KR100492487B1 - Non-motorized sand filtering apparatus - Google Patents

Abstract

The present invention relates to a non-powered sand filtration device, in particular, to a non-powered sand filtration device, characterized in that the natural filtration and backwashing is possible by using the fall of the precipitation device during the filtration process of particulate matter in the wastewater,

A filter material stacking box in which fine sand, coarse sand, gravel, and filter plates are sequentially stacked; A raw water inlet pipe connected to an upper portion of the filter stack box to supply raw water containing suspended solids; A raw water distribution pipe connected to an end of the raw water inlet pipe and configured to evenly distribute raw water to a filter material stacking box; A treated water discharge pipe connected to a lower portion of the filter medium stacking box and discharging the treated water passing through the filtration layer; A treatment water tank installed at a lower portion of the treatment water discharge pipe and containing the final treatment water passing through the filter medium stacking box; A backwashing water inlet pipe connected to one side of the bottom of the filter media stacking box to provide backwashing water; A backwash water discharge pipe for discharging the backwash water to a raw water tank; The washing water discharge pipe is connected to the backwash water discharge pipe and the filtered water discharge pipe to discharge the washing water passing through the filtered water discharge pipe to the raw water tank.

Description

Non-motorized sand filtering apparatus

The present invention relates to a non-powered sand filtration device, and more particularly to a non-powered sand filtration device, characterized in that the natural filtration and backwashing is possible by using the free fall of the precipitation device during the filtration process of particulate matter in the waste water.

In general, when filtration, coagulation, and sedimentation methods are used to remove particulate matter in the wastewater, and filtration processes are required to be treated to below the standard values of water supply protection zones, sedimentation zones and special areas where the emission standards are difficult. Conventionally, a pressure sand filter or a fiber yarn filter has been adopted.

However, the pressure sand filter or fiber yarn filter requires many auxiliary devices such as a pumping tank, a filtration pump, a backwash tank, a backwash pump, a water level meter, an automatic control panel, a differential pressure gauge, etc. due to its structural characteristics. It caused inconvenience.

The present invention is to solve the above problems, the object of the filtration and backwashing is possible using a drop (water head tea) of the precipitation device.

In addition, there is another purpose to ensure that only the cleanest water is discharged to the outside in the state of removing the lump of the tank for storing the treated water.

As a means for achieving the above object,

The present invention is a filter material stacking box in which fine sand, coarse sand, gravel and filter plates are sequentially stacked; A raw water inlet pipe connected to an upper portion of the filter stack box to supply raw water containing suspended solids; A raw water distribution pipe 20 connected to the end of the raw water inflow pipe 10 for evenly distributing raw water to the filter medium stacking box 100; A treated water discharge pipe 30 connected to a lower portion of the filter medium stacking box 100 and discharging the treated water passing through the filtration layer; A treatment water tank 200 installed at a lower portion of the treatment water discharge pipe 30 and containing the final treatment water passing through the filter medium stacking box 100; A backwashing water inlet pipe 50 connected through a lower side of the filter material stacking box 100 to provide backwashing water; A backwash water discharge pipe 40 for discharging the backwash water to a raw water tank; The backwash water discharge pipe 40 and the filtered water discharge pipe 30 is characterized in that consisting of the washing water discharge pipe 60 for discharging the washing water passing through the filtered water discharge pipe 30 to the raw water tank.

In addition, the upper inner wall of the filter medium stacking box 100, the backwash water discharge partition 150 for outputting the raw water raised to a constant height; It is characterized in that it further comprises a water level detecting device (90) installed on the backwash water discharge partition (150) to check whether the raw water rises above a certain height.

In addition, the air cleaning pipe (80) connected through the side surface of the lower side of the filter medium stacking box (100); It is characterized in that it further comprises a backwashing air distribution pipe (70) installed at the end of the air cleaning pipe (80) for blowing air provided from the blower into the box.

In addition, the raw water distribution pipe is a vertical line 22, a raw water input hole 28 formed in the center of the vertical line 22, and a horizontal line 24 connected to the plurality of vertical lines 22 And a plurality of holes 26 for passing raw water are formed in the lower portion of the horizontal line 24.

In addition, the backwash air distribution pipe 80 is made of a cross-shaped pipe 82, the air inlet hole 86 is formed in the center, the air ejection hole 84 is characterized in that the remaining surface is formed to be.

In addition, the treatment tank 200 faces the first partition wall 210 so that only a constant constant height passes through the first partition wall 210 having a lower portion installed at a point where raw water flows in such that the treated water is first collected. The other side of the beam is characterized in that it further comprises a second partition wall 220 is installed at a height lower than the height of the tank (200).

