KR101463966B1 - Steam trap with multi orifice - Google Patents

Abstract

The present invention relates to a steam trap with orifices that can automatically discharge only condensate water, in which steam is removed from the condensate water generated from a steam pipe, such as production facilities operated by steam, steam pipe facilities, and heat exchangers, by a multiple-orifice structure, thereby preventing leakage of the steam and improving the efficiency of heat energy and the productivity of the production facility using the steam, reducing the costs of the products, and contributing to the low-carbon green growth. The steam trap includes a body with one side being connected to a steam pipe and the other side being provided with a female threaded portion; a condensate water discharge unit threaded and connected to the female threaded portion and connecting the body and a condensate water discharge pipe to discharge the condensate water collected by the body; and an orifice unit engaged to the inside of the condensate water discharge unit and having at least two filter holes to suppress discharge of steam and discharge the condensate water. The orifice unit has a first orifice portion forming a first filter hole, and a second orifice portion threaded and engaged with the first orifice portion and forming a second filter hole.

Description

TECHNICAL FIELD [0001] The present invention relates to a steam trap with multiple orifices,

[0001] The present invention relates to a steam trap, and more particularly, to a steam trap which is capable of removing steam generated from steam piping by a plurality of orifice structures in production facilities, steam pipes, heat exchangers, Steam is prevented from leaking out and the use efficiency of heat energy is increased so that the productivity of the production equipment using steam can be improved, the cost of the product to be produced can be reduced, and steam having a large number of orifices contributing to green growth and low- Trap.

In the piping pipes for steam (steam) in the production facilities using steam (steam, steam), heat exchanger and steam piping facilities, the temperature difference between the inside and the outside of the piping is large due to the high temperature and high pressure steam. It is very common that condensation water or condensation water is generated in the transfer pipe due to the temperature difference.

Such condensed water is moved along with the steam along the steam transfer path, and the steam transfer pipe hits the steam transfer pipe to cause a lot of noise in the steam transfer pipe, which causes a water hammer and causes a decrease in heat efficiency. SteamGard or steam trap may be installed on the steam transfer pipe to remove condensate.

The steam trap automatically discharges the condensate of the steam transfer pipe to the outside of the steam transfer pipe, and various techniques such as the ball float method, the disk method, the bimetal method, the bucket method, and the orifice method are introduced and used.

The ball float type steam trap is a system that automatically discharges condensate to the outside of the steam transfer pipe by using the density difference between steam and condensate. It is not affected greatly by sudden fluctuation of pressure and flow rate, but it causes damage due to freezing .

The disc type steam trap is operated in such a manner that when the condensed water stays in the corresponding steam trap, the internal temperature of the steam trap is lowered and the pressure in the transformer chamber is lowered, thereby discharging the condensed water to the outside.

The bimetal type steam trap is designed such that when the condensed water flows into the corresponding steam trap, the internal temperature of the steam trap is lowered and the bimetal acts, so that the ball valve is opened and the condensed water is discharged to the outside. Here, the bimetal of the bimetallic steam trap is made of two kinds of metals having different coefficients of thermal expansion, and is bent by the temperature change.

A bucket type steam trap is a method in which a bucket floats to close (close) a drain valve. When condensate flows from an inlet to a drain, the bucket of the drain sinks and the drain valve directly connected to the bucket opens. And the condensate in the bucket is discharged to the outside through the drain.

The orifice type steam trap is configured such that the discharged condensed water occupies the orifice hole and is operated in such a manner as to prevent the leakage of steam.

Of these steam traps, the orifice method has an advantage of minimizing leakage of steam, eliminating the need for an operating structure, having a small heat generating area, and improving the heat transfer coefficient to the heating body.

However, since the orifice type steam trap of the related art as described above discharges condensed water and discharges steam together, the utilization efficiency of heat energy or steam energy is comparatively low, and thus the productivity of the production equipment using steam is lowered, There is a problem that it does not greatly contribute to growth and low carbon generation.

Therefore, it is necessary to develop a technology to reduce the discharge of steam from the orifice and to discharge only condensate.

