KR20190136327A - Steam trap - Google Patents

Abstract

The present invention relates to a steam trap capable of increasing thermal efficiency. The steam trap comprises: a body (10) having a condensate inlet (11) and a condensate outlet (13) on a left and a right thereof; an inlet path (20) formed on the body (10) to be connected to the condensate inlet (11); a condensate storage chamber (30) formed on the body (10) to be connected to the inlet path (20); a guide path (40) formed on the body (10) to be connected to the condensate storage chamber (30) and positioned above the condensate storage chamber (30); a ring-shaped protrusion (50) protruding from a lower portion of the guide path (40) to be positioned on the condensate storage chamber (30); a buoy (60) inserted into the guide path (40) to ascend and descend along the guide path (40), wherein a lower portion (61) thereof protrudes from the ring-shaped protrusion (50) to be positioned on the condensate storage chamber (30); and a discharge path (70) formed on the body (10) to connect the guide path (40) and the condensate outlet (13), and opened and closed by an ascent and a descent of the buoy (60).

Description

Steam Traps {STEAM TRAP}

The present invention relates to a steam trap, and more particularly to a steam trap that can effectively block steam discharge.

In general, condensate generated in the steam pipe causes water hammer and should be removed as necessary. At this time, the steam trap is a device for automatically discharging only the drain as much as possible because the steam efficiency is poor. Steam traps include discs, bimetals, and buckets.

In the disc type steam trap, when the condensate accumulates in the trap, the temperature in the trap is lowered and the pressure in the transformer chamber is lowered, so that the disc is lifted and the condensate is discharged.

In the bimetallic steam trap, when condensate accumulates in the trap, the temperature in the trap decreases, and a ball valve is opened by the action of the bimetal to drain the drain.

The bucket type steam trap is normally closed by the drain valve and closed by the drain valve.However, if condensate flows from the inlet and accumulates in the bucket, the drain will accumulate and the bucket will sink and the drain valve directly connected to the bucket will open. The drain in the bucket is discharged by this.

Related prior art is Korean Patent Publication No. 10-1060033. The prior art is to prevent the discharge of condensate water or steam by opening and closing the gate by the movement of the mouth, during the initial operation of the air and the gas is discharged after the temperature in the body by the high temperature steam is the body and one side The shape of the bimetal that is fixedly coupled is deformed, thereby moving the ball downwards to block the gate to prevent the discharge of steam, and when condensate accumulates in the body, the ball is raised by the condensate to open the gate and vents to discharge the condensate. A spherical steam trap with an orifice combined.

Korean Patent Publication No. 10-1060033

An object of the present invention is to provide a steam trap that can increase the thermal efficiency by effectively blocking the discharge of steam during the discharge of condensate.

Technical problems to be solved by the present invention are not limited to the above-mentioned technical problems, and other technical problems not mentioned above will be clearly understood by those skilled in the art from the following description. Could be.

The present invention for achieving the above object is the body 10 having a condensate inlet 11 and the condensate outlet 13 on the left and right, and the inlet passage formed in the body 10 and connected to the condensate inlet 11 ( 20, the condensate storage chamber 30 formed in the body 10 and connected to the inflow passage 20, and the condensate storage chamber 30 formed in the body 10 and connected to the condensate storage chamber 30 A guide passage 40 positioned on the chamber 30, a protruded lower portion of the guide passage 40, and an annular protrusion 50 positioned in the condensate storage chamber 30, and the guide passage 40. Is inserted into the elevating along the guide path 40 and the lower portion 61 is protruded from the annular projection 50 is located in the condensate storage chamber 30 and the ball 60, and the body 10 Is formed is connected to the guide path 40 and the condensate outlet 13 and opened and closed in accordance with the lifting of the float 60 Includes a drain 70,

Condensate flowing through the condensate inlet 11 is stored in the condensate storage chamber 30 through the inlet passage 20, and the level of condensate stored in the condensate storage chamber 30 is the annular protrusion ( If it is higher than the lower surface 51 of the 50, the outlet 60 is opened along the guide path 40, the discharge path 70 is opened, and the condensate storage through the open discharge path 70 The condensate stored in the chamber 30 is characterized in that discharged to the condensate outlet (13).

