KR102491317B1 - Multi-way orifice steam trap - Google Patents

Abstract

The present invention relates to a multi-way orifice steam trap, and more specifically, to a multi-way orifice steam trap installed in devices that use steam and is designed to discharge generated condensate reliably even when excessive condensate is generated, and to minimize the discharge of steam when discharging the condensate. To this end, the multi-way orifice steam trap comprises a body having a chamber formed therein, an inlet pipe for supplying condensate to the body, an outlet pipe for discharging the condensate from the body, and an orifice member installed in the chamber to separate the condensate from the steam to forward to the outlet pipe, wherein the orifice member is composed of a main orifice member that operates at all times and an auxiliary orifice member that operates when more than a set amount of condensate is generated.

Description

Multi-way orifice steam trap {Multi-way orifice steam trap}

The present invention relates to a multi-way orifice steam trap, and more particularly, to discharge condensate generated by being installed in a device that uses steam, but can stably discharge it even if excessive condensate is generated, as well as to discharge steam when condensate is discharged. It relates to a multi-way orifice steam trap that can minimize emissions.

Pipes that transport steam (steam) in production facilities, heat exchangers, and steam piping facilities that use steam (steam) have a large temperature difference between the inside and outside of the transfer pipe due to high-temperature and high-pressure steam. It is very common that condensed water or condensed water is generated in the transfer pipe due to the temperature difference.

As this condensate moves or is transported together with steam along the steam movement path, it strikes the steam transport pipe, causing a water hammer that causes danger in the steam transport pipe and also causes a decrease in thermal efficiency, so it is quickly removed. In order to remove the condensate, a steam trap can be installed by installing a separate pipe to discharge the condensate at the bottom of the steam transfer pipe.

The steam trap automatically discharges the condensed water in the steam transfer pipe to the outside of the steam transfer pipe, and various types of technologies such as ball float type, disk type, bimetal type, bucket type, and orifice type are introduced and used.

Among these steam traps, the orifice method minimizes steam leakage, does not require an operating configuration, has a small heating area, and improves heat transfer to the heating body by seeking an increase in efficiency by continuously discharging condensate. It has great economic benefits.

However, the orifice-type steam trap of the prior art as described above has a fixed diameter of the orifice, so when a certain amount or more of condensed water is generated, the condensed water cannot be discharged. Therefore, there are problems such as occurrence of water hammer causing the above-mentioned risk and deterioration of thermal efficiency.

In order to solve this problem, a technology described in Korean Patent Registration No. 10-2200203 as shown in FIGS. 1 and 2 has been proposed, and its technical features include an inlet pipe 10 for allowing condensate to flow in; A pressure gauge 12 provided on one side of the inlet pipe 10; an inlet chamber 20 communicating with the inlet pipe 10; a filter net 30 installed in the center of the inlet chamber 20 to remove foreign substances; a foreign matter outlet 40 formed in the lower portion of the inflow chamber 20 and discharging foreign matter; An intermediate chamber 60 formed on the top of the filter net 30 and opened in the opposite direction of the filter net 30; a discharge pipe 80 communicating with the inlet chamber 20 through the intermediate chamber 60 and discharging condensed water; an adjuster assembly (50) disposed in the intermediate chamber (60) and having a plurality of orthogonal tunnels; It is characterized in that it includes; a temperature sensor 84 provided on one side of the discharge pipe 80.

By the way, the technology described in Korean Patent Registration No. 10-2200203 has the advantage of controlling the condensate discharged according to the situation by adjusting the orifice, but the temperature sensor is used to determine whether the condensate is normally discharged or the condensate remains abnormally. After measuring and determining the temperature with (84), there is a problem that it is not easy to adjust the orifice.