Korea Patent Registration No. 10-1189706 (Apr. 4, 2012) "Title: Orifice Steam Trap" Korea Patent Registration No. 10-0244999 (November 25, 1999) "Title: Steam Trap Device"

The present invention provides a steam trap having a plurality of orifices and a plurality of orifices for discharging only condensed water by changing a hole size of each orifice.

The present invention also provides a steam trap having a plurality of orifices for reducing the steam discharged by adjusting the number of orifices constituting the steam system by a plurality of orifices and discharging only condensed water.

Also, the present invention provides a steam trap having a plurality of pressure-reducing chambers and a plurality of orifices for shutting off the discharge of steam as much as possible and discharging only condensed water.

The present invention provides a steam trap having a large number of orifices for increasing the energy efficiency of the steam system, improving the productivity of the production equipment, reducing the cost of the product, and contributing to green growth and low carbon generation.

In order to achieve the above object, a steam trap according to the present invention includes a main body 110 having one side connected to a steam pipe 101 and a female screw 116 formed on an inner side surface of the other side; A condensed water discharge unit 120 that connects the main body 110 and the condensed water discharge pipe 103 so as to discharge the condensed water collected by the main body 110 by screwing with the internal threaded portion 116; And an orifice unit (130) coupled to the interior of the condensed water discharge unit (120) and having at least two or more multiple filter holes for discharging steam and discharging condensed water, the orifice unit (130) A first orifice portion 1000 having a filter hole 1050 formed therein and a second orifice portion 2000 screwed with the first orifice portion 1000 and forming a second filter hole 2060, have.

The first orifice part (1000) has a protruding protrusion (1010) fixed to an end of one end of the condensed water discharge unit (120) and protruding at a diameter larger than the diameter of the first body part (1100); A first depressurizing portion 1020 formed at a central portion where the protruding protrusion 1010 is formed; A first partition wall 1030 separating the first depressurization part 1020 and formed in the radial direction of the condensed water discharge unit 120; The first partition wall 1030 is formed from one side of the first partition wall 1030 to a middle portion of the thickness of the first partition wall 1030 and is formed at a central position of the first partition wall 1030 in the direction of the first decompression part 1020 A first movement path 1040 formed in an enlarged triangular pyramid shape; A first filter hole 1050 connected to the first movement path 1040 and extending to the other end of the first partition wall 1030 and having a uniform diameter; A first boosting portion 1060 connected to the first filter hole 1050 and formed at a longitudinal intermediate position of the first orifice portion 1000; A first seating surface 1070 formed on the cylindrical wall surface of the first thickening portion 1060; A first insertion hole (1080) connected to the first mounting jaw (1070) and extended to the other side end of the condensed water discharge unit (120); And a female screw portion (1090) continuously formed in a spiral shape on an inner circumferential surface of the first insertion hole (1090); . ≪ / RTI >

The second orifice part 2000 has a cylindrical insertion part 2010 formed at one side of the second orifice part 2000 and having a diameter smaller than the diameter of the second body part 2090; An inclined portion 2020 formed at an end portion of one side of the insertion portion 2010 so as to be inclined; A male screw portion 2030 continuously formed in a spiral shape on the cylindrical surface of the insert 2010; A second insertion hole 2040 formed at a central portion of the insertion portion 2010; A second partition wall 2050 which separates the second insertion hole 2040 and is formed in the radial direction of the second orifice 2000; A second filter hole 2060 having a uniform diameter at the center of the second partition wall 2050 and penetrating from one side of the second partition wall 2050 to the other side; A second boosting portion 2070 connected to the second filter hole 2060 and extending to the other end of the second orifice portion 2000; And a female screw portion 2080 continuously formed in a spiral shape on an inner circumferential surface of the second boosting portion 2070; . ≪ / RTI >

The diameter of the first filter hole 1050 may be larger than the diameter of the second filter hole.