Specifically, the inflow passage 20 may form an orifice having a diameter smaller than that of the condensate inlet 11.

An orifice member 80 having an orifice hole 81 having a diameter smaller than the condensate inlet 11 is installed at the condensate inlet 11, and the orifice hole 81 is connected to the inflow path 20. In addition, the inflow passage 20 may have a diameter smaller than that of the orifice hole 81.

The condensate inlet 11 may be provided with a filtration member 90 for filtering the condensate flowing into the inlet (20).

The sub-ball 60 is made of an egg shape having a smaller diameter than the lower part 61 than the upper part 63, and when the sub-ball 60 is raised, the lower part 61 is the annular protrusion 50 and the guide path ( A gap G is formed from the inner wall of the wall 40, and condensate stored in the condensate storage chamber 30 is introduced into the gap G to flow to the discharge path 70.

According to the present invention, since the condensed water is discharged only by the operation of the buoy by buoyancy, the short life problem of the mechanical buckle is solved, and there is no opening / closing interval by the mechanical operation, thereby effectively blocking steam discharge.

In addition, since the steam introduced with the condensate is not discharged in the closed space even in the operation of the float, the loss of thermal energy is minimized.

In addition, since the inflow of steam is blocked by the orifice, the thermal efficiency can be increased.

1 is a view showing a state in which the steam trap of the present invention is mounted on the drain pipe.
2 is an exploded view of the steam trap of the present invention.
3 is a view showing a state in which condensed water is stored in the steam trap of the present invention.
4 is a view showing a steam trap of the present invention to discharge condensate.
5 is an enlarged view of a portion of FIG. 4.
6 is a view showing another example of the steam trap of the present invention.
7 is a view showing still another example of the steam trap of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention. Like elements in the figures are denoted by the same reference numerals wherever possible. In addition, detailed descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted.

As shown in the figure, the steam trap of the present invention includes a body 10 having a condensate inlet 11 and a condensate outlet 13 on left and right sides. The body 10 may be flanged to form a flange as shown in the drawing to flange the drain pipe 1, the condensate inlet 11, and the condensate outlet 13, respectively, and form a screw to form the drain pipe 1 and the condensate inlet ( 11) and the condensate outlet 13 may be screwed respectively.

The body 10 has an inflow passage 20 connected to the condensate inlet 11, and a condensate storage chamber 30 connected to the inflow passage 20 is formed, respectively. The inflow path 20 serves to guide the condensate (W) flowing into the condensate inlet 11 to the condensate storage chamber 30, the condensate storage chamber 30 is formed in the lower portion of the body 10 to condensate ( W) is stored.

Body 10 has a lower cover 14 for opening and closing the condensate storage chamber 30 in the lower portion to facilitate the molding of the condensate storage chamber 30, and to clean the condensate storage chamber 30 as needed. Can be.

The inflow path 20 forms an orifice having a diameter smaller than that of the condensate inlet 11 to block the steam S and guide only the condensate W to the condensate storage chamber 30. Inflow path 20 is preferably located in the center or below the center of the condensate inlet (11). When the temperature is high, such as summer, condensate (W) generation is significantly reduced, so condensate (W) can be discharged together with steam (S) without filling the inlet (20) in consideration of this condensate inlet (11) It is better to be designed to be located below the center of. The inflow path 20 may be bent at least once in the middle to further block steam S and guide only the condensate W into the condensate storage chamber 30.

The body 10 is connected to the condensate storage chamber 30 and is formed in the guide passage 40 positioned on the condensate storage chamber 30, and protrudes below the guide passage 40 to be located in the condensate storage chamber 30. Each annular protrusion 50 is formed, and the guide hole 40 is inserted into the sub-ball 60 to move up and down along the guide path 40. At this time, the buoy 60 is the lower portion 61 protrudes from the annular projection (50) is located in the condensate storage chamber (30).

