KR101511969B1 - Foreign Material Separating Device - Google Patents

Abstract

A foreign matter separation apparatus is disclosed. A foreign material separation apparatus according to an embodiment of the present invention includes an inlet for introducing a mixture of foreign substances, a chamber communicating with the inlet and introducing the mixture, and a partition wall partitioning the interior of the chamber, A housing; And a first discharge pipe connected to the inflow nozzle and adapted to move the fluid in the mixture introduced through the inflow nozzle, wherein the inflow nozzle includes: an inflow nozzle into which the foreign matter contained in the mixture inserted into the partition and introduced into the chamber through the inflow port flows; And a plurality of discharge ports extending from the discharge port to the discharge port of the discharge port to discharge the foreign substances to the lower side of the housing, .

Description

[0001] The present invention relates to a foreign material separating device,

The present invention relates to a foreign matter separating apparatus used for separating a fluid and a foreign object from each other by using a difference in specific gravity between a marine plant facility or a facility for collecting crude oil and a mixture including foreign matter such as sand.

Generally, in an offshore plant ship or an earthy harvesting line, after the sand mixed with seawater or river is sucked, the fluid and the sand are separately separated and only the sand is stored separately, or the sand is discarded and only the fluid is stored separately.

Particularly, the offshore plant ship or gravel harvesting line is very narrow, so it is very important to separate the fluid and the sand quickly and quickly in a limited space from the viewpoint of workability and economics.

However, up to now, the equipment for separating sand has become too large or the treatment capacity has been relatively insufficient, which has caused difficulties in using the above-mentioned offshore plant vessel or soil-collecting ship to be frosted, and it became necessary to take urgent measures against this.

Korean Patent No. 10-0599535 (Registered on July 05, 2006)

Embodiments of the present invention seek to stably remove foreign matter contained in a fluid and conveniently increase or decrease the capacity according to the capacity of the mixture.

According to an aspect of the present invention, there is provided a method of manufacturing a honeycomb structure, including: a housing having an inlet port through which a mixture containing a foreign substance flows, a chamber communicating with the inlet port and into which a mixture flows, and a partition wall partitioning the interior of the chamber; And a first discharge pipe connected to the inflow nozzle and adapted to move the fluid in the mixture introduced through the inflow nozzle, wherein the inflow nozzle includes: an inflow nozzle into which the foreign matter contained in the mixture inserted into the partition and introduced into the chamber through the inflow port flows; And a plurality of discharge ports extending from the discharge port to the discharge port of the discharge port to discharge the foreign substances to the lower side of the housing, .

The housing including: a first housing communicating with the inlet; A second housing provided above the first housing and providing a space in which the fluid moved through the first discharge pipe is temporarily stored; And a third housing provided below the first housing and providing a space in which foreign matter separated through the dis- sanding tube is temporarily stored.

The partition wall having a first partition wall disposed between the first housing and the second housing and having a plurality of open ports into which the dishing pipe is inserted; And a second partition disposed between the first housing and the third housing and having a plurality of open ports into which the des- gagging tube is inserted.

The partition walls are formed in a disc shape, and the ports are arranged at equal intervals along the circumferential direction.

The foreign matter separating device includes a cap which is selectively inserted into a port to which the dis- sanding pipe is not inserted.

The foreign matter separating device selectively removes the cap according to the amount of the mixture to control the separation efficiency of the foreign matter.

The foreign matter separating apparatus comprises: a storage tank in which a large amount of a mixture is stored; A first pipe connected at one end to the storage tank and connected at the other end to an inlet of the housing; And a pump installed in the first pipe and pumping the mixture stored in the storage tank to the housing.

A flange formed on an outer side of the housing and closely adhered to upper and lower surfaces of the partition; And a fastening member installed via the flange and the partition to fix the partition.

A second slanting portion coupled to a lower side of the head portion and having a reduced diameter decreasing in a downward direction along an inner longitudinal direction, and a first dishinging tube having a thread formed along an outer lower circumferential direction; A first straight portion formed with threads along an inner circumferential direction so as to be screwed with a lower side of the first dishinging pipe and extending a predetermined length along an inner longitudinal direction, A plurality of second dishinging tubes having a second inclined portion having a reduced diameter and connected to the first dis- A first straight portion formed with a thread along the inner circumferential direction to be screwed with the lower side of the second dis- sanding tube and extending along the inner longitudinal direction to the same inner diameter, and a second linear portion extending from the lower end of the first straight portion to the inner side And a third dishing tube having a reduced third inclined portion and a second straight portion extending downward from the lower end of the third inclined portion to the same inner diameter.

