KR20140031827A - Continuous injection type's steam condensate exhauster, in which engineering nozzle can be adopted - Google Patents

Abstract

The present invention relates to a continuous injection type condensate water discharger which significantly improves durability by continuously discharging condensate water through an engineering nozzle based on the two phase flow's law; and which improves the efficiency of thermal equipment by largely blocking steam and lowering the leakage rate of the steam. The continuous injection type condensate water discharger according to the present invention comprises one body (20) with an inlet (21) on one side and a joint hole (22) on the other side; and the other body (30) which is inserted into the joint hole (22) on the other side of one body (20), which has a through-hole (32) with the engineering nozzle (32) at the center of one side, and which has an outlet (31) on the other side. The engineering nozzle (10) is made of a multistage orifice which has three or more stages and of which the diameter gradually decreases; and has a flange (16) at the front, and a ring-shaped protrusion (17) at the front of the flange (16).

Description

Continuous injection type's steam condensate exhauster, in which engineering nozzle can be adopted

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a condensate discharger for discharging condensate generated from a thermal facility using steam as a heat source, and more particularly, to an engineering nozzle applying a two phase flow's law. The present invention relates to a continuous jet condensate discharger that discharges condensate continuously using a nozzle to greatly improve durability and at the same time block steam almost to reduce the leakage rate of live steam.

The condenser discharger is used for various heat facilities such as heat exchanger, heat radiator, steam header, steam tracing, main pipe drip, steam jacket heating, tank heating, various dryers, sterilizers, air conditioners, etc. do.

The steam continuously changes the gaseous steam into liquid condensed water from the moment it transfers heat to the thermal equipment, in contact with the hot steam and the surrounding low temperature objects. It is preferable to discharge the outside. If condensate is left inside the heat facility, water hammering occurs when the steam hits the condensate, causing problems such as corrosion of pipes and freezing of the winter with residual condensate, thereby reducing the efficiency of the heat facility. A problem arises.

In addition, when discharging condensate, steam should not be discharged as much as possible so as not to reduce the efficiency of the thermal installation.

As such, for good efficiency of the heat installation, it is desirable to discharge the condensate as soon as possible without causing steam to leak. Used for this purpose is a condenser discharger.

Conventional condensate dischargers use actuators such as ball float type, disc type, bucket type, bimetallic type, etc. By installing enough general purpose nozzles and repeating the opening and closing of these actuators, a certain amount of condensate accumulates inside and is discharged to the outside.

Such a conventional condensate ejector has a problem that the operating device must be operated repeatedly, so that wear occurs for a long period of time, resulting in short lifespan.In addition, condensate is intermittently discharged, resulting in condensate such as water hammering and leaking with the condensate. There was also a problem that the loss of steam is high because the amount of steam is also large.

In order to solve this problem, the present inventors have developed a condensate discharger for continuously discharging condensed water and registered it as Utility Model Registration No. 0118406. This condensate discharger has a long life because there is no operating device, but there is a problem that the long-term use of the high pressure does not deform the nozzle and the leakage rate of steam does not significantly lower.

The present invention has been made in view of the problems of the prior art as described above, to provide a condenser discharger that improves the efficiency of thermal facilities by reducing the steam leak rate and at the same time to increase the durability to prevent failure even after long-term use The purpose is to.

In order to achieve the above object, the continuous injection type condensate ejector of the present invention is formed on one side of the inlet is formed in one side, the space is formed inside and the coupling hole on the other side, the coupling formed on the other side of the one body In the continuous injection condenser discharger including the other body is inserted into the ball and the engineering hole is installed in the center of one side and the outlet is formed on the other side, the fluid flow and A vortex promotion hexagon rod installed in a right angle direction and an on / off valve installed on one side of a portion corresponding to the space between the vortex promotion hexagon rod and the engineering nozzle and formed with a foreign matter accumulation groove; The engineering nozzle is formed of three or more multistage orifices whose diameter decreases toward the center, and the rear orifice behind the smallest central orifice has a larger diameter than the central orifice, and has a flange formed at the front thereof. An annular protrusion is formed in front of the flange.