The condensed water discharge unit 120 includes a male screw part 121 screwed to the female screw part 116 and formed on an outer peripheral surface of one side of the body part 126; A female screw portion 122 continuously formed in a spiral shape on the inner circumferential surface of the other side of the condensed water discharge unit 120; An orifice hole 123 formed in the center of the male thread 121 and inserted or inserted into the orifice unit 130; An orifice seating jaw 124 which separates the orifice hole 123 and is formed in the center of the diameter of the condensed water discharge unit 120; A boosting portion 125 connected to the orifice seating jaw 124 and extended to the other end of the condensed water discharging unit 120; . ≪ / RTI >

The female screw portion 1090 is screwed to the male screw portion 2030 and the orifice unit 130 is inserted into the orifice hole 123 and fixedly installed.

The orifice unit 130 may further include a third orifice part 3000.

According to the present invention, since the orifices are formed in a large number and the orifices have different hole sizes, only the condensed water is discharged and the discharge of steam is blocked.

Further, the present invention is advantageous in that even when the steam pressure of the steam system is high, the number of orifices constituted by a plurality of orifices is adjusted to reduce steam exhausted and to discharge only condensed water.

In the meantime, the present invention has an advantage in that a number of decompression chambers are formed to shut off the discharge of steam and to discharge only condensed water.

The present invention has the advantage of increasing energy efficiency, increasing productivity of production facilities, reducing product cost, contributing to green growth and low-carbon generation by controlling steam emission to a minimum

FIG. 1 is a perspective view illustrating a steam trap having a plurality of orifices according to an embodiment of the present invention. FIG.
FIG. 2 is a perspective view of a steam trap having a plurality of orifices according to an embodiment of the present invention,
FIG. 3 is an exploded perspective view illustrating a configuration of a steam trap having a plurality of orifices according to an embodiment of the present invention. FIG.
FIG. 4 is a cross-sectional perspective view of a steam trap having a plurality of orifices according to an embodiment of the present invention,
FIG. 5 is a cross-sectional view of a steam trap having a plurality of orifices according to an embodiment of the present invention,
6 is an enlarged partial sectional view for explaining a first orifice according to an embodiment of the present invention,
7 is an enlarged partial sectional view for explaining a second orifice according to an embodiment of the present invention,
And
8 is a cross-sectional view of a steam trap according to a second embodiment of the present invention, illustrating a steam trap having a plurality of orifices.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is capable of various modifications and various embodiments, and specific embodiments are illustrated in the drawings and will be described in detail in the detailed description. It should be understood, however, that the invention is not intended to be limited to the particular embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. In the following description, the steam pipe is a general cylindrical pipe, and the remaining constitution is also a corresponding configuration. The steam and the steam are the same meaning, and they can be mixed and used selectively in accordance with the context.

FIG. 1 is a perspective view illustrating a steam trap having a plurality of orifices according to an embodiment of the present invention. FIG. 2 is a perspective view of a steam trap having a plurality of orifices, 3 is an exploded perspective view illustrating a structure of a steam trap having a plurality of orifices according to an embodiment of the present invention.

1 to 3, a steam trap 100 having a plurality of orifices includes a main body 110, a condensed water discharge unit 120, and an orifice unit 130.

The steam trap 100 collects the condensed water (condensation water) generated in the steam pipe 101 to which the steam is transferred, and discharges the collected condensed water to the condensate discharge pipe 103.

That is, the steam trap 100 includes a main body 110 connected to the steam pipe 101, a condensed water discharge unit 120 connecting the main body 110 and the condensed water discharge pipe 103, And an orifice unit 130 which is press-fitted.

Here, the steam trap 100 according to an embodiment of the present invention is a condensate discharge unit (not shown) for easily adjusting the hole diameter of the orifice unit 130 for reducing and discharging the condensed water according to the diameter of the steam pipe, 120 and the orifice hole 130 of the orifice unit 130 can be arbitrarily selected.

The main body 110 has an inlet connected to the steam pipe 101 and an outlet connected to the condensed water discharge unit 120. In addition, when the abnormal pressure is generated, a dispenser 111 for removing the condensed water collected inside or discharging the internal pressure to the outside is provided. At this time, a blow-down valve 116 may be connected to the branch mechanism 111.

In addition, the main body 110 inserts the foreign matter removing member 113 into the dispenser 111 to prevent foreign substances contained in the steam and the condensed water from flowing into the condensed water discharge unit 120.