And the third dischaining tube includes a step formed on the outer side so as to be engaged with the upper portion of the partition wall.

The inner diameter of the first dishing pipe is D1 connected to the head portion, and the ratio D2 = D1 / 2 is applied when the inner diameter connected to the second dishing pipe is D2.

The degassing pipe is made of stainless steel.

The foreign material separating device includes a cover plate installed on the upper surface of the first partition and installed on the upper surface of the desiccating tube and the port; And a plurality of bolts coupled from the upper surface of the cover plate toward the first partition.

According to another aspect of the present invention, there is provided an apparatus for separating foreign substances, comprising: an inflow nozzle through which a mixture of foreign substances flows directly; A head connected to the inflow nozzle and having a first discharge pipe for moving the fluid among the mixture introduced through the inflow nozzle; A second inclined portion coupled to a lower side of the head portion and having a reduced diameter decreasing in a downward direction along an inner longitudinal direction, and a first dishinging tube having a thread formed along an outer lower circumferential direction; A first straight portion formed with threads along an inner circumferential direction so as to be screwed with a lower side of the first dishinging pipe and extending a predetermined length along an inner longitudinal direction, A plurality of second dishinging tubes having a second inclined portion having a reduced diameter and connected to the first dis- And a second straight line portion having threads formed along the inner circumferential direction to be screwed with the lower side of the second dischaining tube and extending along the inner longitudinal direction to the same inner diameter, and a second linear portion extending downward from the lower end of the second linear portion A third degassing tube having a third inclined portion whose inside diameter is reduced and a third rectilinear portion extending downward from the lower end of the third inclined portion to the same inside diameter toward the lower side and the flow of the mixture introduced through the inlet nozzle is called a cyclone (cyclone) type so that only the foreign substance is discharged.

Wherein the inflow nozzle comprises a first inclined portion which is provided in a direction normal to the head portion and which extends toward the inside of the head portion and whose inner diameter is reduced toward the head portion and a second inclined portion which is provided at a front end portion of the first inclined portion, And a spray nozzle extending to a diameter that is relatively smaller than the diameter of the first reduction tube and increases the speed when the mixture introduced through the inflow nozzle is injected into the head part.

The embodiments of the present invention can change the flow of the mixture into a cyclone shape to stably separate only foreign substances contained in the fluid and conveniently increase the capacity according to the capacity of the mixture, And economic efficiency can be achieved at the same time.

Embodiments of the present invention can reliably remove various foreign substances contained in ground water, crude oil or agricultural water, and can conveniently transport only the fluid where necessary.

1 is a longitudinal sectional view showing a foreign matter separator according to an embodiment of the present invention;
2 is a sectional view taken along the line AA in Fig.
3 is a vertical cross-sectional view of a dishinging tube installed in a foreign matter separating apparatus according to an embodiment of the present invention;
Fig. 4 is a perspective view of Fig. 3; Fig.
5 is a cross-sectional view taken along BB line.
6 is a longitudinal sectional view showing a foreign matter separating apparatus according to another embodiment of the present invention.
7 is a perspective view of Fig. 6; Fig.
8 is a cross-sectional view taken along the line CC.
FIG. 9 to FIG. 11 are operational states of a foreign matter separation apparatus according to an embodiment of the present invention. FIG.
12 is an operational state diagram of a foreign matter separation apparatus according to another embodiment of the present invention.

The configuration of a foreign matter separator according to an embodiment of the present invention will be described with reference to the drawings.

1 to 5, a foreign matter separation apparatus 1 is used for separating sand mixed with a fluid in the process of collecting crude oil, gas, and gravel, and includes an inlet port A chamber 101 communicating with the inlet 102 and into which the mixture flows and a housing 100 having an inner region divided through a partition 120 partitioning the interior of the chamber 101; An inflow nozzle 200 which is inserted into the partition 120 and into which foreign matter contained in the mixture moved into the chamber 110 through the inflow opening 102 flows; A head part 210 formed with a first discharge pipe 212 for moving a fluid among the mixture introduced through the nozzle 200 and a plurality of individual parts extended toward the lower side of the head part 210, And a de-sanding tube 220 for changing the flow of the mixture introduced through the filter 200 into a cyclone shape and discharging only the foreign matter to the lower side of the housing 100.