Body 10 may be installed in the upper cover 15 to open and close the guide road 40 in the upper portion to insert the buckle 60 in the guide road 40, the molding of the guide road 40 easily And, it is possible to easily replace the cleaning of the guide furnace 40 and the floats 60 and the floats (60).

The guide passage 40 and the condensate outlet 13 are connected to the body 10, and a discharge passage 70 is formed to be opened and closed according to the elevation of the float 60, and the middle is bent one or more times so that the steam S is It can be blocked further and drained only condensate.

As shown in FIG. 3, in the present invention, condensate (W) flowing through the condensate inlet 11 is stored in the condensate storage chamber 30 through the inlet passage 20, and the water level is an annular protrusion 50. The float 60 does not operate until it becomes the same plane as the lower surface 51 of.

As shown in FIGS. 4 and 5, when the level of the condensate W stored in the condensate storage chamber 30 is higher than the lower surface 51 of the annular protrusion 50, the buoy 60 is guided by buoyancy. The discharge path 70 is opened by rising along the furnace 40, and the condensate W stored in the condensate storage chamber 30 is discharged through the open discharge path 70 to the condensate outlet 13.

Floating ball 60 is preferably made of an egg-shaped egg diameter smaller than the upper portion 63, the diameter of the guideway 40 and the diameter of the annular projection (50) is also egg-shaped float (60) It is formed to be in close contact with, the lower portion 60 is raised when the lower portion 61 is opened from the inner wall surface of the annular projection 50 and the guide path 40, the gap (G) is formed, the gap (G) Due to the discharge path 70 is opened, the condensate stored in the condensate storage chamber 30 is introduced into the gap (G) flows to the open discharge path (70). The buoy 60 has a watertightness and is discharged to the upper portion of the guide passage 40 because the portion immediately above the portion where the gap G is formed rises in close contact with the inner wall surface of the guide passage 40. To be blocked.

If the water level of the condensate (W) is the same plane as the lower surface 51 of the annular projection 50, the buoyancy is lowered, the buoy 60 is lowered, and this eliminates the gap (G), thereby closing the discharge path (70) By doing so, the condensed water (W) is no longer discharged, and the outlet 60 repeats the ascending and descending of the annular protrusion 50 and discharges only the condensed water (W). .

In particular, even if steam (S) is introduced with the condensate (W), the steam (S) is trapped in the closed space (R) blocked through the water level around the annular projection (50), the level of the condensate (W) Since the float 60 is raised and lowered on the same surface as the lower surface 51 of the annular protrusion 50, the closed space R is not broken and the steam S trapped in the closed space R is not discharged. Do not. Steam (S) trapped in the closed space (R) can condense steam (S) continuously because the condensed water (W) is condensed over time.

On the other hand, as shown in Figure 6, the condensate inlet 11 may be provided with a filtration member 90 for filtering the condensate (W) flowing to the inlet (20). An approximately V-shaped extension passage 17 is formed between the condensate inlet 11 and the inlet passage 20, and a filtration member 90 is installed in the middle of the extension passage 17 to filter the condensate W. can do. The filtering member 90 is preferably separated from the body 10 so that cleaning is possible. The filter member 90 is formed in a cylindrical shape and filters foreign matters on the inner wall surface by flowing the condensed water (W) from the inside. Therefore, the inflow path 20 and the discharge path 70 are not blocked due to a pipe foreign matter such as rust, and are fixed to the outer wall of the buoy 60 so as to be in contact with the inner wall surface of the guide path 40 and the annular protrusion 50. There is no occurrence of a gap between the condensate (W) is discharged.