In addition, the raw water inlet pipe 10 is provided with a raw water inlet control valve 10a for controlling the input of raw water to the filter medium stacking box 100, the filter medium stacking box 100 in the filtered water discharge pipe 30 A treated water discharge control valve 30a is installed to control the discharge of the treated water, and the backwashed water inflow pipe 50 controls the backwashed water inflow control valve 50a for controlling backwash water input into the filter medium stacking box 100. ) Is installed, the air cleaning pipe 70 is provided with an air control valve (70a) for controlling the supply of air to the filter medium stacking box 100, the raw water inlet pipe 10 and filtration during the filtration process Open the valves 10a and 30a so that the treated water discharge pipe 30 is connected to each other, and at the time of backwashing, the valve 50a of the backwashing water inlet pipe 50 and the backwash water discharge pipe 40 and the air washing pipe 70 , 70a) respectively, and the raw water inlet pipe ( 10) and a control unit 300 for controlling to open the valve (10a) of the washing water discharge pipe (60).

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings. In addition, in the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

1 is a view showing the main configuration of the present invention,

The present invention is largely composed of the filter medium laminated box 100 and the treatment tank 200.

The filter medium stacking box 100 is configured by inputting various filtration materials, and the raw water flows into the filter medium stacking box so that the treated water is output while the pollutants are removed through the filter material. The structure is discharged after temporary storage at 200.

First, the contents of the filter medium stacking box 100 will be described. A thin sand layer 110 is formed on the top layer, a coarse sand layer 120 is formed below, and a gravel layer 130 is formed thereunder. The filter plate 140 is formed below it.

And, the top of the filter medium stacking box 100 is provided with a raw water distribution pipe 20 for evenly distributing the raw water, the bottom of the filter medium stacking box 100 to supply air to assist backwashing Backwash air distribution pipe (80) is installed.

The raw water inlet pipe 20 is connected to the raw water inlet pipe 10, the raw water introduced through the raw water inlet pipe 10 is introduced into the filter medium stacking box 100 via the raw water distribution pipe 20, and the filter medium is laminated. The treated water filtered through the box 100 is discharged through the lower filtered water discharge pipe 30 and temporarily stored in the treated water tank 200.

The backwash water discharge pipe 40 is connected to an upper side of the filter medium stacking box 100 and connected to a raw water tank, and the backwash water inlet pipe connecting the raw water inlet pipe 10 and the lower end of the filter medium stacking box 100 to each other. 50 is further connected.

Then, the air washing pipe 70 is connected through one side of the distribution pipe 80 of the backwashing air, and the washing water discharge pipe 60 is disposed between the filtered water discharge pipe 30 and the backwash water discharge pipe 40. Connected.

In addition, the upper inner circumference of the filter medium stacking box 100 is provided with a backwashing water discharge partition 150, and the raw water is supplied to the filter medium stacking box 100 while passing the backwashing water discharge partition 150. When it stops, stop feeding and backwash.

The treatment water distribution pipe 20 is composed of one vertical line 22 and a plurality of horizontal lines 24 connected to the raw water input hole 28 and the vertical line 22, the horizontal line 24 A plurality of raw water passing holes 26 are formed to uniformly output raw water introduced through the raw water input hole 28 and the vertical line 22 through the raw water passing hole 26 over the horizontal line 24. Structure.

The backwashing air distribution pipe 80 is formed of a cross-shaped pipe 82 and the pipe 82 forms one input hole 86 and a plurality of air passage holes 84 to form the backwashing air. It is a structure that evenly outputs the air introduced through the pipe 70 through the plurality of holes 84.

A control valve is installed in each of the pipes, the raw water inlet pipe 10 is provided with a raw water inlet control valve 10a, and the backwashed water inlet pipe 50 is provided with a reverse raw water inlet control valve 50a. The filtration treated water discharge pipe 30 is provided with a filtration treated water discharge control valve 30a, the rinsed water discharge pipe 80 is provided with a rinsed water discharge control valve 80a, and the air washing pipe 70 An air washing piping control valve 70a is installed.

In addition, the backwash water discharge partition 150 is provided with a detection sensor 90 for detecting that the raw water overflows.

The detection sensor 90 and the control valves 10a, 30a, 50a, 70a, and 80a are connected to the control unit 300 to command the control unit 300 according to an operation command of the detection sensor 90 and the input unit 310. Depending on the opening and closing automatically.

In addition, the treatment tank 200 is installed directly below the treated water discharge pipe 30 so that the treated water passing through the filter medium stacking box 100 does not slump and is temporarily stored, but has a lower portion of the first partition 210 opened to a predetermined length. It further comprises a secondary partition wall 220 to allow the constant of the water discharged to the outside after passing through the treatment tank 200 passes.

Hereinafter, the operation of the present invention will be described.