Korean Registered Patent No. 10-2200203 (registered on January 4, 2021)

The present invention has been made to solve the above problems, and an object of the present invention is a main orifice member that always operates inside a chamber constituting a steam trap for discharging condensate, and when condensate is generated more than a set amount. Provide one or more auxiliary orifice members that operate, but have an opening and closing device in the auxiliary orifice member so that condensate is discharged through the main orifice in a normal state, and when excessive condensate occurs, the auxiliary orifice member operates through the opening and closing device It is to provide a multi-way orifice steam trap that can stably discharge condensate even in special circumstances.

And, another object of the present invention is to ensure that the position of the orifice member installed inside the chamber is the same as or below the lower position of the inlet pipe through which the condensate flows, so that the condensate accumulated in the lower part of the chamber blocks the inlet of the orifice member. To provide a multi-way orifice steam trap that can prevent steam from leaking to the outside.

The present invention to solve these problems;

A body in which a chamber is formed, an inlet pipe for supplying condensed water containing steam to the body, a discharge pipe for discharging condensate from the body, and a discharge pipe installed in the chamber to separate the condensate from steam and discharge it to the discharge pipe. It is characterized in that it consists of an orifice member.

Here, the orifice member is characterized in that it consists of a main orifice member that operates at all times and one or more auxiliary orifice members that operate when condensed water is generated more than a set amount.

In addition, an installation member to which the orifice member is detachable is formed inside the chamber to communicate with the discharge pipe.

At this time, the installation member is further provided with an opening and closing device for controlling the operation of the auxiliary orifice member. It is characterized in that it consists of an opening and closing stopper for opening and closing the inlet of the auxiliary orifice member, and a floating body installed on the other side of the operating lever and moving upward by condensed water.

Here, the orifice member is characterized in that located at the same as or below the lower part of the inlet pipe.

On the other hand, a partition wall separating the upper space and the lower space is formed inside the chamber, a flow path communicating the upper space and the lower space is formed in the partition wall, and a filter net is installed in the flow path. .

At this time, a connection pipe installed along an outer surface of the chamber and connected to the lower space is formed at an end of the inlet pipe.

In addition, a gas flow pipe is formed inside the chamber in a vertical direction, and a lower end of the gas flow pipe is formed to communicate with the main orifice member.

In addition, a plurality of auxiliary orifice members are installed, and each of the auxiliary orifice members operates at different levels of condensate water.

According to the present invention having the above configuration, a main orifice member that always operates inside the chamber constituting a steam trap for discharging condensate and one or more auxiliary orifice members that operate when more than a set amount of condensate is generated, but, By providing an opening and closing device to the auxiliary orifice member, condensate is discharged through the main orifice in normal conditions, and when excessive condensate occurs, the auxiliary orifice member is operated through the opening and closing device to stably discharge condensate even in special situations. It works.

In addition, the present invention makes the position of the orifice member installed inside the chamber equal to or below the lower position of the inlet pipe through which the condensed water flows, so that the condensed water accumulated in the lower part of the chamber blocks the inlet of the orifice member to prevent steam This has the effect of preventing leakage to the outside.

1 is a schematic cross-sectional view of a conventional steam trap.
2 is a cross-sectional view of a main part in which an orifice part of a conventional steam trap is disassembled.
3 is a conceptual diagram of a multi-way orifice steam trap according to the present invention.
Figure 4 is a cross-sectional view of the installation member of the multi-way orifice steam trap according to the present invention.
5 is a conceptual diagram of a state in which an orifice is installed in an installation member of a multi-way orifice steam trap according to the present invention.
Figure 6 is a longitudinal cross-sectional view of a state in which the opening and closing device is installed in the auxiliary orifice member of the multi-way orifice steam trap according to the present invention.
7 is a conceptual diagram in which a gas flow pipe is formed inside a body according to another embodiment of the present invention.
8 is a planar cross-sectional view of an installation member according to the embodiment of FIG. 7 .
9 is a cross-sectional view of an installation member of a multi-way orifice steam trap according to another embodiment of the present invention.
10 is a conceptual diagram of a multi-way orifice steam trap according to another embodiment of the present invention.
11 is an external view of a multi-way orifice steam trap according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. The same reference numerals are used for the same components in the drawings, and redundant descriptions of the same components are omitted. And, it should be understood that the present invention may be embodied in many different forms and is not limited to the described embodiments.

