similar to a spring with a long length left and right (in FIG. 11).

That is, the rotational flow inducing member 173 is formed in a spiral shape.

In addition, the inner diameter of the rotational flow inducing member 173 gradually increases from one end to the other end, the separation distance between screw threads gradually increases from one end to the other end, and the contact surface 179 that contacts the fluid during the backwashing process is It is formed at an angle of 40 to 50 degrees from the filter tube 171.

First, the inner diameter of the rotational flow guiding member 173 gradually increases from the right end (in FIG. 11) to the left end.

This means that the distance between the inner ring of the rotational flow inducing member 173 and the outer ring of the filter member 172 gradually increases from the right end to the left end.

In addition, the separation distance between the screw threads of the rotational flow guiding member 173 gradually increases from the right end (in FIG. 11) to the left end.

Here, the separation distance between the screw threads means a kind of pitch, and as the rotational flow inducing member 173 is formed in a spiral shape, when it comes into contact with an imaginary line (line, longitudinal direction of the rotational flow inducing member), there are multiple The dots are spaced apart and taken side by side. This refers to the distance between a random point and another adjacent point among a plurality of points.

For example, among a plurality of contact points made by contacting the outer ring of the rotational flow guiding member 173 with an imaginary line, a point located at the rightmost end (in FIG. 11) and to the left of a point located at the rightmost end The separation distance between a point located at the leftmost end and a point located to the right of a point located at the leftmost end appears longer than the separation distance between the two located points.

In this way, the inner diameter of the rotational flow guidance member 173 gradually increases, and the separation distance between the threads forming the rotational flow guidance member 173 gradually increases, from the right end (in FIG. 11) to the left end of the filter member 172. Even as the liquid for backwashing coming out of the filter member 172 gradually increases, the flow rate of the rotational flow is made the same so that the shear force for cleaning can be maintained uniformly.

) 경사지게 형성된다.At the same time, as shown in FIG. 12, the contact surface 179 where the rotational flow inducing member 173 and the liquid for backwashing come into contact is 40 to 50 degrees to the left from the inner ring of the filter tube 171 (

) is formed obliquely.

This is to ensure that a sufficient rotational flow of the liquid for backwashing can be formed by the rotational flow inducing member 173 and to facilitate the flow of the liquid for backwashing.

In addition, inside the filter member 172, there is a distribution member 178 that distributes the flow rate of the fluid from one end to the other end in the process of supplying fluid from one end to the other end of the filter member 172 for backwashing. It is provided.

The distribution member 178 is provided inside the filter member 172, and is located at the right end of the filter member 172 (in FIG. 12) during the process of supplying liquid for backwashing into the inside of the filter member 172. This is to ensure that the fluid flow rate appears the same from to the left end.

In addition, the distribution member 178 changes the direction in which fluid is supplied into the inside of the filter member 172 to the outside of the filter member 172, thereby improving cleaning power.

For this purpose, the distribution member 178 is located at the left end of the filter member 172 and has a shape similar to a cone with long left and right lengths.

That is, the separation distance between the outer ring of the distribution member 178 and the inner ring of the filter member 172 gradually decreases toward the right end of the filter member 172, and through this, the fluid supply direction can be changed and the fluid flow rate can be maintained. It is to be so.

Meanwhile, on one side of the filter unit 170, a prevention unit 174 is provided to prevent the flow of the filter unit 170 by being combined with a plurality of filter units 170.

The prevention unit 174 is provided on the lower side of the filter unit 170 (in FIG. 1) and is combined with a plurality of filter units 170 to prevent the bottom of the filter unit 170 from flowing. .

To this end, the prevention portion 174 has a shape similar to a flat plate and a hole is formed through which the second coupling member 177 can be inserted.

Of course, it would be preferable that the hole formed in the prevention portion 174 be configured so that the second coupling member 177 can be coupled through interference fit.

The first filter means 100 configured as described above filters the liquid flowing into the inside, and the second filter means 300, which will be described later, has a substantially identical configuration to the first filter means 100.

An inlet pipe 110 is provided below (in FIG. 1) the first filter means 100.

The inflow pipe 110 is provided below the first filter means 100 and allows fluid to be supplied into the first filter means 100.

At this time, the fluid supplied into the first filter means 100 through the inlet pipe 110 contains impurities such as rust.

That is, fluid is supplied into the first filter means 100 through the inlet pipe 110.

On one side of the inlet pipe 110, a first valve member 112 is provided to selectively block the inflow of liquid into the first filter means 100.

