KR100805037B1 - Water drain apparatus for compressed air - Google Patents

Abstract

The present invention relates to a water discharge device in the compressed air to enable the cleaning of the device connected to the upper valve in order to discharge the water of the condensed water and steam pipe in the compressed air pipe every time the water is discharged.

According to the present invention, when discharging the condensate collected therein, the foreign substances contained in the condensate are cleaned at a high pressure, and at the same time, even the part where clogging occurs at the upper part is completely cleaned, which is the second ripple phenomenon due to the inability to discharge. It can prevent the damage of equipment and equipment at the front and back, thus minimizing the adverse effect due to condensate throughout the equipment.

In addition, condensed water in the compressed air used to blow pulverized coal into the blast furnace causes a failure of a large compressor, causing enormous loss of maintenance and shutdown, and also causing blockage due to moisture in the blown pipe, causing sudden pulverized coal during blast furnace operation. There was a case of unstable operation due to fluctuations such as rapid drop of furnace in the blast furnace operation due to the impossibility of blowing, but the clear discharge of condensate can solve all these problems.

Condensate, foreign material cleaning, blast furnace operation, condensate discharge, water separator

Description

Water discharge device in compressed air {WATER DRAIN APPARATUS FOR COMPRESSED AIR}

1 is a longitudinal cross-sectional view of the entire atmosphere of the water discharge device in the compressed air according to the present invention;

2 is a cross-sectional view of the upper atmosphere of the water discharge device in the compressed air according to the present invention;

3 is a cross-sectional view of the central portion of the water discharge apparatus in the compressed air according to the present invention in the atmosphere;

Figure 4 is a cross-sectional perspective view of the lower atmosphere of the water discharge device in the compressed air according to the present invention;

5 is a longitudinal sectional view of the entire discharge of the water discharge device in the compressed air according to the present invention;

6 is a cross-sectional view when discharging the middle portion of the water discharge device in the compressed air according to the present invention;

7 is a cross-sectional view of the lower discharge of the water discharge device in the compressed air according to the present invention;

8 is a partial cutaway cross-sectional view of the water discharge device in the compressed air according to the present invention

9 is a configuration diagram in which the water discharge device in the compressed air according to the present invention is mounted to the bottom of the container.

       <Description of the symbols for the main parts of the drawings>

1 ..... Body 2 ..... Top Cover

3 ..... Assembled tube 4 ..... tumbler

5 ..... tumbler hole 6 ..... tumbler inlet euro hole

7 ..... Swivel Outlet Euro Hole 8 ..... Rotator Shaft

9 ..... Turntable side groove 10 ..... Assembled tube O-ring                 

11 ..... rotary vanes 12 ..... injury plate

13 ..... Inlet plate discharge hole 14 ..... Center plate for injury plate

15 ..... blank 16 .....

17 ..... Floating wing 18 ..... Floating bottom contact

19 ..... Outlet hole on the side of the container body.

21 ..... flow path cylindrical primary outlet

22 ... 2nd outlet of the flow-forming cylinder

23 ..... Rotator lower nut 24 ..... blank

25 ..... Lower flow path inlet hole 26 ..... Lower container body flow path discharge hole

27 ..... lower container body 28 ..... lower container body O-ring

29 ..... Pressure forming flow path 30 ..... Pressure building flow path

31 ..... Flow forming valve 32 ..... Flow forming valve O-ring

33 ..... Spring 34 ..... Flow-forming valve

35 ..... The flow path forming part container body 36 ..... The flow path forming part container body Outlet flow path

37 ..... Lower container body outlet groove 38 ..... Flow forming part O-ring

39 ..... Flow opening valve bottom hole

40 ..... rotor blade retaining ring 41 ..... rotor blade base

The present invention relates to a water discharge device in the compressed air to enable the cleaning of the device connected to the upper valve in order to discharge the water of the condensed water and steam pipe in the compressed air pipe every time the water is discharged.

     In general, the automatic condensate discharge device has a structure in which when the water level rises inside the hollow container, the floating body for automatic discharge rises as a buoyancy and a flow path is formed inside the device to discharge the water inside the container. When the water level is lowered, the injured body, which was injured above, comes back down to block the flow path and block the discharged water.