The dispensing mechanism 111 is formed with a coupling hole 115 for fixing the foreign substance removing member 113 and connecting the blowdown valve. One end of the foreign material removing member 113 is in close contact with the inside of the main body 110 and the other end is held in a fixed state by the connecting hole 115.

The foreign matter removing member 113 includes ring members at both ends to stably fix the main body 110 to the main body 110 while preventing deformation of the cylindrical and sieve-like filtering nets for removing foreign substances. The ring members are respectively joined to both ends of the sieve through a welding method, and the ends thereof are rounded.

The rounded guide portion is formed on the ring member when the foreign material removing member 113 is inserted into the distributing mechanism 111 and the connecting hole 115 is fastened to fix the foreign material removing member 113, 113 are prevented from being deformed while being smoothly inserted and fixed to the coupling position of the main body 110 and the coupling hole 115.

The condensed water discharge unit 120 and the orifice unit 130 according to an embodiment of the present invention will be described in detail with reference to FIGS.

FIG. 4 is a cross-sectional perspective view of a steam trap having a plurality of orifices according to an embodiment of the present invention. FIG. 5 is a cross-sectional perspective view illustrating a steam trap having a plurality of orifices, FIG. 6 is an enlarged partial cross-sectional view for explaining a first orifice according to an embodiment of the present invention, and FIG. 7 is an enlarged partial cross-sectional view for explaining a second orifice according to an embodiment of the present invention. to be.

4 to 7, a condensed water discharge unit 120 according to an embodiment of the present invention includes a water thread portion 121 formed on an outer surface of one side end portion to be fastened to a discharge port of the main body 110, And a female screw portion 122 to which the condensed water discharge pipe 103 is fastened is formed on the inner surface. Therefore, the female threaded portion 116 is formed on the body 110 at the position corresponding to the male threaded portion 121 and is screwed to the male threaded portion 121.

The orifice hole 123 is formed in the center of the condensate discharge unit 120 so that the condensed water collected in the main body 110 can be discharged smoothly and the orifice seat 124 is formed at the rear of the orifice hole 123 And a pressure increasing portion 125 are sequentially formed on the rear portion of the orifice mounting step 124. [

The outer diameter of the male screw part 121 is larger than the outer diameter of the body part 126. The outer diameter of the male screw part 121 is smaller than the outer diameter of the body part 126, And the male screw part 121 and the body part 126 are connected by an inclined part 127 forming a predetermined inclination angle.

The condensate discharging unit 120 can arbitrarily select the number of the orifice hole 130 and the number of the orifice hole 130 according to the diameter of the steam pipe 101 to which the steam is transferred or the steam pressure.

The length of the orifice hole 123 formed in the condensed water discharge unit 120 must be changed to correspond to the length of the orifice unit 130 when the number of the orifice unit 130 is adjusted or changed. A detailed description of changing the length of the orifice hole 123 due to the change of the number will be omitted.

The orifice unit 130, whose component number is adjusted, is coupled to the inside of the orifice hole 123 by forced press-fitting. In addition, the orifice unit 130 may form a tapered inclination generally normal to the outer diameter of the orifice hole 123 so that insertion or insertion of the orifice unit 130 into the orifice hole 123 is relatively easy.

The orifice unit 130 includes a first orifice portion 1000 and a second orifice portion 2000.

The first orifice part 1000 is inserted into the orifice hole 123 in the following order after the second orifice part 2000 is first inserted into the orifice hole 123.

The first orifice part 1000 has a protruding protrusion 1010 formed at the end of one side of the condensed water discharging unit 120 and an end of the one end of the condensed water discharging unit 120, 1 body portion 1100 is formed.

A first depressurizing portion 1020 is formed at a central portion or an inner diameter portion of one side of the first orifice portion 1000 where the protrusion 1010 is formed. The first depressurization portion 1020 is defined by the first partition wall 1030.

The first partition wall 1030 has a first moving path 1040 having a triangular-pyramidal shape for moving steam and condensed water, and a first filter hole 1050 having a uniform diameter is formed on the other end So as to be penetrated.