The continuous jet condensate ejector of the present invention does not constitute any operation device for discharging condensate and is provided with a protection means of the nozzle so that no wear or failure occurs and thus durability can be increased for a long time, and condensate is generated. As it is continuously discharged, water hammering, air binding, steam locking, etc. do not occur, and the engineering nozzle, nozzle protection guide, nozzle protection capsule, or vortex installed in front of it It is possible to reduce the steam leak rate by the acceleration hexagon bar, which greatly improves the efficiency of the thermal installation.

1 is a cross-sectional view of an engineering nozzle applied to the continuous jet condensate ejector according to the present invention,
2 is a cross-sectional view of a continuous jet condensate discharger of one embodiment according to the present invention;
3 is a cross-sectional view of a continuous jet condensate discharger of another embodiment according to the present invention;
Figures 4a and 4b is a cross-sectional view of a continuous jet condensate discharger of another embodiment according to the present invention,
5 is a graph showing the actual steam loss rate according to the condensate load variation of the engineering nozzle of the condensate ejector according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The present invention utilizes an engineering nozzle 10 applying the two phase flow's law as shown in FIG.

The law of two-phase fluid flow refers to the flow of steam in a liquid state because the condensate in the liquid phase has a large difference in volume and velocity when steam and condensate passes through a certain nozzle with the same cross-sectional area. It affects the steam to the outside through the nozzle as much as possible to prevent the loss of steam and purely condensate can be discharged continuously.

More specifically, the volume ratio of steam to water is 1600: 1 at atmospheric pressure. Steam and water (condensed water) flow as volumes. When applying the concept of volume, steam and water show a large difference in volume due to the characteristics of the fluid. For example, water is 1 liter at 1 Kg at atmospheric pressure and 1.63 m ³ at 1 Kg at atmospheric pressure. As the pressure increases, the volume ratio decreases but on average differs by as much as 800: 1. Therefore, steam is much lighter than water at the same volume, and when it passes through nozzles having the same cross-sectional area, it means that the amount of steam passing through is smaller than the amount of water passing by weight.

And the speed of steam and water flowing in a specific nozzle is about 10: 1 at 2-3 kg / cm ² . In other words, there is a difference in nozzle passage speed when steam and water pass through a specific nozzle. Due to this characteristic, when steam (live steam) and water (condensed water) are present at the same time, even if the space occupied by the condensate is small, it is a factor that suppresses the excessive leakage of the accompanying leaking steam such as condensed water. In other words, the fast leaking steam is prevented by the slow leaking water.

The inventor designed the engineering nozzle by applying two principles applied when steam and water flow inside the nozzle as described above.

In addition, the actual steam (live steam) loss rate according to the load variation of the condensate is shown in the graph in FIG. As shown in the figure, when the load ratio of condensate in a steam heat facility is 25%, the leakage of live steam leaked to a specific nozzle is 0.425% of the maximum discharge amount of condensate. If condensate is not discharged from a particular nozzle, the condensate load rate is 0% (ie no condensate), and the amount of live steam leaked is 3.4% of the maximum in terms of weight. Therefore, when the amount of condensate discharged to the specific nozzle is designed, the diameter of the specific nozzle can be determined at the point where the live steam can be suppressed to the maximum.

In general, engineering nozzles are designed in consideration of steam pressure and back pressure of the thermal facility, steam temperature and steam consumption (condensate generation), transport height of condensate, transport distance, and safety factor considering load variation of condensate.

As shown in FIG. 1, the engineering nozzle 10 of the present invention is configured in a multistage orifice type in which the diameter is reduced to three stages and then the diameter thereof is increased again as it goes to the center portion. The reason for the multi-stage orifice is to increase the speed of the fluid during the orifice and to create a vortex at the step so that the fast-leaking steam collides with the slow-leaking condensate and is restricted in movement. This is to slow down the speed of condensate passing.