The first valve member 112 is provided in the middle of the flow path provided by the inlet pipe 110, and is capable of selectively blocking the inflow of liquid into the first filter means 100 through the inlet pipe 110. It is to make it possible.

This first valve member 112 may be made of a manual or automatic opening/closing valve.

In this way, the inflow of fluid into the first filter means 100 through the inflow pipe 110 can be selectively blocked by the first valve member 112.

In addition, a discharge pipe 120 is provided at the top of the first filter means 100 (in FIG. 1).

The discharge pipe 120 is provided on the upper right side of the first filter means 100, and allows the liquid that has been sufficiently filtered by the filter unit 170 provided inside the first filter means 100 to the outside. This is the part that allows discharge.

That is, the liquid discharged through the discharge pipe 120 has been filtered.

On one side of the discharge pipe 120, a third valve member 122 is provided to selectively block the discharge of liquid from the first filter means 100.

The third valve member 122 is provided in the middle of the flow path provided by the discharge pipe 120, and selectively discharges the liquid filtered by the first filter means 100 through the discharge pipe 120. This is so that it can be blocked.

This third valve member 122 may be made of a manual or automatic opening/closing valve.

In this way, the liquid filtered by the first filter means 100 can be selectively blocked from being discharged through the discharge pipe 120 by the third valve member 122.

And, the first chamber means 200 is provided above the first filter means 100 (in FIG. 1).

The first chamber means 200 is provided on the upper side of the first filter means 100 and is a part that allows fluid to be accommodated therein.

This first chamber means 200 is a part connected to the first filter means 100.

Additionally, the first chamber means 200 may be further equipped with a water level gauge to check the level of the liquid contained therein.

In this way, the first chamber means 200 is a part where gas is accommodated inside, and when liquid is supplied into the first filter means 100, the gas accommodated inside the first chamber means 200 is As it is compressed, some of the filtered liquid is accommodated inside the first chamber means 200.

In this way, the gas compressed inside the first chamber means 200 has the property of expanding, and in a state in which the first valve member 112, the third valve member 122, and the fifth valve member 131 are locked, When the fifth valve member 131 is opened, the liquid contained inside the first chamber means 200 is moved toward the first back tubule 130 through expansion of the gas, and through this, the first filter means 100 ) The filter unit 170 provided inside is cleaned.

In addition, a seventh valve member 210 is provided on one side of the first chamber means 200 to adjust the discharge flow rate of the fluid compressed inside the first chamber means 200.

The seventh valve member 210 is provided on the lower side (in FIG. 1) of the first chamber means 200, and discharges fluid discharged from the first chamber means 200 toward the first filter means 100. This is the part where the flow rate can be adjusted.

That is, the seventh valve member 210 is provided in the pipe connecting the first chamber means 200 and the first filter means 100.

This seventh valve member 210 corresponds to a flow control valve and may be made of a valve whose opening/closing rate can be adjusted manually or automatically.

In this way, the flow rate discharged from the inside of the first chamber means 200 is controlled by the seventh valve member 210.

Additionally, a first back tubule 130 is provided below (in FIG. 1) the first filter means 100.

The first backwash tube 130 is provided below the first filter means 100 and is a part that allows liquid mixed with impurities to be discharged to the outside through backwashing.

That is, the liquid used for backwashing can be discharged to the outside through the first backwash pipe 130.

In the present invention, a portion of the first back tubule 130 is connected to the inlet pipe 110, but the first back tubule 130 and the inlet pipe 110 may be provided separately.

On one side of the first back tubule 130, a fifth valve member 131 is provided to selectively block the discharge of fluid from the first filter means 100.

The fifth valve member 131 is provided in the middle of the flow path provided by the first back tubule 130, and is capable of selectively blocking the discharge of the liquid used for backwashing through the first back tubule 130. It is to make it possible.

This fifth valve member 131 may be made of a manual or automatic opening/closing valve.

In this way, the fifth valve member 131 can selectively block the liquid used for backwashing from being discharged through the first backwash pipe 130.

In this way, when the first filter means 100 is configured to allow filtration of the liquid, the filtration of the liquid cannot be performed in a situation where the first filter means 100 is backwashed.