The first filter holes 1050 may be formed in a diameter of 1.5 to 1 millimeter in size, preferably in a diameter of 1 millimeter in size to lower the temperature of the steam, speed up the discharge of condensed water, and reduce the pressure. If the diameter is larger than 1 millimeter, the temperature of the steam is relatively difficult to lower, the discharge of the condensate is relatively late, and the pressure is also relatively difficult to lower. Also, if the diameter is smaller than 1 millimeter in size, no enhancement of this effect was observed.

The first booster portion 1060 is formed in a region defined by the other side of the first partition wall 1030 and the first booster portion 1060 is configured to pressurize the steam passing through the first filter hole 1050, ≪ / RTI >

A first seating surface 1070 is formed at the end of the first pressure increasing portion 1060 so that the inner diameter of the first pressure increasing portion 1060 is slightly narrower than the inner diameter of the first pressure increasing portion 1060 and extends to the other end end portion of the first orifice portion 1000 The first insertion hole 1080 is formed. A female screw portion 1090 is formed on the inner diameter of the first insertion hole 1080.

One or more than one or at least two or more of a protruded (embossed) keyed or an inserted (embored) keyed groove may be formed instead of the female threaded portion 1090 as needed.

The insertion portion 2010 inserted into the first insertion hole 1080 is formed at one side of the second orifice portion 2000 and the body portion 2090 is formed at the other side. On the other hand, it is highly desirable to form the inclined portion 2020 at one end of the insertion portion 2010 so as to be easily inserted into the first insertion hole 1080.

The outer diameter of the insertion portion 2010 is formed to correspond to the female screw portion 1090 and is screwed to the male screw portion 2030 to prevent steam from leaking.

If necessary, the male screw portion 2030 may be structured such that a key or key formed in the inner diameter of the first insertion hole 1080 is formed with a corresponding key groove or key, so that the steam is not leaked.

A second insertion hole 2040 is formed in the center of the insertion portion 2010 so that one side of the insertion portion 2010 is penetrated by the first boosting portion 1060 and a second separation wall 2050 is formed on the other side thereof.

A second filter hole 2060 having a uniform diameter is formed in the central portion of the second separation variant 2050 from the one side portion through which the second insertion hole 2040 is formed to the other side portion.

The diameter of the second filter hole 2060 is made smaller than the diameter of the first filter hole 1050, and is formed with a diameter of 1.3 to 0.8 millimeter size, preferably a diameter of 0.8 millimeter.

When the diameter of the second filter hole 2060 is larger than 0.8 mm, the temperature of the steam (steam) is relatively difficult to lower, the discharge of the condensed water is relatively late, and the pressure is also relatively difficult to lower. Further, when the diameter is smaller than 0.8 millimeter in size, no enhancement phenomenon of this effect was observed.

Since the diameter of the second filter hole 2060 is smaller than the diameter of the first filter hole 1050, the vapor discharge is suppressed as a whole and only the condensed water is discharged.

A second increased pressure portion 2070 is formed at the other end of the second partition wall 2050.

The second pressure increasing portion 2070 may have a female screw 2080 having the same configuration as the female screw portion 1090 or a key or a key groove may be formed.

Here, the outer diameter of the first body part 1100 and the outer diameter of the second body part are preferably the same size and are preferably cylindrical, but they can be formed in a polygonal shape if necessary and form a uniform inclination angle or taper can do.

8 is a cross-sectional view of a steam trap according to a second embodiment of the present invention, illustrating a steam trap having a plurality of orifices.

The orifice unit 130 includes a first orifice portion 1000, a second orifice portion 2000, and a third orifice portion 3000.

The third orifice portion 3000 to the Nth orifice portion may have a configuration and an action similar to those of the second orifice portion 2000. The third orifice portion 3000 may include a fourth orifice portion, a fifth orifice portion, and an Nth orifice portion, And the description of the duplication is omitted.

In the third embodiment, the orifice unit may include only the first orifice portion 1000.

The adjustment of the number of the orifice portions 1000, 2000, and 3000 constituting the orifice unit 130 to be further increased or decreased can be arbitrarily selected according to the pressure of the steam to be used, Can be further increased.