As shown in Figure 2 to 4b, the condensate discharger of the present invention is formed on one side of the inlet 21, the space is formed inside and the coupling body 22 is formed on the other side one side 20 And a through hole 32 inserted into the coupling hole 22 formed at the other side of the one main body 20 and having an engineering nozzle 10 installed at the center of one side, and an outlet 31 formed at the other side. The other main body 30 is provided.

In the figure, one side body 20 and the other side body 30 is shown as being coupled to each other by a screw coupling method, it can be combined in other coupling methods such as welding, flange coupling. End portions of the one side body 20 and the other side body 30 were formed in each of the hexagonal portions (23, 33) to facilitate screwing. The inlet 21 and the outlet 31 are formed to be installed in a thermal facility (not shown) by forming a female screw, but may also employ other coupling methods such as flange coupling.

Continuous injection type condenser discharger of an embodiment of the present invention is suitably used when the fluid is a high pressure, as shown in Figure 2, installed in front of the engineering nozzle 10 to protect the nozzle and the front The nozzle protection guide 40 having a plurality of condensate passages 41a formed at the edge of the wall 41 and the inner side of the condensate passage 41a of the nozzle protection guide 40 are installed in front of the front and rear surfaces thereof. The filter net 50 is formed in an open cylindrical shape.

In addition, the engineering nozzle 10 is formed of three or more multistage orifices whose diameter decreases toward the center, and the rear orifice of the rear of the central orifice 11 having the smallest diameter is larger in diameter than the central orifice 11. It is. As shown in FIGS. 1 and 2, the front end of the smallest central orifice 11 has the largest diameter of the first stage front orifice 12, and the middle of the central orifice 11 and the first stage front orifice 12. The two-stage front orifice 13 of diameter is formed. At the rear of the central orifice 11, a first stage rear orifice 14 having a diameter larger than the diameter of the central orifice 11 and a two stage rear orifice 15 having a larger diameter than the first stage rear orifice 14 are formed. .

Moreover, the flange 16 is formed in front of the engineering nozzle 10 so that it may be installed stably only by fitting the engineering nozzle 10 to the through-hole 32 of the other main body 30. As shown in FIG.

The engineering nozzle 10 is provided with a model number for each diameter of the orifice according to the processing capacity and after setting dozens of models to make a separate heat facility capacity selection table to easily adopt the engineering nozzle. In this case, the other parts of the condensate discharger may be used as it is and only the engineering nozzle 10 may be replaced.

The continuous jet condenser discharger according to another embodiment of the present invention is suitably used when the fluid is low pressure, and as shown in FIG. 3, it is installed in front of the engineering nozzle 10 to protect the nozzle. In order to form a space between the side wall 62 and the inner wall of the one side body 20, a plurality of condensate passages 62a are formed on the side wall 62, the nozzle protection is screwed to the other body 30 It is provided on the capsule 60, the filtering net 51 provided on the front surface of the engineering nozzle 10, and one side body 20 of the portion corresponding to the side wall 62 of the nozzle protection capsule 60, The on-off valve 70 in which the foreign matter accumulation groove 71 is formed is provided.

The on-off valve 70 is installed to discharge the foreign matter when accumulated in the foreign matter accumulation groove 71 by a long time use.

The filter net 51 is installed in a plane form when the nozzle protection capsule 60 is screwed with the other body 30 is sandwiched therebetween.

The engineering nozzle 10 of this embodiment uses the nozzle of the above-described embodiment as it is, and is formed of three or more multi-stage orifices whose diameter decreases toward the center, and the rear of the central orifice 11 having the smallest diameter. The rear orifice has a larger diameter than the central orifice 11, and the flange 16 is formed in the front.

A continuous jet condenser ejector of another embodiment of the present invention is suitably used for low pressure thermal equipment such as tracing, instrumentation, drip, and the like, as shown in FIGS. 4A and 4B, from the front of the engineering nozzle 10. Corresponds to the space between the vortex accelerator hexagon rods 80 and 80 'installed at right angles to the flow of the fluid at a predetermined distance away from the vortex accelerator rod and the engineering nozzle 10. It is provided on one side of the main body 20 to the opening and closing valve 70 is provided with a foreign matter accumulation groove (71).

