KR101376727B1 - Steam trap - Google Patents

Abstract

The present invention discloses a steam trap. The disclosed steam trap includes: a main body which connects to the steam pipes, a condensate discharge unit which connects the main body and the condensate discharge pipes to discharge the condensate collected in the main body; and an auxiliary orifice unit coupled to the condensate discharge unit which increases the speed of the condensate flow of the condensate discharge unit and discharges the condensate.

Description

Steam Traps {STEAM TRAP}

The present invention relates to a steam trap, and more particularly, to a steam trap that not only automatically discharges the condensate generated in the steam using device or steam pipe, but also facilitates processing and installation.

In steam (steam) transfer pipes, such as production facilities and heat exchangers that use steam, condensed water is generated in the transfer pipes due to the temperature difference between the inside and the outside of the transfer pipes due to high temperature and high pressure steam.

Such condensed water causes water hammer that hits the steam transport pipe during steam transport, and therefore causes a lot of noise in the steam transport pipe, and also lowers thermal efficiency. Accordingly, a steam trap is installed in the steam transport pipe to remove condensate.

Steam traps automatically discharge only condensate from the steam transport pipe, and are provided in various ways, and ball float, disc, bimetal, bucket, and orifice types are frequently used.

Ball float steam traps discharge condensate using the density difference between steam and condensate. It is not greatly influenced by sudden fluctuations of pressure and flow rate, but can be damaged by freezing.

Disc-type steam traps cause condensate to float inside the steam trap when the temperature in the trap is lowered and the pressure in the pressure chamber is lowered.

In the bimetallic steam trap, when the condensate accumulates in the steam trap, the temperature in the trap decreases, and the ball valve is opened by the action of the bimetal to discharge the condensate. In addition, the bimetallic steam trap bimetal is formed by attaching two kinds of metals having different thermal expansion rates, and bends due to temperature change.

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

The orifice type steam trap keeps the discharged condensate occupying the orifice hole and prevents the leakage of steam.

Among these steam traps, orifice steam traps are economically advantageous due to advantages such as minimizing steam leakage, no need of an operation tool, a small heating area, and an improved heat transfer rate for the heating element.

However, the conventional orifice steam traps as described above are difficult to process orifice holes having a small diameter, which not only decreases productivity, but also require a total replacement of the orifice steam traps in order to change the size of the orifice holes. There is a rising problem.

Therefore, there is a need to improve this.

Korean Patent Registration No. 10-1189706 (Registration Date: 2012.10.04, Name: Orifice Steam Trap) Korean Patent Registration No. 10-0244999 (Registration Date: November 25, 1999, Name: Steam Trap Device)

The present invention has been created by the necessity as described above, can be easily installed by adjusting the size of the orifice hole according to the size and the use of the steam pipe, can be easily processed the orifice hole steam trap that can improve productivity The purpose is to provide.

Steam trap according to an embodiment of the present invention to achieve the above object is: a main body connected to the steam pipe; A condensed water discharge unit connecting the main body and the condensed water discharge pipe to discharge the condensed water collected in the main body; And an auxiliary orifice unit coupled to the condensate discharge unit to increase and discharge the condensate flow rate of the condensate discharge unit.

In addition, the auxiliary orifice unit is characterized in that coupled to the discharge direction of the condensate from the condensate discharge unit.

In addition, the auxiliary orifice unit, the coupling portion is pressed into the inner surface of the first orifice hole of the condensate discharge unit; And a support part supported at an inlet side of the first orifice hole.

The coupling part may include a press-fit surface having a diameter equal to an inner diameter of the first orifice hole or a diameter larger than an inner diameter of the first orifice hole; And a guide surface extending from the press-fit surface to have a diameter smaller than the inner diameter of the first orifice hole.

In addition, the coupling portion, characterized in that the chip inlet is formed between the pressing surface and the guide surface in which the chip generated by the push of the first orifice hole is formed.

In addition, the coupling portion, characterized in that the length is formed longer than the length of the first orifice hole.

In addition, the auxiliary orifice unit, the second orifice hole is formed, characterized in that it further comprises a second decompression unit for reducing the pressure of the condensate flowing into the second orifice hole.

In addition, the auxiliary orifice unit, the second orifice hole is formed, characterized in that it further comprises a second booster for increasing the pressure of the condensate discharged from the second orifice hole.