Figure 3 is a conceptual diagram of a multi-way orifice steam trap according to the present invention, Figure 4 is a cross-sectional view of the installation member of the multi-way orifice steam trap according to the present invention, Figure 5 is the installation member of the multi-way orifice steam trap according to the present invention 6 is a longitudinal cross-sectional view of a state in which an opening and closing device is installed in an auxiliary orifice member of a multi-way orifice steam trap according to the present invention, and FIG. 7 is an inner side of a body according to another embodiment of the present invention. A conceptual diagram in which a gas flow pipe is formed, Figure 8 is a plan view of the installation member according to the embodiment of Figure 7, Figure 9 is a cross-sectional view of the installation member of the multi-way orifice steam trap according to another embodiment of the present invention, 10 is a conceptual diagram of a multi-way orifice steam trap according to another embodiment of the present invention, and FIG. 11 is an external view of a multi-way orifice steam trap according to the present invention.

The present invention relates to a multi-way orifice steam trap, and as shown in Figs. It may include an inlet pipe 340 for supplying, a discharge pipe 350 for discharging condensed water from the body 300, and an orifice member 400 installed inside the chamber 310 to separate condensed water from steam.

Here, the orifice member 400 is installed to communicate with the discharge pipe 350 so that the condensed water filtered through the orifice member 400 is discharged through the discharge pipe 350, thereby minimizing the discharge of steam.

At this time, the orifice member 400 may be composed of a main orifice member 410 installed to operate all the time and an auxiliary orifice member 420 that operates only in special situations.

The auxiliary orifice member 420 operates when the amount of condensed water generated is higher than the usual amount of water.

The length of the auxiliary orifice member 420 may be shorter than that of the main orifice member 410 in order to secure an installation space for the opening/closing device 500 including the floating body 520 to be described later.

So, even if excessive condensate is generated, condensate is stably discharged, so that devices such as production facilities, heat exchangers, and steam piping facilities using steam (steam) in which the steam trap of the present invention is installed can be stably and error-free. make it work

In addition, an installation member 370 is formed inside the chamber 310, and the main orifice member 410 and the secondary orifice member 420 constituting the orifice member 400 are formed in the installation member 370. It can be combined to be detachable.

Here, an installation space 372 may be formed inside the installation member 370 so that the main orifice member 410 and the auxiliary orifice member 420 can be attached or detached. At the front end of the installation space 372, A through hole 374 may be formed to allow condensed water introduced into the chamber 310 to flow in, and a rear side of the installation space 372 may be formed to communicate with the outside of the body 300 .

At this time, the installation stopper 376 is detachable from the rear of the installation space 372 to firmly fix the orifice member 400 provided therein. Although not shown in the drawing, the rear of the installation space 372 A passage communicating with the outlet 350 may be formed, and condensed water passing through the orifice member 400 moves to the outlet 350 through the passage.

On the other hand, the auxiliary orifice member 420 constituting the orifice member 400 is operated only when excessive condensate occurs, and the opening and closing device 500 for controlling the operation of the auxiliary orifice member 420 is It may be provided on the installation member 370.

Here, as shown in FIG. 6 , the opening/closing device 500 includes an operating lever 510 rotatably installed above the installation member 370 and an opening/closing stopper installed on one side of the operating lever 510. 530 and a floating body 520 installed on the other side of the operating lever 510. The floating body 520 may be formed in a spherical shape or in various shapes including a semicircle. .

At this time, the opening and closing stopper 530 is installed to open and close the through hole 374 of the installation space 372 located at the entrance of the auxiliary orifice member 420, and the floating body 520 is installed to open and close the chamber 310 It can move upward by the condensed water accommodated in the inside.