Therefore, the rust removal filter system according to the present invention includes the first filter means 100, the first chamber means 200, the inlet pipe 110, the discharge pipe 120, and the first back tubule 130. A second filter means 300 is provided on one side of the first filter means 100 and filters the liquid flowing into the inside, and a second filter means 300 is provided on one side of the second filter means 300 and can accommodate fluid therein. A second chamber means 400, a first connection pipe 310 connected to the inflow pipe 110 and allowing liquid to flow into the second filter means 300, and the discharge pipe A second connection pipe 320 is connected to (120) and allows discharge of the liquid filtered by the second filter means 300, and is provided on the other side of the second filter means 300 and a second It further includes a second back tubule 330 that allows discharge of impurities or foreign substances filtered from the inside of the filter means 300.

The second filter means 300 is provided on the right side (in FIG. 6) of the first filter means 100.

Since the second filter means 300 has the same structure and function as the first filter means 100, detailed description will be omitted.

In this way, the first connection pipe 310 is provided below (in FIG. 6) the second filter means 300.

The first connection pipe 310 is provided on the lower side of the second filter means 300 and is connected to the inlet pipe 110 so that the fluid flows into the second filter means 300 through the inflow pipe 110. This is the area where the supply of

On one side of the first connection pipe 310, a second valve member 311 is provided to selectively block the inflow of liquid into the second filter means 300.

The second valve member 311 is provided in the middle of the flow path provided by the first connection pipe 310, and the second filter means 300 flows through the inflow pipe 110 and the first connection pipe 310. ) so that the inflow of liquid into the chamber can be selectively blocked.

This second valve member 311 may be made of a manual or automatic opening/closing valve.

In this way, the inflow of fluid into the second filter means 300 through the inlet pipe 110 and the first connection pipe 310 can be selectively blocked by the second valve member 311.

Of course, in order to allow liquid to be supplied into the second filter means 300 through the first connection pipe 310, the first valve member 112 provided in the inlet pipe 110 must be closed. .

Conversely, in order to allow liquid to be supplied into the first filter means 100 through the inlet pipe 110, the second valve member 311 provided in the first connection pipe 310 must be closed. .

In addition, the first connection pipe 310 may be preferably connected to the inflow pipe 110 so that liquid can be supplied from the inflow pipe 110 even when the first valve member 112 is closed.

In addition, a second connection pipe 320 is provided on the upper side (in FIG. 6) of the second filter means 300.

The second connection pipe 320 is provided on the upper side of the second filter means 300 and is connected to the discharge pipe 120 so that it is provided inside the second filter means 300 through the discharge pipe 120. This is a part where liquid that has been sufficiently filtered by the filter unit 170 can be discharged to the outside.

On one side of the second connection pipe 320, a fourth valve member 321 is provided to selectively block the discharge of liquid from the second filter means 300.

The fourth valve member 321 is provided in the middle of the flow path provided by the second connection pipe 320, and the second filter means 300 is provided through the second connection pipe 320 and the discharge pipe 120. ) so that the discharge of the filtered liquid can be selectively blocked.

This fourth valve member 321 may be made of a manual or automatic opening/closing valve.

In this way, discharge of the liquid filtered by the second filter means 300 through the second connection pipe 320 and the discharge pipe 120 can be selectively blocked by the fourth valve member 321.

Of course, in order to allow the liquid filtered by the second filter means 300 to be discharged through the second connection pipe 320, the third valve member 122 provided in the discharge pipe 120 must be closed. will be.

Conversely, in order to allow the liquid filtered by the first filter means 100 to be discharged through the discharge pipe 120, the fourth valve member 321 provided in the second connection pipe 320 must be locked. will be.

In addition, the second connection pipe 320 may be preferably connected to the discharge pipe 120 so that liquid can be discharged through the discharge pipe 120 even when the third valve member 122 is closed.

And, a second chamber means 400 is provided above the second filter means 300 (in FIG. 6).

The second chamber means 400 is provided on the upper side of the second filter means 300 and is a part that allows fluid to be accommodated therein.

This second chamber means 400 is a part connected to the second filter means 300.

Additionally, the first chamber means 400 may be further equipped with a water level gauge to check the level of the liquid contained therein.

In this way, the second chamber means 400 is a part where gas is accommodated inside, and when liquid is supplied into the second filter means 300, the gas accommodated inside the second chamber means 400 is As it is compressed, a portion of the filtered liquid is accommodated inside the second chamber means 400.

In this way, the gas compressed inside the second chamber means 400 has the tendency to expand, and in a state in which the second valve member 311, the fourth valve member 321, and the sixth valve member 331 are locked, When the sixth valve member 331 is opened, the liquid contained in the second chamber means 400 moves toward the second back tubule 330 through expansion of the gas, and through this, the second filter means 300 ) The filter unit 170 provided inside is cleaned.