First, in the filtration process state, the raw water inflow control valve 10a is opened and the filtered water discharge control valve 30a is opened, and the raw water passing through the raw water inflow pipe 10 is filtered through the filter medium stacking box 100. Flow into the treatment tank (200).

To solve this, in the filtration process state, the raw water enters the filter medium stacking box 100 through the raw water inlet control valve 10a, the raw water inlet pipe 10 and the raw water distribution pipe 20, and the filter medium stacking box ( 100 is filtered through the fine sand layer 110, the coarse sand layer 120 and the gravel layer 130 and the filter plate 140, and then filtered filtration water discharge pipe 30 and the valve for controlling the discharge of filtration water 30a. Pass through the treatment tank 200 is entered.

Of course, the remaining valves remain closed.

At this time, the natural filtration proceeds by a natural free fall according to the height between the raw water inlet pipe 10 and the filtered water discharge pipe 30 without using a separate pump in treating the raw water with the treated water.

That is, since the raw water inlet pipe 10 is located at a position higher than that of the filter medium stacking box 100, and the treatment water tank 200 is located below the filter medium stacking box 100, a natural filtration process is performed by free fall due to gravity. will be.

On the other hand, if filtration continues as described above, suspended solids are gradually accumulated in the sand layers 110 and 120 and the gravel layer 130, and the filtration function is gradually lost. Will slowly rise upwards.

When the raw water reaches the end of the backwash water discharge partition 150, it is checked by the water level sensor 90 to open the backwash water inlet valve 50a to remove the backwash water from the lower portion of the filter medium stacking box 100. Supply to backwash.

That is, when the backwash water discharge partition 150 is crossed, it detects this and opens the backwash water inflow valve 50a and simultaneously closes the original water inflow control valve 10a and the filtered water discharge control valve 30a. The backwashed raw water flows through the backwashed water inlet pipe 50 to reach the lower end of the filter medium stacking box 100, and then passes through the filtration membrane 140, the gravel layer 130, the coarse sand layer 120, and the thin sand layer 110. It flows to the backwash water discharge pipe 40 beyond the partition 150.

At this time, since the line for supplying the backwash water is located at a higher position than the filter material stacking box 100, a natural backwash line is formed due to a drop, thereby backwashing the various filter layers while removing floating materials.

Meanwhile, in the present invention, backwashing according to gravity is also possible, but in order to make the backwashing more smooth, a structure capable of blowing backwashing air is further added. The pipe 80 is installed, and the backwashing air distribution pipe 80 is connected through the air cleaning pipe 70, and the air cleaning pipe is connected to the blower.

Therefore, the air is provided through the blower and the air cleaning pipe 70 so that the backwashing action of the suspended solids present in the filtration layer is performed at a high speed. The valve installed in the air cleaning pipe 70 ( When 70a) is opened, air is provided at the lower portion of the filter stack stacking box 100, and the air is used to increase the performance of the backwashing by allowing the backwashing water to rise rapidly to the top.

Finally, after the backwashing process, the washing process is carried out. The floating material is scattered in the filtration layer by the backwashing process, and the raw material is supplied from the upper part and transported back to the raw water tank again. To remove it again.

In the present invention, for this purpose, the washing water discharge pipe 60 was installed between the filter treatment water discharge pipe 30 and the backwash water discharge pipe 40, and the raw water inlet control valve 10a was opened through the raw water inlet pipe 10. Raw water was supplied from the top of the filtration layer, and then passed through the filtration layer to be discharged to the filtered water discharge pipe 30, the washing water discharge pipe 60 and the backwash water discharge pipe 40 to feed back to the raw water tank.

As a result, the suspended solids remaining in the backwashing process were recycled again through the washing process to filter the suspended solids again, and after the backwashing for a predetermined time, the filtered water was again output to the treatment tank 200. .

The first and second partitions 210 and 220 are installed in the treatment tank 200, and the first partition 210 is installed at a predetermined height and the lower portion thereof is opened to allow the filtered water discharge pipe 80 to be opened. The treated water having passed through firstly flows into the first partition wall 210, passes through the lower part of the first partition wall 210 to the center of the water tank, and is discharged through the upper part of the second partition wall 220.

In the above, the first partition wall 210 weakens the flow of the treated water so as not to slack, so that the suspended solids remaining in the treated water remain on the bottom surface of the treated water tank 200, and the upper portion of the second partition wall 220 Only through the constant to move to the inside of the second partition wall 220 to be output to the outside.

As a result, only the clean water is passed through the treatment tank to the outside.

As described above, the present invention provides a sand filtration device but performs a filtration function by using free fall energy by gravity, and thus does not require a separate power device, which is very simple and inexpensive, and uses a small amount of space occupying the entire facility. To provide efficient advantages.

Although the present invention has been described in connection with the above-mentioned preferred description, various other modifications and variations may be made without departing from the spirit and scope of the invention. Accordingly, the appended claims may be determined to include such modifications and variations as fall within the true scope of the invention.