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

The female screw portion 1090 of the first orifice portion 1000 and the male screw portion 2030 of the second orifice portion 2000 are screwed to each other to constitute the orifice unit 130. Here, the male screw portion 2030 of the second orifice portion 2000 is easily inserted into the female screw portion 1090 of the first orifice portion 1000 by the inclined portion 2020.

The orifice unit 130 is press-fitted into the orifice hole 123 of the condensate discharge unit 120 and fixed.

At this time, the protruding jaw 1010 covers one side end of the condensed water discharge unit 120, so that the orifice unit 130 is not completely inserted into the orifice hole 123. Accordingly, when the orifice unit 130 is separated from the condensed water discharge unit 120 as required, it can be easily separated and removed.

Since the orifice unit 130 is abradable, it is relatively preferable to replace the orifice unit 130 with a new one after use for a predetermined period of time.

Meanwhile, the male screw portion 121 of the condensed water discharge unit 120 is fixed to the female screw portion 116 of the body 110 by screwing.

Then, the condensed water discharge pipe (103) is screwed into the female threaded portion (122) of the condensed water discharge unit (120).

The condensate discharge unit 120 including the orifice unit 130 is made of a metal material of stainless steel 304, 303, 316 or ductail, and the outer surface can be polished or matte if necessary.

The production facility in which the steam trip is used may be a fiber drying cylinder, an AHU, a unit heater, a laundry, a sauna, a dryer, a tracing line, a line drip, and the like.

Here, the pressure of the steam (steam) is assumed to be 1.4 BAR (20 psig) in one embodiment.

The condensed water in this condition is 700 times as heavy as the steam of the same volume and it is general that heavy condensed water hardly passes through the first filter hole 1050 and the second filter hole 2060 having a small inner diameter, The smaller the pressure, the smaller the pressure.

The discharge capacity of the condensate in the fixed orifice is proportional to the square root of the vapor pressure.

The major difference between volume and density, physical characteristics of steam and condensed water, is clearly interpreted as the interference phenomenon that occurs while passing through the fixed nozzle, and the diameter of the second filter hole 2060 is larger than the diameter of the first filter hole 1050 It is a technical idea to reduce the size and thus to prevent the loss of energy due to the discharge of steam and to discharge only the condensed water.

The volume of steam and condensate of the same weight is as large as 818 to 1 at atmospheric pressure. The flow rates of steam and condensate through the nozzles are 340 m / sec and 10-50 m / sec, respectively, and when the two fluids are mixed, the discharge rate of steam is limited by the speed of the condensate. The above configuration uses such a physical phenomenon.

The orifice unit 130 may be formed to have a forced fit structure so as not to be automatically separated from the orifice hole 123 by repeated impact or vibration, and may be configured to be screwed as necessary.

The present invention having the above-described structure improves energy utilization efficiency by 5 to 30% and increases productivity by up to 18 (%) by increasing the flow rate of condensed water, discharging smoothly and promptly, discharging steam immediately after generation of condensed water, %, And maintenance cost can be reduced by up to 60%, while stabilizing the production process and extending the service life.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art.

100: steam trap 101: steam piping
103: condensate discharge pipe 110:
111: minute mechanism 113: foreign matter removing member
115: connecting port 116, 122, 1090, 2080: female thread portion
120: condensed water discharge unit 121, 2030:
123: Orifice Hall 124: Orifice seating jaw
125: pressure increasing portion 126: body portion
130: Orifice unit 1000: First orifice part
1010: protruding chin 1020: first decompression part
1030: first partition wall 1040: first movement path
1050: first filter hole 1060: first boosting portion
1070: first seating chin 1080: first insertion hole
1100: first body part 2000: second orifice part
2010: insertion portion 2020: inclined portion
2040: second insertion hole 2050: second partition wall
2060: second filter hole 2070: second boosting portion
2090: second body part 3000: second orifice part