In addition, on one side of the second chamber means 400, an eighth valve member 410 is provided to adjust the discharge flow rate of the fluid compressed inside the second chamber means 400.

The eighth valve member 410 is provided on the lower side (in FIG. 6) of the second chamber means 400, and discharges fluid discharged from the second chamber means 400 toward the second filter means 300. This is the part where the flow rate can be adjusted.

That is, the eighth valve member 410 is provided in the pipe connecting the second chamber means 400 and the second filter means 300.

This eighth valve member 410 corresponds to a flow control valve and may be made of a valve whose opening/closing rate can be adjusted manually or automatically.

As such, the flow rate discharged from the inside of the second chamber means 400 is controlled by the eighth valve member 410.

Additionally, a second back tubule 330 is provided below (in FIG. 6) the second filter means 300.

The second backwash tube 330 is provided below the second filter means 300 and is a part that allows liquid mixed with impurities to be discharged to the outside through backwashing.

That is, the liquid used for backwashing can be discharged to the outside through the second backwash pipe 330.

In the present invention, a portion of the second back tubule 330 is configured to be connected to the first connection pipe 310, but the second back tubule 330 and the first connection pipe 310 may be provided separately. will be.

On one side of the second back tubule 330, a sixth valve member 331 is provided to selectively block the discharge of fluid from the second filter means 300.

The sixth valve member 331 is provided in the middle of the flow path provided by the second back tubule 330, and is capable of selectively blocking the discharge of the liquid used for backwashing through the second back tubule 330. It is to make it possible.

This sixth valve member 331 may be made of a manual or automatic opening/closing valve.

In this way, the sixth valve member 331 can selectively block the liquid used for backwashing from being discharged through the second backwash pipe 330.

In this way, when the second filter means 300 is configured to filter the liquid, the liquid cannot be filtered in a situation where the second filter means 300 is backwashed.

At this time, by allowing filtration by the first filter means 100 to be performed, discharge of the filtration liquid through the discharge pipe 120 can be continued.

That is, by further providing a second filter means 300 together with the first filter means 100, filtration of the second filter means 300 can be performed during the backwashing process of the first filter means 100, By allowing the first filter means 100 to perform filtration during the backwashing process of the second filter means 300, the filtered liquid can be continuously supplied through the discharge pipe 120.

Meanwhile, between the discharge pipe 120 and the second connection pipe 320, a portion of the liquid discharged from the first filter means 100 can be bypassed to the second filter means 300 or A bypass pipe 500 is provided to allow a portion of the liquid discharged from 300 to be bypassed to the first filter means 100.

The bypass pipe 500 is provided between the discharge pipe 120 and the second connection pipe 320 and corresponds to a pipe connecting the discharge pipe 120 and the second connection pipe 320.

This bypass pipe 500 allows some of the filtered liquid to be supplied to the second filter means 300 in the process of discharging the filtered liquid discharged from the first filter means 100 to the outside through the discharge pipe 120. It is a configuration that allows this.

That is, part of the filtered liquid discharged from the first filter means 100 is discharged to the outside through the discharge pipe 120 and is supplied into the second filter means 300 through the bypass pipe 500.

Of course, on the contrary, part of the filtered liquid discharged from the second filter means 300 is discharged to the outside through the second connection pipe 320 and the discharge pipe 120, and is discharged to the first filter means through the bypass pipe 500. It is supplied to the interior of (100).

In this way, rinsing of the filter unit 170 can be performed by allowing the filtered liquid to be supplied to the filter unit 170 on which filtration is not performed through the bypass pipe 500.

Here, rinsing means allowing impurities that are not completely removed during the backwashing process to be further removed.

On one side of the bypass pipe 500, a ninth valve member 510 is provided to adjust the amount of fluid supplied through the bypass pipe 500.

The ninth valve member 510 is provided in the middle of the flow path provided by the bypass pipe 500, and is a portion that allows the supply flow rate of fluid through the bypass pipe 500 to be adjusted.

This ninth valve member 510 corresponds to a flow control valve and may be made of a valve whose opening/closing rate can be adjusted manually or automatically.

In this way, the supply flow rate through the bypass pipe 500 is adjusted by the ninth valve member 510.

Meanwhile, a first sensor member 111 is provided on one side of the inlet pipe 110 to measure the pressure of the liquid flowing into the interior through the inlet pipe 110, and a discharge pipe is provided on one side of the discharge pipe 120. A second sensor member 121 is provided to measure the pressure of the liquid discharged through (120).