In addition, as shown in Figure 7, the condensate inlet 11 may be provided with an orifice member 80 having an orifice hole 81 having a diameter smaller than the condensate inlet 11, the orifice hole 81 is inlet Is connected to the furnace 20, the inflow passage 20 may have a diameter smaller than the orifice hole (81). Therefore, the orifice hole 81 of the orifice member 80 blocks the primary steam S, and the inflow passage 20 of the secondary orifice type blocks the steam S to more effectively block the steam S discharge. Can be.

In addition, the lower cover 14 of the body 10 may form a discharge port 103 that is opened and closed by the valve 105 to discharge the condensed water (W) of the condensate storage chamber 30 to the outside. Since the condensate (W) is very hot, there is a risk of burns when the lower cover (14) is removed. Therefore, the safety accident can be prevented by discharging the condensed water (W) accumulated in the condensate storage chamber 30 in advance.

As described above, according to the present invention, since the condensed water is discharged only by the operation of the buoy by buoyancy, the short life problem of the mechanical buckle is solved, and there is no opening / closing interval by the mechanical operation, thereby effectively blocking steam discharge.

In addition, since the steam introduced with the condensate is not discharged in the closed space even in the operation of the float, the loss of thermal energy is minimized.

In addition, since the inflow of steam is blocked by the orifice, the thermal efficiency can be increased.

The present invention has been described with reference to the preferred embodiments, and those skilled in the art to which the present invention pertains to the detailed description of the present invention and other forms of embodiments within the essential technical scope of the present invention. Could be. Here, the essential technical scope of the present invention is shown in the claims, and all differences within the equivalent range will be construed as being included in the present invention.

1: drain piping 10: body
11: condensate inlet 13: condensate outlet
14: lower cover 15: upper cover
20: inlet passage 30: condensate storage chamber
40: with guide 50: annular projection
51: 60: float
61: lower 63: upper
80: orifice member 81: orifice hole
90: filtration member

Claims (5)

A body 10 having a condensate inlet 11 and a condensate outlet 13 on the left and right sides, an inlet passage 20 formed in the body 10 and connected to the condensate inlet 11, and the body 10. Formed in the condensate storage chamber 30 connected to the inflow passage 20 and the body 10 and connected to the condensate storage chamber 30 and positioned on the condensate storage chamber 30. 40, an annular protrusion 50 protruding from the lower portion of the guide passage 40 and positioned in the condensate storage chamber 30, and inserted into the guide passage 40 and the guide passage 40. And a lower portion 61 protrudes from the annular protrusion 50 and is positioned in the condensate storage chamber 30, and is formed in the body 10 and the guide path 40. It connects the condensate outlet 13 and includes a discharge path 70 that is opened and closed in accordance with the lifting of the float 60,
Condensate flowing through the condensate inlet 11 is stored in the condensate storage chamber 30 through the inlet passage 20, and the level of condensate stored in the condensate storage chamber 30 is the annular protrusion ( If it is higher than the lower surface 51 of the 50, the outlet 60 is opened along the guide path 40, the discharge path 70 is opened, and the condensate storage through the open discharge path 70 Steam trap, characterized in that the condensed water stored in the chamber 30 is discharged to the condensate outlet (13).
According to claim 1,
The inlet passage 20 is a steam trap, characterized in that to form an orifice having a diameter smaller than the condensate inlet (11).
The method of claim 2,
An orifice member 80 having an orifice hole 81 having a diameter smaller than the condensate inlet 11 is installed at the condensate inlet 11, and the orifice hole 81 is connected to the inflow path 20. The steam trap is characterized in that the inflow path 20 has a diameter smaller than the orifice hole (81).
According to claim 1,
Steam traps that the condensate inlet 11 is provided with a filtration member 90 for filtering the condensate flowing in the inlet 20.
According to claim 1,
The sub-ball 60 is made of an egg shape having a smaller diameter than the lower part 61 than the upper part 63, and when the sub-ball 60 is raised, the lower part 61 is the annular protrusion 50 and the guide path ( A gap G is formed from the inner wall of the wall 40, and a condensate stored in the condensate storage chamber 30 flows into the gap G to flow to the discharge path 70. .

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