A housing according to an embodiment of the present invention will be described with reference to the drawings.

The housing 100 is generally cylindrical in shape. The housing 100 includes a first housing 110, a second housing 120, and a third housing 130.

The first housing 110 communicates with the inlet port 102 and is located at the center of the housing 100 and has a length similar to the dishing pipe 220 described later.

The second housing 120 is provided on the upper side of the first housing 110 and provides a space for temporarily storing the fluid moved through the first discharge pipe 212 and is located on the upper side of the housing 100 The first housing 110 has a relatively smaller volume than the first housing 110.

The third housing 130 is provided at a lower side of the first housing 110 and provides a space for temporarily storing foreign matter separated through the dishing pipe 220. The third housing 130 is similar to the second housing 120 Volume. After the first to third housings 110, 120 and 130 are individually manufactured, they are held in a fixed state by the flange 101 and the fastening member 103, which will be described later. The housing 100 may be made of stainless steel to prevent corrosion and may be made of other materials that are resistant to corrosion.

A partition according to an embodiment of the present invention will be described with reference to the drawings.

The barrier rib 120 includes a first barrier rib 122 and a second barrier rib 124 which define the inner region of the housing 100 in the lateral direction.

The first partition 122 is disposed between the first housing 110 and the second housing 120 and is formed with a plurality of open ports 122a through which the desludging pipe 230 is inserted, 122a are arranged at equal intervals along the circumferential direction of the first partition 122.

When the de-sanding tube 220 is inserted into the port 122a, the upper end of the de-sanding tube 220 is retained on the upper surface of the port 122a and the lower end thereof is engaged with the step of the third dis- The first and second barrier ribs 226d and 226d are engaged with and held on the upper side of the second barrier ribs 124 and remain in a fixed state.

The second partition wall 124 is disposed between the first housing 110 and the third housing 130 and has a plurality of open ports 124a into which the desludging pipe 220 is inserted.

A cap 10 is inserted into the ports 122a and 124a at positions where the degassing pipe 220 is not installed to maintain the upper surfaces of the opened ports 122a and 124a in an enclosed state. The cap 10 is formed in the shape shown in the enlarged view, but is not necessarily limited to the above-described shape, and may be changed to another shape capable of sealing the upper surface of the ports 122a and 124a. The cap 10 is fixed to the first partition 122 and the second partition 124 by bolts.

The foreign material separating apparatus 1 includes a cover plate 20 installed on the upper surface of the first partition wall 122 and installed on the upper surface of the desiccating tube 230 and the port 122a, And a plurality of bolts 30 coupled toward the first partition 122.

The cover plate 20 is formed in a disc shape and is fixed to the desiccating tube 20 and the plurality of caps 10 at the same time so that the mixture is moved through the desiccating tube 220 at a predetermined pressure, So that it stably remains fixed even when pressure is applied.

The degassing pipe 220 may be alternately installed in the port 122a along the circumferential direction of the first partition 122 or may be installed in the port 122a even when the capacity of the mixture is increased.

The housing 100 fixes the partition 120 through the flange 101 and the fastening member 103. The flange 101 is in close contact with the upper and lower surfaces of the first and second partitions 122 and 124 And the partition wall 120 is fixed through the fastening member 103 made of bolt and nut. The gasket G for sealing is inserted into the upper and lower surfaces of the first and second barrier ribs 122 and 124 so that the mixture does not leak to the outside through the gap between the barrier rib 120 and the flange 101, Is maintained.

An inflow nozzle according to an embodiment of the present invention will be described.

The inlet nozzle 200 is installed in the normal direction with respect to the head portion 210 and the end portion extends toward the inner circumferential direction of the head portion 210 so that the mixture pressurized by the inlet nozzle 200 flows into the head portion 210 210 in the direction of the inner circumference. Since the inflow nozzle 200 is formed in a shape in which the end diameter is relatively reduced, the flow rate of the mixture pressurized by the pump 4 is increased in the relatively circumferential direction of the head portion 210, The flow is maintained stably. The mixture is injected into the head part 210 through the inflow nozzle 200 and then moved along the degassing pipe 220. The fluid and the sand are separated from each other by the specific gravity difference and moved in different directions.