So, when the amount of condensed water supplied into the chamber 310 is greater than the set amount, the floating body 520 moves upward, and accordingly, the operating lever 510 moves upward to open and close the stopper ( 530 is separated from the through hole 374 so that condensed water flows into the auxiliary orifice member 420 .

Therefore, when the amount of condensed water generated is within the set range, the floating body 520 does not move upward, so only the main orifice member 410 operates, but when the amount of condensed water generated exceeds the set range, the floating body ( 520 moves upward to actuate the auxiliary orifice member 420.

In addition, the orifice member 400 installed inside the chamber 310 is installed at the same height as the lower part of the inlet pipe 340 supplying steam containing condensed water, or the lower part of the inlet pipe 340. It can be installed so as to be positioned below.

Here, the height of the orifice member 400 is equal to or lower than the lower part of the inlet pipe 340 so that the height of the condensed water introduced into the chamber 310 is the same as that of the orifice member 400. When the condensate is discharged to the discharge pipe 350 through the main orifice member 410, it is possible to prevent condensed water from flowing backward through the inlet pipe 340.

Of course, even when excessive condensate is generated, the auxiliary orifice member 420 operates, thereby stably preventing the reverse flow of condensate, and production equipment using steam (steam) in which the steam trap of the present invention is installed, Devices such as heat exchangers and steam piping facilities operate stably without errors.

In addition, a partition wall 360 separating the upper space 320 and the lower space 330 is formed inside the chamber 310 formed in the body 300, and the partition wall 360 has the upper space 320 ) and the lower space 330, a flow path 362 may be formed, and a pressure gauge for sensing an internal pressure may be further provided at an upper part of the upper space 320.

Here, as shown in FIG. 3, the inlet pipe 340 remains disconnected from the upper space 320, and although not shown in the figure, the end of the inlet pipe 340 and the lower space ( 330) may be formed in a spiral shape outside the chamber 310.

At this time, a filtering net 364 for filtering out foreign substances such as scale included in the condensed water may be further installed in the flow path 362, and the lower part of the lower space 330 is filtered by the flow path 362. A foreign substance outlet 332 for discharging foreign substances may be further formed, and an openable cover may be further provided in the foreign substance outlet 332 .

So, the condensed water introduced through the inlet pipe 340 is supplied to the lower space 330 through the connection pipe (not shown), and the condensed water supplied in this way is filtered out of foreign substances by the filter net 364, By moving to the upper space 320, it can be stably discharged to the outside through the orifice member 400.

Meanwhile, as shown in FIGS. 7 and 8 as another embodiment of the present invention, a gas flow pipe 324 may be further formed inside the chamber 310 formed in the body 300 in a vertical direction.

Here, the upper end of the gas flow pipe 324 may be formed to communicate with the upper part of the upper space 320, and the lower end of the gas flow pipe 324 is an installation space formed inside the installation member 370 ( 372) may be formed to communicate with.

At this time, the installation space 372 in which the lower end of the gas flow pipe 324 communicates communicates with the installation space 372 in which the main orifice member 410 is installed, so that the amount of condensate flowing into the chamber 310 When the gas accommodated in the upper space 320 is pressurized, it can be discharged to the outside through the gas flow pipe 324 and the main orifice member 410, so that condensate can stably flow into the chamber 310. there is.

Of course, when the internal pressure of the upper space 320 is lowered as the condensed water is discharged through the orifice member 400, the condensed water flows backward through the gas flow pipe 324 to adjust the pressure.

And, although not shown in the drawings, a stay space 378 in which the gas introduced through the gas flow pipe 324 can stay is further formed in the entire installation space 372 where the orifice member 400 is installed. can do.

Here, the ceiling of the staying space 378 may be formed to be located above the orifice member 400, and the lower end of the gas flow pipe 324 may be formed to communicate with the lower part of the staying space 378. there is.

Thus, the gas introduced into the staying space 378 through the gas flow pipe 324 is discharged to the outside together with the condensed water through the main orifice member 410 .