As described above, the steam trap according to the present invention can be used by selectively combining the auxiliary orifice unit with the first orifice hole of the condensate discharge unit, unlike the prior art, according to the size or use of the steam pipe of the first orifice hole The size can be easily adjusted.

In addition, since the present invention forms a second orifice hole having a small diameter in the auxiliary orifice unit, the orifice hole having a small diameter can be easily processed, thereby improving productivity.

1 is a perspective view showing a steam trap according to an embodiment of the present invention.
2 is a cross-sectional view of Fig.
3 is an exploded perspective view showing a steam trap according to an embodiment of the present invention.
Figure 4 is a perspective view of the condensate discharge unit and the auxiliary orifice unit according to an embodiment of the present invention.
Figure 5 is an enlarged perspective view of the main portion showing a state in which the auxiliary orifice unit is coupled to the condensate discharge unit according to an embodiment of the present invention.
6 is a cross-sectional view of the combination of FIG.
7 is an enlarged view of a portion “A” of FIG. 6.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the steam trap according to the present invention. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

1 is a perspective view showing a steam trap according to an embodiment of the present invention, Figure 2 is a cross-sectional view of Figure 1, Figure 3 is an exploded perspective view showing a steam trap according to an embodiment of the present invention, Figure 4 4 is a perspective view illustrating a condensate discharge unit and an auxiliary orifice unit according to an embodiment of the present invention. FIG. 5 is a cross-sectional view of FIG. 4, and FIG. 6 is an enlarged view of a main part of FIG. 5.

As shown in Figures 1 to 3, the steam trap 100 according to the present embodiment is connected to the steam pipe 101, the steam is transported to collect the condensed water generated in the steam pipe 101, the collected condensed water To the condensate discharge pipe (103).

The steam trap 100 includes a main body 110 connected to the steam pipe 101, a condensate discharge unit 120 connecting the main body 110 and the condensate discharge pipe 103, and the condensate discharge unit 120. Auxiliary orifice unit 130 is coupled to the).

At this time, the steam trap 100 according to the present embodiment, the condensate discharge unit 120 and the auxiliary orifice unit 130 so that the diameter of the orifice hole for discharging the condensate by reducing pressure can be easily adjusted according to the size or pressure of the steam transfer pipe. Orifice hole size of, for example, the diameter of the orifice hole is formed to have a different size.

The main body 110 has an inlet connected to the steam pipe 101 and the condensate discharge unit 120 is connected to the discharge port, and the branch port 111 for removing condensate collected inside or discharging the internal pressure when an abnormal pressure is generated. Equipped. In this case, a blowdown valve (not shown) may be connected to the branch 111.

In addition, the main body 110 is provided with a foreign matter removing member 113 is inserted through the branch 111 to prevent foreign substances contained in the steam and condensate flowing into the condensate discharge unit 120.

The coupler 111 is coupled to the connector 115 for fixing the foreign matter removing member 113 and connecting the blowdown valve.

The foreign material removing member 113 is one end is in close contact with the inside of the main body 110, the other end is supported by the connector 115.

The debris removal member 113 includes a cylindrical sieve 113a for removing debris and a ring member 113b for stably fixing the main sieve 110 while preventing deformation of the sieve 113a. . The ring members 113b are respectively joined to both ends of the strainer 113a by welding, and the ends thereof have a round shape.

As such, forming the round guide portion in the ring member 113b is when fastening the debris removing member 113 by fastening the connector 115 in a state where the debris removing member 113 is inserted into the branch 111. In order to prevent the deformation of the foreign material removing member 113, the main body 110 and the connector 115 to be smoothly inserted and fixed to the coupling position.

The condensate discharge unit 120 and the auxiliary orifice unit 130 according to the present embodiment will be described in more detail with reference to FIGS. 4 to 7.

Figure 4 is a perspective view showing a condensate discharge unit and the auxiliary orifice unit according to an embodiment of the present invention, Figure 5 is an enlarged perspective view showing the main portion of the auxiliary orifice unit coupled to the condensate discharge unit according to an embodiment of the present invention 6 is a cross sectional view of FIG. 4, and FIG. 7 is an enlarged view of portion “A” of FIG. 6.