1 is an overall configuration diagram of the present invention.

Figure 2 is a detailed configuration of the raw water distribution pipe of the present invention.

Figure 3 is a detailed configuration of the backwash air distribution pipe of the present invention.

4 is a block diagram of a control valve and a control unit of the present invention.

Explanation of symbols on main parts of drawing

10: raw water inlet pipe 10a: raw water control valve

20: distribution pipe for raw water 22: vertical line

24: horizontal line 26: hole for passing water

28: raw water input hole 30: filtered water discharge pipe

30a: filtered water discharge pipe control valve 40: backwash water discharge pipe

50: backwash water inflow pipe 50a: backwash water inflow control valve

60: washing water discharge pipe 70: air cleaning pipe

70a: air washing control valve 80: backwash air distribution pipe

82: cross pipe 84: hole for air passage

86: hole for air input 90: water level sensor

100: lamination layer of filter medium 110: fine sand layer

120: coarse sand layer 130: gravel layer

140: filtration membrane 150: partition

200: treatment tank 210: first partition wall

220: second partition 300: control unit

310: input means

Claims (7)

A filter material stacking box 100 in which fine sand, coarse sand, gravel, and filter plates are sequentially stacked; A raw water inlet pipe 10 connected through an upper portion of the filter medium stacking box 100 to supply raw water containing suspended solids; A raw water distribution pipe 20 connected to the end of the raw water inflow pipe 10 for evenly distributing raw water to the filter medium stacking box 100; A treated water discharge pipe 30 connected to a lower portion of the filter medium stacking box 100 and discharging the treated water passing through the filtration layer; A treatment water tank 200 installed at a lower portion of the treatment water discharge pipe 30 and containing the final treatment water passing through the filter medium stacking box 100; A backwashing water inlet pipe 50 connected through a lower side of the filter material stacking box 100 to provide backwashing water; A backwash water discharge pipe 40 for discharging the backwash water to a raw water tank; Non-powered sand, characterized in that consisting of the washing water discharge pipe 60 is connected between the backwash water discharge pipe 40 and the filtered water discharge pipe 30 to discharge the washing water passing through the filtered water discharge pipe 30 to the raw water tank. Filtration device. The method of claim 1, A backwashing partition 150 for outputting raw water raised to a predetermined height on an upper inner wall of the filter medium stacking box 100; The non-powered sand filtration device, characterized in that it further comprises a water level detecting device (90) installed on the backwash water discharge partition (150) to check whether the raw water rises above a certain height. The method of claim 1, An air cleaning pipe (80) connected through one side surface of the lower portion of the filter medium stacking box (100); The non-powered sand filtration device is installed at the end of the air cleaning pipe (80) further comprises a backwash air distribution pipe (70) for blowing air provided from the blower into the box. The method of claim 1, The raw water distribution pipe is a vertical line 22, a raw water input hole 28 formed in the center of the vertical line 22, and a horizontal line 24 connected to the plurality of vertical lines 22 It is made, the non-powered sand filtration device, characterized in that a plurality of raw water passage hole 26 is formed in the lower portion of the horizontal line (24). The method of claim 1, The backwashing air distribution pipe 80 is made of a cross-shaped pipe 82, the air inlet hole 86 is formed in the center, the air blowing hole 84 is characterized in that the remaining surface is formed Powerless sand filter. The method of claim 1, The treatment tank 200 has a first partition 210 having a lower portion installed at a point where raw water is introduced so that treated water is first collected, and the other side facing the first partition 210 so that only a constant constant water passes therethrough. The non-powered sand filtration device, characterized in that it further comprises a second bulkhead 220 is installed at a height lower than the height of the tank (200). The method of claim 1, The raw water inlet pipe 10 is provided with a raw water inlet control valve 10a for controlling the raw water is input to the filter medium stacking box 100, The filtered water discharge pipe 30 is provided with a treated water discharge control valve 30a for controlling the discharge of the treated water of the filter medium stacking box 100, The backwashing water inflow pipe 50 is provided with backwashing water inflow control valve 50a for controlling backwashing water input to the filter medium stacking box 100, The air cleaning pipe 70 is provided with an air control valve 70a for controlling supply of air to the filter medium stacking box 100, In the filtration process, the valves 10a and 30a are opened to connect the raw water inlet pipe 10 and the filtered water discharge pipe 30, respectively, and during backwashing, the backwashing water inlet pipe 50 and the backwash water discharge pipe 40 And a control unit for opening the valves 50a and 70a of the air cleaning pipe 70 and opening the valves 10a of the raw water inlet pipe 10 and the washing water discharge pipe 60 during the washing process. Non-powered sand filter, characterized in that it further comprises 300).