A first sensor member 111 is provided outside the inlet pipe 110.

The first sensor member 111 is provided on the outside of the inlet pipe 110, and the liquid flowing into the first filter means 100 or the second filter means 300 through the inlet pipe 110 This is the part where the pressure is measured.

And, a second sensor member 121 is provided outside the discharge pipe 120.

The second sensor member 121 is provided on the outside of the discharge pipe 120, and discharges the liquid filtered from the first filter means 100 or the second filter means 300 through the discharge pipe 120. This is the part where the pressure is measured.

In this way, the pressure of the liquid supplied into the interior of the rust removal filter system according to the present invention by the first sensor member 111 and the second sensor member 121 and the pressure of the liquid discharged from the interior of the rust removal filter system according to the present invention It becomes possible to measure the pressure of a liquid.

Meanwhile, a control means 600 is provided on one side of the first filter means 100 to control the first valve member 112 to the ninth valve member 510.

The control means 600 is connected to the first valve member 112 to the ninth valve member 510, the first sensor member 111, and the second sensor member 121, and the first sensor member ( 111) and the second sensor member 121, it is a part that receives measured values and allows control of the first valve member 112 to the ninth valve member 510.

That is, the control means 600 receives information from the first sensor member 111 and the second sensor member 121 and automatically operates the backwash of the first filter means 100 or the second filter means 300. Backwashing of the first filter means 100 or the second filter means 300 is programmed to be performed, or is programmed to be performed according to a user's selection or a preset cycle.

Therefore, when the difference between the measured value measured from the first sensor member 111 and the measured value measured from the second sensor member 121 exceeds a certain value, it is determined that impurities have accumulated in the filter unit 170, and Backwashing of the first filter means 100 or the second filter means 300 may be achieved through control (opening and closing adjustment) of the first valve member 112 to the ninth valve member 510.

In addition, backwashing of the first filter means 100 or the second filter means 300 through control of the first valve member 112 to the ninth valve member 510 according to the user's selection through the control means 600. may come true.

In addition, a backwash cycle is set inside the control means 600, and the first filter means 100 or the first filter means 100 is controlled through control of the first valve member 112 to the ninth valve member 510 according to the preset cycle. 2 Backwashing of the filter means 300 may be performed.

In this way, as the first sensor member 111, the second sensor member 121, and the control means 600 are provided, backwashing can be performed according to the specific situation desired by the user.

In the rust removal filter system according to the present invention, the cleaning effect of the filter member by backwashing can be maximized by providing a rotating flow inducing member and a distribution member.

In the rust removal filter system according to the present invention, the separation distance between the inner diameter of the rotational flow inducing member and the screw thread can be gradually increased, so that an even cleaning effect can be achieved throughout the filter member.

In the rust removal filter system according to the present invention, a pair of filter means is provided, so that filtration can be continuously performed even during the backwashing process.

In the rust removal filter system according to the present invention, since the chamber means is provided, backwashing of the filter part can be performed through operating pressure.

In the rust removal filter system according to the present invention, since a bypass pipe is provided, rinsing of the other filter means can be performed even during the filtration process of one filter means.

Since the rust removal filter system according to the present invention is equipped with a control means, backwashing can be automatically performed according to a user's selection or a preset cycle.

In the rust removal filter system according to the present invention, as the first sensor member and the second sensor member are provided, backwashing can be automatically performed through the pressure difference between the inlet pipe and the discharge pipe.

The scope of the present invention is not limited to the embodiments illustrated above, and many other modifications based on the present invention will be possible to those skilled in the art within the above technical scope.

100. First filter means 110. Inlet pipe
111. First sensor member 112. First valve member
120. Discharge pipe 121. Second sensor member
122. Third valve member 130. First back tubule
131. Fifth valve member 140. Filter housing
141. Support end 142. Cap
150. Partition 160. Joint part
170. Filter unit 171. Filter tube
172. Filter member 173. Rotational flow induction member
174. Prevention unit 175. First coupling member
176. O-ring groove 177. Second coupling member
178. Absence of distribution 179. Contact surface
180. O-ring member 200. First chamber means
210. Seventh valve member 300. Second filter means
310. First connector 311. Second valve member
320. Second connector 321. Fourth valve member
330. Second back tubule 331. Sixth valve member
400. Second chamber means 410. Eighth valve member
500. Bypass pipe 510. Ninth valve member
600. Control measures