     However, in the conventional automatic condensate discharge device as described above, the floating body that is injured by buoyancy before the foreign material contained in the condensate is completely discharged, the water level is lowered to stop the discharge of condensate and foreign matter by blocking the flow path, It will cause a malfunction. Because of this, if the condensed water is filled to the inside of the operating equipment such as the compressor due to the discharge of the condensate, it will lead to damage to the equipment, and also adversely affects the equipment or apparatus in which the compressed air is used.

The present invention has been made in order to solve the above-mentioned conventional problems, and when the floating body inside the container rises once to start the discharge of condensate, the internal condensate is completely discharged, and then the high-pressure compressed air or steam After the inside of the container is completely cleaned, the floating body stops and the discharge is stopped, thereby automatically cleaning the inside of the container itself every time it is discharged, as well as to the vulnerable areas where clogging occurs frequently due to the sticking of foreign substances. It is an object to provide a water discharge device in the compressed air to be carried out.

In order to achieve the above object, the present invention is an apparatus for separating condensate in a vessel or separator separated from the air and condensate, it is disposed on the lower surface of the vessel or separator, and the inside through the end pipe of the upper side A hollow container body into which the high pressure air and the condensed water are introduced into the container or the separator;

A flow path forming valve having a floating body lifted by condensate inside the container body and opening a flow path below the container body by the rising of the floating body;

It is fitted to the center of the floating body to move up and down, the top of the rotating plate rotated by the pressure of the condensate is mounted so as to be slidable, the rotating blade is provided in the middle of the rotating blade is raised by the rotating plate during the discharge of the condensate water Full axis;

A storage space for collecting condensed water introduced into the container body between the lower surface of the floating body and the lower container body of the container body; and raising the floating body by the condensate, and raising the rotating shaft so that the foreign matter in the container or the separator. By lifting the strainer and by providing a water discharge device in the compressed air, characterized in that configured to achieve the discharge of condensate with the foreign matter.

Hereinafter, the present invention will be described in more detail with reference to the drawings.

The apparatus of the invention shown in FIG. 1 is shown enlarged as a detailed view of FIGS. 2, 3 and 4. The water discharge device 100 in the compressed air according to the present invention is the upper cover (2) is blocked by the welding structure on the upper portion of the hollow container body (1), the assembly is assembled with the upper portion in the middle of the upper cover (2) The forging pipe 3 is assembled together with the assembling pipe of the o-ring 10, and the rotary plate 4 is rotatably inserted between the upper cover 2 and the rotary plate hole in the rotary plate 4 so as to pass up and down. (5) is formed.

The rotary plate hole 5 connects the flow path 3a between the assembly end pipe 3 and the rotating shaft 8, which will be described later, to the space under the upper cover 2, so that the upper cover Holes (not shown) are also formed in (2) to allow condensed water to flow from the flow path 3a to the lower side to flow into the interior of the container body 1.

The rotary plate inlet flow passage hole 6 and the rotary plate outlet flow passage hole 7 are connected to the rotary plate 4, and the rotary shaft 8 having a “+” cross section is provided at the center of the rotary plate 4. It is fitted to be slidable.

In the central portion of the apparatus, as shown in detail in FIG. 3, a rotary blade 11 fitted in the center of the rotary shaft 8 is rotated by the rotary blade support portion 41 and the rotary blade fixing ring 40. It is fixed integrally to the entire shaft 8, which is mounted on the flow path forming cylinder 20.

Below, the anti-injury plate 12 is fixed to the container body 1 by welding, and the anti-injury plate 12 is formed with a plurality of anti-injury plate discharge holes 13 on the outer circumferential surface thereof. The floating prevention plate center hole 14 is formed, and the floating body 16 is formed under the floating prevention plate 12, and the floating wing 17 is formed in the lower part of the outer side of the floating prevention plate 12, Floating bottom contact face 18 is coupled.                     

The floating body 16 has a specific gravity smaller than that of water, and is lifted by the condensed water introduced into the container body 1 to be lifted up to the injury preventing plate 12, and the outer circumferential surface of the container body 1 is increased. It forms smaller than the inner peripheral surface, and forms the flow path 16a in which condensate falls.