In addition, as described above, the main orifice member 410 and the secondary orifice member 420 constituting the orifice member 400 may be installed at the same height, but as shown in FIG. 9, the main orifice member 410 The installation space 372 in which the and auxiliary orifice members 420 are installed may be formed in different directions and at different heights.

Thus, by forming the main orifice member 410 and the auxiliary orifice member 420 at different heights, the height of the condensed water for opening and closing the auxiliary orifice member 420 can be set.

In addition, as another embodiment of the present invention, as shown in FIG. 10, the orifice member 400 is composed of a main orifice member 410 that always operates and a secondary orifice member that operates when condensate is generated more than a set amount. 420, the auxiliary orifice member 420 may be installed in plurality.

Here, each of the plurality of auxiliary orifice members 420 is provided with an opening/closing device 500, and the level of the condensed water floating upward in the floating body 520 constituting each opening/closing device 500 may be set differently. there is.

So, depending on the amount of condensed water generated, only one auxiliary orifice member 420 may operate, and additionally one or a plurality of auxiliary orifice members 420 may operate, so that the condensed water can be discharged more stably. .

Although preferred embodiments of the present invention have been described above, the scope of the present invention is not limited thereto, and the spirit of the present invention extends to those within the scope substantially equivalent to the embodiments of the present invention. Various modifications and implementations are possible by those skilled in the art to which the present invention pertains within the scope that does not deviate from the above.

The present invention relates to a multi-way orifice steam trap, and more particularly, to discharge condensate generated by being installed in a device that uses steam, but can stably discharge it even if excessive condensate is generated, as well as to discharge steam when condensate is discharged. It relates to a multi-way orifice steam trap that can minimize emissions.

300: body 310: chamber
320: upper space 330: lower space
340: inlet pipe 350: discharge pipe
360: bulkhead 370: installation member
400: orifice member 410: main orifice member
420: auxiliary orifice member 500: opening and closing device
510: operating lever 520: floating body
530: opening and closing stopper

Claims (9)

A body in which a chamber is formed, an inlet pipe for supplying condensed water containing steam to the body, a discharge pipe for discharging condensate from the body, and a discharge pipe installed in the chamber to separate the condensate from steam and discharge it to the discharge pipe. It consists of an orifice member,
The orifice member is composed of a main orifice member that always operates and one or more auxiliary orifice members that operate when more condensate is generated than a set amount,
A multi-way orifice steam trap, characterized in that a gas flow pipe is formed inside the chamber in a vertical direction, and the lower end of the gas flow pipe is formed to communicate with the main orifice member.
delete According to claim 1,
A multi-way orifice steam trap, characterized in that the installation member to which the orifice member is detachable is formed inside the chamber to communicate with the discharge pipe.
According to claim 3,
Multi-way orifice steam trap, characterized in that the installation member is further provided with an opening and closing device for controlling the operation of the auxiliary orifice member.
According to claim 4,
The opening and closing device includes an operating lever rotatably installed on the upper portion of the installation member;
An opening and closing stopper installed on one side of the operation lever to open and close the inlet of the auxiliary orifice member;
A multi-way orifice steam trap, characterized in that consisting of a floating body installed on the other side of the operating lever and moving upward by condensate.
According to claim 1,
The orifice member is a multi-way orifice steam trap, characterized in that located at the same as or below the lower part of the inlet pipe.
According to claim 1,
A partition wall separating an upper space and a lower space is formed inside the chamber,
A flow passage communicating the upper space and the lower space is formed in the partition wall,
A filtering net is installed in the flow passage,
Multi-way orifice steam trap, characterized in that the end of the inlet pipe is installed along the outer surface of the chamber is formed a connection pipe connected to the lower space.
delete According to claim 4,
A plurality of auxiliary orifice members are installed,
Multi-way orifice steam trap, characterized in that each of the auxiliary orifice member operates at a different level of condensate water.

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