The vortex promotion hexagon bars 80 and 80 ′ are installed through the main body 20 in a direction perpendicular to the fluid flow direction, and a hexagonal portion 81 having a hexagonal cross section is formed at the tip end thereof.

Vortex promoting hexagonal rods 80 and 80 'cause vortices to form at the rear, i.e., in front of the engineering nozzle 10, to impede the flow of steam by impinging the condensate, and at the same time, foreign matter contained in the fluid. This contact serves to separate.

Since the tip portions of the vortex promotion hexagon bars 80 and 80 'are formed by the hexagonal portion 81, the flow of the fluid is smooth and the vortex is also well formed.

The vortex promoting hexagonal rod 80 of FIG. 4A has a structure welded from one side of the main body 20 through one side body 20, and the vortex promoting hexagonal rod 80 'of FIG. 4B has one side body 20. It is structured to weld inside. The vortex promotion hexagon bar 80 of FIG. 4a is easy to weld and hassle has to be surface treated after welding, and is not good in appearance. The vortex promotion hexagon bar 80 'of FIG. 4b is difficult to weld but the surface after welding. The advantage is that it does not need to be treated and does not affect aesthetically.

 The engineering nozzle 10 of this embodiment is formed of three or more multistage orifices whose diameter decreases toward the center, and the rear orifice of the rear of the central orifice 11 having the smallest diameter is larger than the central orifice 11. It is largely formed, and the flange 16 is formed in front, and the annular protrusion 17 is formed in front of the flange 16. As shown in FIG. The protrusion 17 serves to shield foreign matter from entering the orifice of the engineering nozzle 10.

The components constituting the condensate discharger of the present invention are used for a long time by using a material having a high corrosion resistance such as stainless steel.

The continuous jet condenser discharger of the present invention configured as described above functions as follows.

Referring first to the embodiment of Figure 2, in the heat facility using steam as a heat source condensed water is generated continuously so that steam and condensed water enters the inside of one body 20 through the inlet 21 of one body 20. Since the fluid is high pressure and the flow rate of steam is very fast, the steam collides with the front wall 41 of the nozzle protection guide 40, forming a vortex, which causes the steam to collide with the condensate, which delays the flow and pushes the condensate to the edge. Serve The condensate flows to the edge and passes through the cylindrical filtration network 50 to remove foreign matter, and passes through the condensate passage 41a formed at the edge of the front wall 41 of the nozzle protection guide 40. Therefore, most of the condensed water enters the inside of the nozzle protection guide 40, and most of the steam is blocked so that only a part of the nozzle protection guide 40 is introduced. In addition, since the pressure inside the nozzle protection guide 40 is low, the engineering nozzle 10 is protected.

The condensate and steam then pass through the orifice of the engineering nozzle 10, passing through the 1st front orifice 12, the 2nd front orifice 13 and the central orifice 11, whereby the flow velocity is gradually increased and vortices are generated at the step. The condensate impacts the condensate, which inhibits the flow of steam and causes condensate to flow. Subsequently, the fluid flows through the first stage rear orifice 14 and the second stage rear orifice 15 and the outlet 31 so that the flow rate is lowered, so that the steam is further restricted by the condensate and thus continuously discharges the condensate. Significantly reduce the steam leak rate.

In another embodiment of the present invention shown in FIG. 3, the fluid enters the inside of the main body 20, and a high velocity steam impinges on the front wall 61 of the nozzle protection capsule 60, causing a vortex while repulsing. In the meantime, the condensed water flows to the edge of one side body 20 and enters the nozzle protective capsule 60 through the condensate passage 62a formed on the side wall 62 of the nozzle protective capsule 60. Therefore, most of the condensate enters the inside of the nozzle protection capsule 60, and most of the steam is blocked so that only a part of the nozzle protection capsule 60 is introduced. In addition, since the pressure inside the nozzle protection capsule 60 is low, the engineering nozzle 10 is protected. The condensate is ejected by being discharged to the outside through the orifice of the engineering nozzle 10 after the foreign matter contained therein is filtered by the filter net 51 is the same as the case of the embodiment of FIG.