A description will now be given of a degassing tube according to an embodiment of the present invention.

The dis- sanding pipe 220 includes first to third dis- sanding pipes 222, 224, 226, and the first to third dis- sanding pipes 222, 224, 226 are connected to each other in a threaded manner.

The first degassing pipe 222 is coupled to the lower portion of the head portion 210 and has a second inclined portion 222a whose diameter decreases toward the lower side along the inner longitudinal direction and is formed with a thread along the outer lower circumferential direction do.

The first degassing pipe 222 is moved along the second inclined portion 222a while the speed of the downward movement is decreased and the rotational force is increased The mixture is not moved to the center of the first decanerated pipe 222 but is moved in the cyclone shape along the inner side, and the sand particles having a relatively heavy specific gravity due to the specific gravity difference of the mixture are rotated by the rotational force The movement is made along the inner surface of the first degassing tube 222 and the pressure difference between the rotational pressure of the mixture and the portion opened below the first degassing tube 222 causes the first degassing tube Since the negative pressure is generated at the center of the sand, the fluid having a relatively smaller specific gravity than the sand is discharged through the first discharge pipe 212.

Assuming that the inner diameter of the first de-sanding tube 222 connected to the head 210 is D1 and the inner diameter of the second de-sanding tube 224 is D2, the ratio of D2 = D1 / 2 Is applied. That is, D2 is formed at a half of the diameter of D1 to control the descending speed and rotational force of the mixture. For example, if the inner diameter of D2 is too small, the rate of descent of the mixture may be decreased and the rotational force may be increased, but it is preferable that the ratio is maintained because the phenomenon of stagnation or clogging of the mixture may partially occur.

The second de-sanding pipe 224 is threaded along the inner circumferential direction to be screwed with the lower side of the first de-sanding pipe 222, and has a first straight- And a second inclined portion 224b extending downward from the first linear portion 224a and having a reduced diameter toward the lower end. The first inclined portion 224a is connected to the first dishing pipe 222.

A plurality of second dishing sandwiching pipes 224 may be installed on the lower side of the first dishing pipe 222, and the number of the second dishing sandwiching pipes 224 may be varied depending on the capacity of the foreign material separating device.

The second dischaining tube 224 is configured such that the mixture moving at a predetermined rotational force along the inner surface of the first dishing pipe 222 is moved through the first rectilinear section 224a to increase the moving speed of the mixture, As the mixture moves along the inclined portion 224b, the rotational force is increased to move downward, and the sand contained in the mixture is moved downward along the second dishinging pipe 224 to which a plurality of the connected second dishinging pipes 224 are connected, And is moved through the first discharge pipe 212.

The third dishinging pipe 226 is threaded along the inner circumferential direction to be screwed with the lower side of the second dishinging pipe 224 and has a second straight portion A third inclined portion 226b having an inner diameter reduced toward the lower side from the lower end of the second rectilinear portion 226a and a third inclined portion 226b extending downward from the lower end of the third inclined portion 226b to the same inner diameter And a third rectilinear section 226c.

The third di-sanding pipe 226 is installed to discharge the sand separated through the first and second dis- sanding pipes 222 and 224 to the third housing 130, And a step 226d which is engaged with the opened hole.

The top portion of the dishing pipe 220 is fixed by the plurality of bolts 30 in a state where the head portion 210 is inserted into the first partition 122 and the cover plate 20, And is stably fixed in the state of being held in the step 226d.

A plurality of the dishing sandwiching pipes 220 are provided along the circumferential direction of the center of the first bank 122 and the capacity of the dishing sandwiching pipe 220 may be increased or decreased according to the supply amount of the mixture.

Since the degassing pipe 220 is made of stainless steel and therefore corrosion is prevented, it can be used stably even when foreign substances contained in seawater containing crude oil or salt are separated.

A configuration of a foreign matter separating apparatus according to another embodiment of the present invention will be described with reference to the drawings.