4 to 7, the condensate discharge unit 120 according to the present embodiment has a male screw portion formed on an outer surface of one end portion to be fastened to an outlet of the main body 110, and a condensate discharge tube 103 on the inner surface of the other end. The female screw portion to be fastened is formed.

The condensate discharge unit 120 includes a first orifice hole 121 formed in a central portion of the condensate discharge unit 120 so as to smoothly discharge the condensed water collected in the main body 110, and the first reduced pressure at both ends of the first orifice hole 121. The part 123 and the first booster 125 are formed, respectively.

The auxiliary orifice unit 130 is press-fitted into the first orifice hole 121 so that the size of the first orifice hole 121 is adjusted according to the size of the steam transfer pipe or the steam pressure .

In addition, the first pressure reducing portion 123 of the condensed water discharging unit 120 has a multi-stepped hole shape in which the diameter of the condensed water discharging unit 120 is gradually reduced so that the pressure of the condensed water gradually increases.

In addition, the first booster 125 of the condensate discharge unit 120 has a multi-stage hole shape in which the diameter thereof gradually increases so that the pressure of the condensate discharged from the first orifice hole 121 gradually increases.

In the present exemplary embodiment, although the first pressure reducing part 123 of the condensate discharge unit 120 is formed in a three-stage hole shape, and the first booster part 125 is formed in a two-stage hole shape, it is shown as required by a user. The first pressure reducing part 123 may be formed in two or more stages, or the first pressure increasing part 125 may be formed in three or more stages.

The auxiliary orifice unit 130 coupled to the condensate discharge unit 120 to adjust the size or diameter of the first orifice hole 121 increases the flow rate of the condensate by reducing the diameter of the first orifice hole 121. .

Auxiliary orifice unit 130 according to the present embodiment is the size of the first orifice hole 121 of the condensate discharge unit 120 according to the size or use of the steam pipe 101, the steam pressure of the steam pipe 101 It is detached to the first orifice hole 121 to easily adjust.

In addition, the auxiliary orifice unit 130 includes a coupling part 131 press-fitted into the first orifice hole 121 and a support part 133 supported by the condensate discharge unit 120. At this time, the supporting portion 133 of the auxiliary orifice unit 130 is formed to have a larger diameter than the engaging portion 131.

The auxiliary orifice unit 130 is coupled in a direction in which condensed water is discharged from the inlet side of the first orifice hole 121 so that the support part 133 is supported by being in contact with the bottom surface of the first pressure reducing part 123. This prevents the auxiliary orifice unit 130 from being disengaged or flowing from the first orifice hole 121 by the discharge pressure of the reaction shafts.

In addition, the auxiliary orifice unit 130 is longer than the length of the first orifice hole 121 of the coupling portion 131 is coupled to the first orifice hole 121, the end of the coupling portion 131 is the first It is exposed to the outlet side of the orifice hole 121. Thus, when the auxiliary orifice unit 130 is separated from the condensate discharge unit 120, the coupling part 131 may be hit by the first booster 125 to be easily separated.

Coupling portion 131 is the same as the inner diameter of the first orifice hole 121 or smaller than the inner diameter of the first orifice hole 121 and the indentation surface 131a having a diameter larger than the inner diameter of the first orifice hole 121 It consists of a guide surface 131b extending from the press-fit surface 131a to have a diameter. At this time, the guide surface 131b is formed to be inclined downward so that its diameter decreases.

The coupling part 131 is easily inserted into the first orifice hole 121 by the guide surface 131b and the press-fitting surface 131a is firmly press-fitted into the first orifice hole 121.

In addition, the coupling part 131 further includes a chip inflow part 131c into which a chip generated in the process of being coupled to the first orifice hole 121 is introduced so as to be more easily and completely coupled to the first orifice hole 121. do.

The chip inflow portion 131c is formed in a groove shape between the press-in surface 131a and the guide surface 131b. The press-in surface 131a is press-fitted into the first orifice hole 121, The chip which flows in due to the fatigue phenomenon is introduced. Thus, the engaging portion 131 can be completely press-fitted into the first orifice hole 121.

On the other hand, the auxiliary orifice unit 130 according to the present embodiment is the second orifice hole 135, the second pressure reducing portion 137 and the first formed on the inlet side and the outlet side of the second orifice hole 135, respectively 2 further includes a booster (139).