Then, between the lower surface of the floating body 16 and the lower container body 27 of the container body 1 is to form a storage space to collect the condensed water flowing into the container body (1).

In addition, as shown in Figure 4, the lower side surface of the container body (1) has a side discharge hole 19 of the container body, which is a rotary plate inlet flow path hole in the upper side of the container body (1) as shown in FIG. It is connected to (6) via a pipe (19a), the lower container body 27 together with the lower container body O-ring 28 is assembled to the bottom of the container body (1) with screws.

The lower container body 27 has a lower container body flow path discharge hole 26 is formed in the lower side of the lower container body 27, and the lower container body outlet groove 37 is formed, and the flow path forming unit container body 35 is formed at the center of the flow path forming unit O-ring. Assembled together with (38), the flow path forming portion container body 35 is formed with a pressure forming flow path 30 in the lower portion horizontally, the central portion formed in the horizontal flow path forming portion container body outlet flow path 36, the center The lower passage inlet hole 25 is vertically drilled.

The hole 25 is connected to the upper rotating plate outlet flow path hole 7 of the container body 1 through the pipe 25a, so that the condensed water discharged to the rotating plate outlet flow path hole 7 is turned around the rotating plate 4. It is to be introduced into the hole (25).

In the upper space, the flow path forming cylinder 20 forms the flow path forming cylinder primary outlet 21 and the flow path forming cylinder secondary outlet 22, and in the center thereof is a rotating shaft 8. ) Is located.

In addition, between the lower container body 27 and the center of the flow path forming portion of the container body 35, a pressure forming flow path plate 29 is installed to be in contact with the upper floating body lower contact surface 18, the outer side The flow path forming valve 31 forms a flow path forming valve over-float prevention plate 34 at the top and a flow path forming valve bottom hole 39 at the bottom thereof, and has a spring 33 at the inside and a flow path forming valve O-ring (below). 32) It is installed together with the structure.

The pressure forming flow path plate 29 positioned between the lower container body 27 and the flow path forming part container body 35 has a plurality of upper and lower through holes 29b formed on the lower side, respectively, as shown in detail in FIG. 8. The leg portions 29a of the plurality of guide holes 35b provided in the annular stepped portions 35a forming the central hole 25 of the flow path forming container body 35. It is inserted to be able to descend. Therefore, when the pressure forming flow path plate 29 is slightly lifted to the upper side, the pressure forming flow path plate 29 passes through the space between those leg portions 29a, as shown in Figs. It is to flow from the central hole 25 to the flow path forming portion container body outlet flow path (36).

Referring to the operation of the present invention configured as described above according to the drawings as follows.

In FIG. 1, when the condensate is generated inside the container body 1, the floating body 16 is raised by buoyancy and the floating body lower contact surface 18 positioned below the floating body 16 is shown in FIG. 7. The pressure of the condensed water is introduced into the plurality of through holes 29b provided in the legs 29a of the pressure forming flow path plate 29 so as to be separated from the contact with the pressure forming flow path plate 29. The flow path is formed together with the spring 33 which is transferred to the lower portion of the flow path formation valve 31 through the pressure formation flow path 30 formed in the secondary container body 35 and the pressure is blocked by the flow path formation valve O-ring 32. Lift valve 31 up. At this time, the conveying amount of the flow path forming valve 31 is limited by the over-float prevention plate 34 formed in a plurality of protrusions on the upper surface of the flow path forming valve.

When the flow path forming valve 31 is raised by the operation as described above, as shown in FIG. 4, the upper flange lower outer surface 31a of the flow path forming valve 31 is the upper portion of the flow path forming container body 35. As the flow path forming valve 31 closed while being pressed in surface contact with the surface is raised, a portion of the upper outer surface of the lower flange 31a is raised from the upper surface of the flow path forming container body 35 to open the valve. will be.