Claims (7)

delete A main body 110 having one side connected to the steam pipe 101 and the internal side of the other side forming a female screw 116; A condensed water discharge unit 120 for connecting the main body 110 and the condensed water discharge pipe 103 so as to discharge the condensed water collected by the main body 110 by screwing with the internal threaded portion 116; And an orifice unit (130) coupled to the interior of the condensed water discharge unit (120) and having two or more multiple filter holes to restrict the discharge of steam and discharge condensed water, the orifice unit (130) A first orifice part 1000 formed at one end of the condensed water discharge unit 120 and having a hole 1050 formed at one end of the condensed water discharge unit 120 and a first insert part 1000 formed at the first orifice part 1000, And a second orifice part (2000) screwed into the hole and forming a second filter hole (2060), the steam trap having a plurality of orifices,
The first orifice part (1000)
A protrusion 1010 fixed to an end of one end of the condensed water discharge unit 120 and protruding at a diameter larger than the diameter of the first body 1100;
A first depressurizing portion 1020 formed at a central portion where the protruding protrusion 1010 is formed;
A first partition wall 1030 separating the first depressurization part 1020 and formed in the radial direction of the condensed water discharge unit 120;
The first partition wall 1030 is formed from one side of the first partition wall 1030 to a middle portion of the thickness of the first partition wall 1030 and is formed at a central position of the first partition wall 1030 in the direction of the first decompression part 1020 A first movement path 1040 formed in an enlarged triangular pyramid shape;
A first filter hole 1050 connected to the first movement path 1040 and extending to the other end of the first partition wall 1030 and having a uniform diameter;
A first boosting portion 1060 connected to the first filter hole 1050 and formed at a longitudinal intermediate position of the first orifice portion 1000;
A first seating surface 1070 formed on the cylindrical wall surface of the first thickening portion 1060;
A first insertion hole (1080) connected to the first mounting jaw (1070) and extended to the other side end of the condensed water discharge unit (120); And
A female screw portion 1090 formed continuously in a spiral shape on an inner circumferential surface of the first insertion hole; And a plurality of orifices formed in the steam trap.
3. The method of claim 2,
The second orifice portion 2000
A cylindrical insertion portion 2010 formed at one side of the second orifice portion 2000 and having a diameter smaller than the diameter of the second body portion 2090;
An inclined portion 2020 formed at an end portion of one side of the insertion portion 2010 so as to be inclined;
A male screw portion 2030 continuously formed in a spiral shape on the cylindrical surface of the insert 2010;
A second insertion hole 2040 formed at a central portion of the insertion portion 2010;
A second partition wall 2050 which separates the second insertion hole 2040 and is formed in the radial direction of the second orifice 2000;
A second filter hole 2060 having a uniform diameter at the center of the second partition wall 2050 and penetrating from one side of the second partition wall 2050 to the other side;
A second boosting portion 2070 connected to the second filter hole 2060 and extending to the other end of the second orifice portion 2000; And
A female screw portion 2080 continuously formed in a spiral shape on an inner circumferential surface of the second boosting portion 2070; And a plurality of orifices formed in the steam trap.
The method of claim 3,
Wherein a diameter of the first filter hole (1050) is larger than a diameter of the second filter hole (1050).
5. The method of claim 4,
The condensate discharge unit (120)
A male screw part 121 screwed to the female screw part 116 and formed on the outer peripheral surface of one side of the body part 126;
A female screw portion 122 continuously formed in a spiral shape on the inner circumferential surface of the other side of the condensed water discharge unit 120;
An orifice hole 123 formed in the center of the male thread 121 and inserted or inserted into the orifice unit 130;
An orifice seating jaw 124 which separates the orifice hole 123 and is formed in the center of the diameter of the condensed water discharge unit 120; And
A boosting portion 125 connected to the orifice seating jaw 124 and extended to the other end of the condensed water discharging unit 120; And a plurality of orifices.
6. The method of claim 5,
The female screw portion 1090 is screwed to the male screw portion 2030,
Wherein the orifice unit (130) is inserted and fixed in the orifice hole (123).
3. The method of claim 2,
The orifice unit 130 further includes a third orifice part 3000 having the same structure as the second orifice part 2000 and screwed to the rear end of the second orifice part 2000 A steam trap comprising a plurality of orifices.

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