The second decompression unit 137 is formed of a taper whose diameter gradually decreases to gradually depressurize the pressure of the condensed water introduced through the first decompression unit 123, and the second pressure-reducing unit 139 also includes a second pressure reducing unit 139. 1 It is formed of a taper whose diameter gradually increases so that the condensed water discharged to the booster 125 may be gradually increased and discharged.

In the present embodiment, for example, the tapering of the second pressure reducing part 137 and the second boosting part 139 is described.

As described above, the auxiliary orifice unit 130 according to the present embodiment can easily process the second orifice hole 135, the second pressure reducing part 137, and the second pressure increasing part 139 having a small diameter, and thus productivity Can improve.

The operation and operation of the steam trap according to an embodiment of the present invention will now be described.

First, the auxiliary orifice unit 130 in which the second orifice hole 135 is processed to fit the size and steam pressure of the steam pipe 101 is coupled to the first orifice hole 121 of the condensate discharge unit 120. At this time, the condensed water is discharged from the inlet side of the first orifice hole 121 so that the auxiliary orifice unit 130 is prevented from being separated from the first orifice hole 121 by the discharge pressure of the condensate. Insert in the direction and join.

Then, as the auxiliary orifice unit 130 is easily guided and inserted into the first orifice hole 121 by the guide surface 131b formed to be inclined, the press-fit surface 131a is coupled to the first orifice hole 121 by press-fitting. .

At this time, a chip inflow portion 131c is formed between the press-in surface 131a and the guide surface 131b so that chips generated due to press-fitting of the press-in surface 131a enter the chip inflow portion 131c The auxiliary orifice unit 130 can be more completely and firmly coupled to the first orifice hole 121. [

As such, the size of the first orifice hole 121 of the condensate discharge unit 120 may be variously and easily changed through the auxiliary orifice unit 130. Accordingly, the size of the first orifice hole 121 of the condensate discharge unit 120 can be easily adjusted, and the size of the first orifice hole 121 can be adjusted without replacing the entire condensate discharge unit 120. The production cost can be reduced significantly.

In particular, compared to forming a small diameter orifice hole in the center of the bulky condensate discharge unit 120, the orifice hole of a small diameter in the secondary orifice unit 130 is very small compared to the condensate discharge unit 120 It is easier and simpler to process, thus improving productivity.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. I will understand.

Accordingly, the true scope of protection of the present invention should be defined by the claims.

100: steam trap 101: steam piping
103: condensate discharge pipe 110:
111: minute mechanism 113: foreign matter removing member
115: Connection port 120: Condensate discharge unit
121: first orifice hole 123: first decompression section
125: first boosting unit 130: auxiliary orifice unit
131: coupling portion 133: support portion
135: second orifice hole 137: second pressure-reducing section
139: second boosting unit

Claims (8)

A main body connected to the steam pipe; A condensate discharge unit connecting the main body and the condensate discharge pipe to discharge the condensed water collected by the main body; And an auxiliary orifice unit coupled to the condensate discharge unit to increase and discharge the condensate flow rate of the condensate discharge unit. And a support portion supported on the inlet side of the first orifice hole,
The coupling part may include a press-fit surface having a diameter equal to an inner diameter of the first orifice hole or a diameter larger than an inner diameter of the first orifice hole; And a guide surface extending from the indentation surface to have a diameter smaller than an inner diameter of the first orifice hole, wherein a chip generated by the roughening of the first orifice hole is introduced between the indentation surface and the guide surface. Steam trap, characterized in that the chip inlet is formed. The method of claim 1,
The auxiliary orifice unit is a steam trap, characterized in that coupled in the direction to discharge the condensate from the condensate discharge unit. delete delete delete The method of claim 1,
The coupling portion, the steam trap, characterized in that the length is formed longer than the length of the first orifice hole. The method of claim 1,
The auxiliary orifice unit, the second orifice hole is formed, the steam trap further comprises a second pressure reducing unit for reducing the pressure of the condensate flowing into the second orifice hole. The method of claim 1,
The auxiliary orifice unit, the second orifice hole is formed, the steam trap further comprises a second booster for increasing the pressure of the condensate discharged from the second orifice hole.

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