When the flow path forming valve 31 is opened in this way, the fluid entering the rotating plate inlet flow path hole 6 through the container body side discharge hole 19 and the pipe 19a connected to the lower side of the container body 1 is rotated. Returning to the rotary plate outlet flow path hole (7) while rotating (4) as the rotary plate side groove (9), enters the lower flow path inlet hole (25) of the lower center through the pipe (25a), and the flow path forming cylinder primary outlet port An upper flow path forming valve 31 and a flow path forming container body discharge port flow passage 36 in which the upper flange lower outer surface 31a is raised from the upper surface of the flow path forming container body 35 through the opening 21. Through the lower container body flow path discharge hole 26 is discharged to the outside.

At this time, the rotor shaft 8 is rotated by the rotation of the rotor plate 4, and the rotor blade 11 fixed at the center of the rotor shaft 8 turns together, and the flow path forming cylindrical body 20 is rotated by the rotor blade 11. The whole of the rotating shaft (8) raised on the top of the) is raised to the top.

Of course, if the rotor shaft 8 is raised here, this actuation of the rotor shaft 8 will clean the valve or bottom of its upper vessel or water separator. On the other hand, in this case, the operation of cleaning the bottom of the vessel or separator separated as the rotor shaft 8 is raised is connected to the foreign matter sieve, etc. to the rotor shaft (8) condensate If it is allowed to penetrate, it is possible to discharge the foreign matter attached to the sieve, etc. together. The cleaning operation of such vessels or separators is conventional, and this may be any subsequent operation only in connection with the ascending operation of the rotor shaft 8, and thus a detailed cleaning operation thereof will be omitted. Instead, only the ascending operation of the rotor shaft 8 that can achieve such a cleaning operation will be described in detail.

On the other hand, at this time, the rotor shaft is raised and the floating body 16 comes down during the discharge of condensate and foreign matter to block the pressure-forming flow path plate 29 to stop the discharge is the floating body formed on the outside of the floating body 16 Due to the unbalanced movement of the wing 17 through the container body side discharge hole 19, the opposite side of the container body side discharge hole 19 is lifted, thereby lowering the floating body lower contact surface 18 and the pressure-forming flow path plate. Interruption of contact with (29) allows continuous discharge.

In this way, when the rotary blade 11 is turned to the highest, the lower rotor nut 23 in the lower part of the rotor shaft 8 contacts the inner upper surface of the flow path forming cylindrical body 20 and flows through it. The forming cylinder 20 is lifted as shown by the dotted line in FIG.

As a result, the flow paths that have been used to pass through the lower flow path cylindrical body primary outlet 21 of the flow path cylindrical body 20 are blocked, and the flow path formed cylindrical secondary outlet 22 formed on the outer surface of the flow path cylindrical body 20. ) As the flow path is opened, the flow path entering through the container body side discharge hole 19, the rotor plate inlet passage hole 6, the rotor plate outlet passage hole 7, and the lower passage inlet hole 25 is blocked. The condensate water of the lower part of the floating body 16 is opened in a state where the upper flange lower outer surface 31a is directly raised from the upper surface of the flow path forming container body 35 through the flow path forming cylindrical secondary outlet 22. It is discharged to the outside through the flow path forming valve 31 and the flow path forming portion container body discharge port 36 of the lower container body flow path discharge hole 26. Therefore, the condensate is discharged quickly.

In this process, the rotation of the rotating plate 4 is stopped, so that the rotating plate is lowered along the rotating plate shaft 8 together with the rotating blade 11.

When the discharge of the condensate is completed as described above, the unbalanced state of the floating wing 17 is eliminated and is settled so that the floating lower contact surface 18 contacts and blocks the pressure-forming flow path plate 29. In addition, the pressure of the lower portion of the flow path forming valve 31 exits through the hole 29b of the leg 29a of the pressure forming flow path plate 29 as opposed to the above, and the flow path forming valve 31 descends. As shown in FIG. 4, the upper upper flange lower outer surface 31a portion is lowered to the upper surface of the flow path forming container body 35 so that the flow path is blocked and the discharge of condensed water is stopped.                     

Subsequently, the condensate that subsequently descends through the assembly short pipe 3 enters through the rotating plate hole 5 and accumulates in the lower portion of the container body 1 through the center plate 14 of the anti-floating plate. By repeating 16), the above operation is repeated. Meanwhile, the condensate can be manually discharged by opening an external valve (not shown) connected to the container body side discharge hole 19 in the standby state at this time.