Referring to FIGS. 6 to 8, there are shown an inlet nozzle 200 in which a mixture of foreign substances is directly introduced, and a fluid (not shown) connected to the inlet nozzle 200 and flowing through the inlet nozzle 200 A second inclined portion 222a coupled to a lower side of the head portion 210 and having a reduced diameter downward along an inner longitudinal direction, A first de-sanding tube 222 threaded along the outer lower circumferential direction; A first rectilinear section 224a having a thread formed along the inner circumferential direction to be screwed with the lower side of the first degassing pipe 222 and having a predetermined length along the inner longitudinal direction, A plurality of second dishinging pipes 224 extending to a lower side of the lower portion 224a and having a second inclined portion 224b whose diameter decreases toward the lower end and connected to the first dishing pipe 222; A second straight portion 226a having threads formed along the inner circumferential direction to be screwed with the lower portion of the second dis- sanding tube 224 and extending along the inner longitudinal direction to the same inner diameter, The third inclined portion 226b whose inner diameter is reduced from the lower end of the lower portion 226a toward the lower end and the third straight portion 226c which extends from the lower end of the third inclined portion 226b toward the lower side with the same inner diameter, And a third de-sanding pipe 226. The third de-sanding pipe 226 includes a third de-sanding pipe 226, and the flow of the mixture introduced through the inlet nozzle 200 is changed into a cyclone shape to discharge only foreign substances. Since the dis- sanding pipe 220 is similar to the above-described one, the detailed description is omitted.

The inflow nozzle 200 includes a first inclined portion 202 disposed in a direction normal to the head portion 210 and extending toward the inside of the head portion 210 and having an inner diameter reduced toward the head portion 210, A first inclined portion 202 and a second inclined portion 202. The first inclined portion 202 and the second inclined portion 202 are formed so as to extend inwardly of the head portion 210 and extend at a relatively smaller diameter than the first inclined portion 202, 200 for injecting the mixture into the head portion 210. The injection nozzle 204 is for increasing the speed when the mixture introduced through the head portion 210 is injected into the head portion 210.

Since the inflow nozzle 200 has a thread formed in the inner circumferential direction, it can be used for separating foreign matter by directly coupling a connection pipe into which the mixture flows into the inflow nozzle 200. The injection nozzle 204 extends toward the inner circumferential direction of the head 210 so that when the mixture is injected through the injection nozzle 204, And is moved in the downward direction while changing the flow in the cyclone form.

Since the dis- sanding pipe 220 is the same as the above-described configuration, a detailed description thereof will be omitted.

9, the apparatus for separating foreign matter 1 according to the present invention comprises a storage tank 2 for storing a large amount of a mixture, one end connected to the storage tank 2 and the other end connected to the housing 100, And a pump 4 installed in the first pipe 3 and pumping the mixture stored in the storage tank 2 to the housing 100. The first pipe 3 is connected to the inlet 102 of the first pipe 3, .

For example, when the foreign object separating apparatus 1 desires to separate foreign substances contained in crude oil, a large amount of crude oil is stored in the storage tank 2 and then supplied to the housing 100 using the pump 4, When the mixture is supplied to the degassing tube 220 through the inflow nozzle 200, the pressurized fluid can be moved to the pressurized state.

Although the number of the pumps 4 is only one in the present embodiment, the number of the pumps 4 may vary, and the amount of supply supplied to the inflow nozzle 200 through a control unit (not shown) And speed can be changed.

The operating state of the foreign matter separator according to one embodiment of the present invention will now be described with reference to the drawings.

9 to 11, the soil collected from the sea or the river is collected in the form of a mixture of fluid (oil, gas, water) and sand while passing through the aquifer and stored in the storage tank 2 Is pumped by the pump 4 and is pumped to a specific pressure and is transferred into the chamber 101 via the first pipe 3 and the inlet 102. [

The mixture is injected into the chamber 101 in a state in which a large amount of sand and fluid are mixed and then injected at a predetermined pressure and speed toward the inner circumferential direction of the head part 210 via the inflow nozzle 200 The flow is changed to a cyclone shape having a helical shape along the second inclined portion 222a of the first degassing pipe 222 to move downward and the sand particles having a relatively heavy specific gravity due to the specific gravity difference of the mixture, By the pressure difference between the rotational pressure of the mixture and the portion of the first degassing pipe 222 which is opened below the first degassing pipe 222, A fluid having a relatively smaller specific gravity than the sand is discharged through the first discharge pipe 212 while a negative pressure is generated.