Claims (13)

a first filter means for filtering the liquid introduced therein;
an inflow pipe provided on one side of the first filter means and allowing liquid to flow into the first filter means;
a discharge pipe provided on the other side of the first filter means and allowing the liquid filtered by the first filter means to be discharged;
a first chamber means provided on the other side of the first filter means and configured to accommodate fluid therein;
a first back tubule provided on one side of the first filter means and allowing discharge of impurities or foreign substances filtered within the first filter means;
a second filter means provided on one side of the first filter means and filtering liquid introduced therein;
a second chamber means provided on one side of the second filter means and configured to accommodate fluid therein;
a first connection pipe connected to the inflow pipe and allowing liquid to flow into the second filter means;
a second connection pipe connected to the discharge pipe and allowing discharge of the liquid filtered by the second filter means;
A second back tubule is provided on the other side of the second filter means and allows discharge of impurities or foreign substances filtered inside the second filter means,
Between the discharge pipe and the second connection pipe, a part of the liquid discharged from the first filter means can be diverted to the second filter means, or a part of the liquid discharged from the second filter means can be diverted to the first filter means. A rust removal filter system characterized in that it is provided with a bypass pipe that allows delete According to claim 1,
A first valve member is provided on one side of the inflow pipe to selectively block the inflow of liquid into the first filter means,
A second valve member is provided on one side of the first connection pipe to selectively block the inflow of liquid into the second filter means,
A third valve member is provided on one side of the discharge pipe to selectively block discharge of liquid from the first filter means,
A fourth valve member is provided on one side of the second connection pipe to selectively block the discharge of liquid from the second filter means,
A fifth valve member is provided on one side of the first back tubule to selectively block discharge of fluid from the first filter means,
A rust removal filter system, characterized in that a sixth valve member is provided on one side of the second back tubule to selectively block the discharge of fluid from the second filter means. According to claim 1,
A seventh valve member is provided on one side of the first chamber means to adjust the discharge flow rate of the fluid compressed inside the first chamber means,
A rust removal filter system, characterized in that an eighth valve member is provided on one side of the second chamber means to adjust the discharge flow rate of the fluid compressed inside the second chamber means. delete According to claim 1,
A rust removal filter system, characterized in that a ninth valve member is provided on one side of the bypass pipe to adjust the amount of fluid supplied through the bypass pipe. According to claim 1,
A first sensor member is provided on one side of the inlet pipe to measure the pressure of liquid flowing into the inlet pipe,
A rust removal filter system, characterized in that a second sensor member is provided on one side of the discharge pipe to measure the pressure of the liquid discharged through the discharge pipe. According to claim 1,
A control means for controlling the first to ninth valve members is provided on one side of the first filter means,
The control means is programmed to receive information from the first sensor member and the second sensor member and automatically perform backwashing of the first filter means or the second filter means, or to perform the first filter according to the user's selection or a preset cycle. A rust removal filter system, characterized in that it is programmed so that backwashing of the filter means or the second filter means can be performed. According to claim 1,
The first filter means and the second filter means,
A filter housing that forms an external shape and allows fluid to be accommodated therein;
a partition provided inside the filter housing and dividing the inside of the filter housing;
At least one coupling part is formed on one side of the partition and allows the filter member to be coupled;
A rust removal filter system comprising a filter unit provided on one side of the coupling unit and configured to filter liquid flowing into the filter housing from the inlet pipe or the first connection pipe. According to clause 9,
The filter unit,
A filter tube that is hollow on the inside and allows a plurality of parts to be accommodated therein;
a filter member provided inside the filter tube to filter fluid flowing into the filter tube;
A rust removal filter system comprising a rotary flow inducing member formed to extend from one end to the other end along the inner ring of the filter tube and allowing a rotary flow to be generated during a backwashing process. According to claim 10,
The inner diameter of the rotational flow inducing member gradually increases from one end to the other end, the separation distance between the screw threads gradually increases from one end to the other end, and the contact surface in contact with the fluid during the backwashing process is inclined 40 to 50 degrees from the filter tube. Rust removal filter system featuring. According to claim 10,
A rust removal filter system characterized in that a distribution member is provided inside the filter member to distribute the flow rate of the fluid from one end to the other end in the process of supplying fluid from one end to the other end of the filter member for backwashing. According to claim 10,
At one end of the filter tube, a first coupling member is provided so that it can be inserted into the coupling portion,
At the other end of the filter tube, a second coupling member is provided so that it can be inserted into the prevention portion,
A rust removal filter system, characterized in that a prevention unit is provided on one side of the filter unit to prevent the filter unit from flowing by being combined with a plurality of filter units.

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