As described above, according to the present invention, when discharging the condensed water collected therein, the foreign substances contained in the condensed water are cleaned at a high pressure, and at the same time, the second part due to the incapable discharge can be completely cleaned even in a part where the blockage of the upper part occurs. It prevents the damage of equipment and equipment in the front and rear stages, which is the next wave phenomenon, and minimizes the adverse effect due to condensate water throughout the equipment.

In addition, condensed water in the compressed air used to blow pulverized coal into the blast furnace causes a failure of a large compressor, causing enormous loss of maintenance and shutdown, and also causing blockage due to moisture in the blown pipe, causing sudden pulverized coal during blast furnace operation. There was a case of unstable operation due to fluctuations such as rapid drop of furnace in the blast furnace operation due to the impossibility of blowing, but the clear discharge of condensate can solve all these problems.

Claims (4)

A device for separating condensate in a vessel or separator separated with air and condensate, A hollow container body (1) disposed on a lower surface of the vessel or separator and into which high pressure air and condensed water in the vessel or separator are introduced into the container through an upper end pipe; A flow path forming valve (31) having a floating body (16) which is lifted by condensate inside the container body (1), and opening a flow path below the container body by the rising of the floating body; It is fitted in the center of the floating body 16, the ascending and descending, the upper end of the rotating plate (4) is rotated mounted to the pressure of the condensate, slidably mounted, in the middle is provided with a rotary blade (11) by the rotating plate during the discharge of the condensate A rotating shaft which is rotated while the rotating blades are rotated; Floating body 16 by the condensate, including; a storage space for collecting the condensed water flowing into the container body (1) between the lower surface of the floating body 16 and the lower container body 27 of the container body (1) Raise the, and the rotating shaft to raise the foreign matter filtering net in the container or water separator and configured to achieve the discharge of condensate with the foreign matter. The rotating plate hole (5) is formed in the rotating plate (4) so as to penetrate up and down, and the rotating plate hole (5) is a flow path between the assembling end pipe (3) and the rotating shaft (8). 3a) is connected to a space under the upper cover 2, and a hole is formed in the upper cover 2 so that condensed water flows from the flow passage 3a to the lower side and flows into the inside of the container body 1. Water discharge device in the compressed air, characterized in that. The method of claim 1, wherein the floating body 16 is less than the specific gravity of the water, it is floated by the condensed water flowing into the interior of the container body 1 is below the rotary blade 11 in the container body (1) It is raised to the anti-floating plate 12, the outer peripheral surface is smaller than the inner peripheral surface of the container body (1) characterized in that it forms a flow path (16a) in which the condensed water is dropped therebetween. The lower container body 27 has a lower container body flow path discharge hole 26 formed therein, a lower container body outlet groove 37 formed therein, and a flow path forming unit container body 35 in the center thereof. ) Is assembled with the flow path forming portion O-ring 38 and the flow path forming portion container body 35 has a pressure forming flow passage 30 horizontally formed at the lower portion thereof, and the flow path forming portion container body discharge flow passage 36 is formed horizontally at the center portion thereof. ) Is drilled in the center, and the lower passage inlet 25 is vertically drilled in the center; The hole 25 is connected to the upper rotating plate outlet flow path hole 7 of the container body 1 through the pipe 25a, so that the condensed water discharged to the rotating plate outlet flow path hole 7 is turned around the rotating plate 4. To enter the hole 25; A flow path forming cylinder 20 is formed in the upper space of the hole 25 by forming a flow path forming cylinder primary outlet 21 and a flow path forming cylinder secondary outlet 22, in the center of the rotating body The shaft 8 is located, Between the lower container body 27 and the center of the flow path forming portion container body 35, a pressure-forming flow path plate 29 is installed to be in contact with the upper floating body lower contact surface 18 and to the outside thereof. The flow path forming valve 31 forms a flow path forming valve over-float prevention plate 34 at the upper portion and a flow path forming valve bottom hole 39 at the bottom thereof, and has a spring 33 inward and a flow path forming valve O-ring 32 thereunder. Water discharge device in the compressed air, characterized in that installed along with.

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