The mixture continues to move along the inner surface of the first degassing tube 222 with a predetermined rotational force and the moved mixture passes through the first rectilinear section 224a to increase the moving speed of the mixture and the second inclined section 224b, The sludge contained in the mixture is moved downward along the second dis- sanding pipe 224 to which the plural sludge is connected and the fluid is discharged to the first discharge pipe 212 Lt; / RTI >

After passing through the second dischannel pipe 224, the mixture is moved to the third dischannel pipe 226, then lowered from the position of the second rectilinear portion 226a toward the lower side, reaches the third inclined portion 226b The descending speed is temporarily decreased while moving along the inner circumferential direction and then discharged to the third housing 130 via the third rectilinear section 226c and the fluid removed from the sand is moved to the first discharge pipe 212 2 housing 120 and is transported by a separate pumping means.

The sand separated by the foreign matter separating apparatus 1 is temporarily stored in the third housing 130 and then discharged to the outside through the discharge port 104. [

The mixture does not move into the space of the second housing 120 or the third housing 130 by the first and second partition walls 122 and 124 when the mixture enters the chamber 110 but exists only in the chamber 101, The locking state of the fastening member 103 is released and the fastening state of the cover plate 20 is disassembled in the state where the introduction of the mixture into the chamber 101 through the pump 4 is stopped, The cap 10 inserted into the port 122a of the first partition 122 and the cap 10 inserted into the port 124a of the second partition 124 are released from the fixed state, It is possible to process the increased mixture by inserting it, and the treatment capacity for the mixture can be selectively increased without increasing the total volume of the foreign matter separating apparatus 1.

An operation state of a foreign matter separator according to another embodiment of the present invention will be described with reference to the drawings. In this embodiment, the supply pipe may be connected directly to the desiccating pipe at a small capacity without treating the mixture in a large capacity, so that the sand contained in the fluid can be separated and used.

12, the mixture is supplied to the inside of the inflow nozzle 200 through the supply pipe 40, and is discharged to the head portion (not shown) at a predetermined pressure with the discharge speed of the mixture increased through the spray portion 204 210, the flow is changed to a cyclone shape having a spiral shape as shown by an arrow along the second inclined portion 222a of the first dis- The sand particles having a relatively heavy specific gravity due to the specific gravity difference of the mixture are moved along the inner surface of the first degassing pipe 222 by the rotational force, A negative pressure is generated in the central portion of the first degassing pipe 222 due to a pressure difference between the lower portion and the lower portion of the first degassing pipe 222, and a fluid having a relatively smaller specific gravity than the sand is discharged through the first discharge pipe 212.

When the mixture is moved along the lower longitudinal direction of the second degassing pipe 224, the fluid is moved to the first discharge pipe 212 while the spiral flow is maintained, and the sand is passed through the third dishing pipe 226 So that the sand contained in the fluid can be stably separated.

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 of the invention as set forth in the appended claims. The present invention can be variously modified and changed by those skilled in the art, and it is also within the scope of the present invention.

2: Storage tank
4: Pump
100: Housing
110, 120, 130: first, second and third housings
101: chamber
102: inlet
122, 124: first and second barrier ribs
200: inlet nozzle
210:
220: Dish Sanding Pipe
222, 224, 226: 1st, 2nd and 3th sanding pipes
222a: second inclined portion
224a: a first rectilinear section
224b: second inclined portion
226a: a second rectilinear section
226b: third inclined portion
226c: third straight line portion

Claims (15)