As the condensate flows around the side wall 62 of the nozzle protection capsule 60, foreign matter contacts the side wall, separates from the condensate, gathers down, and accumulates in the foreign matter accumulation groove 71. If it is used for a long time, the on-off valve 70 is opened and discharged to the outside.

In another embodiment of the present invention shown in Figures 4a and 4b, the fluid enters the inside of the main body 20, the steam flows fast flowing around the hexagonal portion 81 of the vortex promotion hexagon bar 80, the rear Vortex flows in and consequently the steam impinges on the condensate, causing the condensate to enter the orifice of the engineering nozzle 10 with a delay in the flow of steam. An annular protrusion 17 is formed at the front edge of the engineering nozzle 10 to prevent foreign matter from entering the orifice of the engineering nozzle 10. Condensate is injected to the outside through the orifice of the engineering nozzle 10 is discharged is the same as the case of the embodiment of FIG.

The condensate is separated from the fluid while in contact with the vortex accelerator hexagon rod 80 to be collected below and accumulated in the foreign matter accumulation groove 71. If it is used for a long time, the on-off valve 70 is opened and discharged to the outside.

Since the continuous injection type condensate ejector of the present invention is not configured with any operation device for discharging condensate, no wear or failure occurs, and the engineering nozzle 10 is also protected against pressure by a protection means, thereby increasing durability. It can be used for a long time.

In addition, the condensate discharge unit of the present invention is discharged continuously as condensate is generated, so that water hammering, air blockage, and steam blockage do not occur, thereby improving the efficiency of the thermal facility.

In addition, since the flow of steam is delayed by the engineering nozzle 10 having the multi-stage orifice, the nozzle protection guide 40, the nozzle protection capsule 60, or the vortex promotion hexagon rod 80 installed in front of the steam leakage rate, As a result, the efficiency of the thermal installation is improved.

In addition, the flange 16 is formed in front of the engineering nozzle 10, and the engineering nozzle 10 is installed stably just by inserting the engineering nozzle 10 into the through hole 32 of the other main body 30. The engineering nozzle 10 can be used in the condenser discharger by making dozens of models having different diameters of orifices according to the processing capacity of the thermal equipment, and adopting an appropriate one of them.

It will be understood by those skilled 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. Of the total.

10: engineering nozzle 11: central orifice
12: 1st front orifice 13: 2nd front orifice
14: 1st stage rear orifice 15: 2nd stage rear orifice
16: flange 17: protrusion
20: one side body 21: inlet
22: coupling hole 23: hexagon
30: other body 31: outlet
32: through hole 33: hexagon
40: nozzle protection guide 41: front wall
41a: condensate passage
50: cylindrical filter net 51: filter net
60: nozzle protection capsule 61: front wall
62: side wall 62a: condensate passage
70: on-off valve 71: foreign matter accumulation groove
80, 80 ': Vortex accelerator hexagon rod 81: hexagon

Claims (1)

Inlet port 21 is formed on one side, the space is formed inside and the coupling body 22 formed on the other side of the main body 20, the coupling hole 22 is formed on the other side 22 In the continuous injection type condenser discharger including the other main body 30 is inserted into the) and the through-hole 32 is formed in the center of one side is installed, the outlet 31 is formed on the other side,
Vortex accelerator hexagon rods 80, 80 'installed at right angles to the flow of fluid at a position away from the engineering nozzle 10 forwardly,
The on-off valve 70 is installed on one side body 20 of the portion corresponding to the space between the vortex promotion hexagon rods 80, 80 'and the engineering nozzle 10, the foreign matter accumulation groove 71 is formed Equipped;
The engineering nozzle 10 is formed of three or more multistage orifices whose diameter decreases toward the center, and the rear orifice of the rear of the central orifice 11 having the smallest diameter is larger in diameter than the central orifice 11. And a flange (16) formed at the front side, and an annular protrusion (17) formed at the front side of the flange (16).

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