A housing in which an internal region is divided through a partition wall partitioning the interior of the chamber, the housing having an inlet port through which a mixture of foreign substances flows, a chamber communicated with the inlet port and into which the mixture flows, And
A first discharge pipe connected to the inflow nozzle and adapted to move the fluid among the mixture introduced through the inflow nozzle, and a second discharge pipe connected to the inflow nozzle, And a plurality of discharge nozzles for discharging the foreign matter to the lower side of the housing by changing a flow of the mixture introduced through the inlet nozzle into a cyclone shape, ≪ / RTI &
The housing includes:
A first housing communicating with the inlet;
A second housing provided above the first housing and providing a space in which the fluid moved through the first discharge pipe is temporarily stored;
And a third housing provided below the first housing and providing a space in which foreign matter separated through the dis- sanding pipe is temporarily stored. delete The method according to claim 1,
Wherein,
A first diaphragm disposed between the first housing and the second housing and having a plurality of open ports into which the dis- sanding tube is inserted;
And a second partition wall disposed between the first housing and the third housing and having a plurality of open ports into which the desiccating tube is inserted. The method of claim 3,
Wherein,
Wherein the plurality of ports are formed in a disc shape, and the ports are arranged at equal intervals in the circumferential direction. The method of claim 3,
The foreign matter separating device comprises:
And a cap (Cap) selectively inserted into a port where the desiccating tube is not inserted. 6. The method of claim 5,
The foreign matter separating device comprises:
Wherein the separation efficiency of the foreign matter is controlled by selectively desorbing the cap according to the supply amount of the mixture. The method according to claim 1,
The foreign matter separating device comprises:
A storage tank in which a large amount of the mixture is stored;
A first pipe connected at one end to the storage tank and connected at the other end to an inlet of the housing;
And a pump installed in the first pipe and pumping the mixture stored in the storage tank to the housing. The method according to claim 1,
The housing includes:
A flange formed on an outer side of the partition and closely adhered to an upper surface and a lower surface of the partition;
And a fastening member installed via the flange and the partition to fix the partition. The method according to claim 1,
The des-
A second inclined portion coupled to a lower side of the head portion and having a reduced diameter decreasing in a downward direction along an inner longitudinal direction, and a first dishinging tube having a thread formed along an outer lower circumferential direction;
A first straight portion formed with threads along an inner circumferential direction so as to be screwed with a lower side of the first dishinging pipe and extending a predetermined length along an inner longitudinal direction, A plurality of second dishinging tubes having a second inclined portion having a reduced diameter and connected to the first dis-
A first straight portion formed with a thread along the inner circumferential direction to be screwed with the lower side of the second dis- sanding tube and extending along the inner longitudinal direction to the same inner diameter, and a second linear portion extending from the lower end of the first straight portion to the inner side And a third dishing tube having a reduced third inclined portion and a second straight portion extending downward from the lower end of the third inclined portion to the same inner diameter. 10. The method of claim 9,
The third dis-
And a step formed on the outside of the partition so as to be engaged with the partition. 10. The method of claim 9,
Wherein the first dis-
And a ratio of D2 = D1 / 2 is applied when the inner diameter of the head connected to the head portion is assumed to be D1 and the inner diameter connected to the second dishing pipe is assumed to be D2. The method according to claim 1,
The des-
Wherein the separator is made of stainless steel. The method of claim 3,
The foreign matter separating device comprises:
A cover plate installed on an upper surface of the first partition and provided on an upper surface of the desiccating tube and the port;
And a plurality of bolts coupled from the upper surface of the cover plate toward the first partition. An inflow nozzle through which a mixture of foreign substances flows directly;
A head connected to the inflow nozzle and having a first discharge pipe for moving the fluid among the mixture introduced through the inflow nozzle;
A second inclined portion coupled to a lower side of the head portion and having a reduced diameter decreasing in a downward direction along an inner longitudinal direction, and a first dishinging tube having a thread formed along an outer lower circumferential direction;
A first straight portion formed with threads along an inner circumferential direction so as to be screwed with a lower side of the first dishinging pipe and extending a predetermined length along an inner longitudinal direction, A plurality of second dishinging tubes having a second inclined portion having a reduced diameter and connected to the first dis- And
A second straight line portion having threads formed along the inner circumferential direction to be screwed with the lower side of the second dis- sanding tube and extending along the inner longitudinal direction to the same inner diameter, and a second linear portion extending from the lower end of the second straight- And a third dishing tube having a reduced third inclined portion and a third straight portion extending downwardly from the lower end of the third inclined portion to the same inner diameter. The flow of the mixture introduced through the inflow nozzle is introduced into the cyclone cyclone, so that only the foreign substance is discharged. 15. The method of claim 14,
Wherein the inflow nozzle comprises:
A first inclined portion which is provided in the normal direction of the head portion and which extends toward the inside of the head portion and whose inner diameter is reduced toward the head portion; and a second inclined portion which is provided at the front end portion of the first inclined portion, And a spray nozzle extending at a diameter relatively smaller than the diameter of the one inclined portion to increase the speed when the mixture introduced through the inflow nozzle is injected into the head portion.

Images