KR101054216B1 - Steam trap - Google Patents

Abstract

PURPOSE: A steam trap apparatus is provided to extend the service life of a pipe system by completely preventing steam from being exhausted. CONSTITUTION: A steam trap apparatus comprises a housing(100), an inlet pipe(200), an outlet pipe(300), a water level sensor, and an opening and closing valve(500). The housing has a condensate storage space. The inlet pipe is coupled to the housing to flow condensate into the housing. The outlet pipe is coupled to the housing to discharge the stored condensate. The water level sensor generates an electric signal depending on the level of the stored condensate. The opening and closing valve opens and closes the outlet pipe depending on the generated electric signal.

Description

Steam trap device {Steam Trap}

The present invention relates to a steam trap device. More specifically, by introducing condensate generated from the steam installation and sensing the level of the condensate to operate a separate on-off valve mounted on the discharge pipe according to the condensate level, it is possible to completely prevent the discharge of steam to discharge only the condensate, This prevents energy loss, improves energy efficiency, extends the service life of the piping system, and divides the space inside the housing where the condensate flows into the inlet and outlet chambers through a separator plate for more accurate and stable condensate. The present invention relates to a steam trap device capable of detecting a water level and improving durability by preventing damage to various components.

In general, the steam trap device is installed in a steam line, that is, a steam line such as a heating radiator or a process heat exchanger, and separates steam and condensate by engineering principle and internal structure to automatically open or control a valve to discharge only condensate. Is a kind of automatic valve.

In other words, the steam line of the steam plant is supplied with a high-temperature steam flows to provide heat in the process of condensation through heat exchange with the outside, at this time, to efficiently remove the condensate generated from the steam plant and prevent the leakage of steam A steam trap device is used as the device.

When a steam leak occurs in such a steam trap device, latent heat of steam is not used and is released, thereby causing energy loss and increasing the pressure in the condensate return pipe for recovering condensate to back pressure to another steam trap device. As a result, the efficiency of the overall steam utilization is reduced, and the life of valves and fittings can be reduced by causing a phenomenon such as a water hammer in the condensate return pipe.

Therefore, the steam trap device must be managed as an important configuration of the surrounding piping system.

However, in the conventional steam trap device according to the prior art, some steam is discharged together in the process of discharging condensate and does not completely block the discharge of steam. Therefore, various problems such as energy loss, deterioration of the efficiency of using steam, and deterioration of the service life of the piping system are caused by the steam discharge.

The present invention has been invented to solve the problems of the prior art, an object of the present invention is to introduce a condensate generated from the steam installation and to detect the level of the condensate by operating a separate on-off valve mounted on the discharge pipe in accordance with the condensate level Therefore, it is possible to provide only steam condensate by completely preventing the discharge of steam, thereby preventing energy loss, improving energy efficiency, and extending the life of the piping system.

Another object of the present invention is to separate the inner space of the housing in which the condensate flows into the inlet chamber and the discharge chamber through the separator plate, which enables more accurate and stable detection of the condensate level and improves durability by preventing damage to various components. It is to provide a steam trap device that can.

The present invention provides a steam trap device for discharging condensed water generated from a steam facility, comprising: a housing having a condensate storage space formed therein; An inlet pipe coupled to the housing such that condensed water enters the housing; A discharge pipe coupled to the housing to discharge the condensed water stored in the housing; A level sensor for generating an electrical signal according to the level of condensate stored in the housing; And it provides a steam trap device comprising an on-off valve that operates to open and close the discharge pipe in accordance with the electrical signal of the water level sensor.

In this case, a separate separating plate is mounted inside the housing so that the inner space of the housing is divided into an inflow chamber communicating with the inflow pipe and a discharge chamber communicating with the discharge pipe, and the condensed water passes through the separation plate. Flow holes are formed, the level sensor may be configured to be located in the discharge chamber.

The water level sensor may include a guide rod penetrating inside and outside of the housing and disposed in a vertical direction; A movable barre coupled to the guide rod so as to move upward and downward by a buoyancy generated from the condensate stored in the housing, the movable contact being mounted at upper and lower ends, respectively; And first and second fixed contacts mounted to upper and lower ends of the guide rod, respectively, so as to be in contact with the movable contact, respectively, according to the up and down movement of the movable bridle, wherein the movable contact is fixed to the first and second. It may be configured to generate different electrical signals upon selective contact with the contacts.

In this case, the first and the second fixed contact may be formed to limit the vertical movement range of the movable portion.

In addition, the discharge pipe may be disposed such that the inlet of the discharge pipe is located below the second fixed contact located at the lower end of the guide rod.

According to the present invention, by entering the condensate generated from the steam equipment and detect the level of the condensate water by operating a separate on-off valve mounted on the discharge pipe in accordance with the condensate level, it is possible to completely prevent the discharge of steam to discharge only the condensate, As a result, energy loss can be prevented, energy efficiency can be improved, and the life of the piping system can be extended.

In addition, by dividing the inner space of the housing into which the condensate flows into the inlet chamber and the discharge chamber through the separator plate, it is possible to detect the more accurate and stable condensate level and to improve the durability by preventing damage to various parts. have.

In addition, the structure of the water level sensor using the buoyancy to maintain the condensate of a certain height at all times in the interior space of the housing, and the inlet of the discharge pipe for discharging the condensate is always kept submerged in the condensed water, to discharge steam through the discharge pipe Can be completely blocked and only the condensate can be discharged, which is more effective in preventing energy loss.

1 is a perspective view schematically showing the configuration of a steam trap apparatus according to an embodiment of the present invention,
Figure 2 is a cross-sectional view schematically showing the internal structure of the steam trap apparatus according to an embodiment of the present invention,
3 and 4 is an operating state diagram schematically showing an operating state of the steam trap apparatus according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings. In addition, in describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

1 is a perspective view schematically showing the configuration of a steam trap apparatus according to an embodiment of the present invention, Figure 2 is a cross-sectional view schematically showing the internal structure of the steam trap apparatus according to an embodiment of the present invention, 3 and 4 is an operating state diagram schematically showing an operating state of the steam trap apparatus according to an embodiment of the present invention.

As a device for discharging condensate 700 generated from a steam installation, it is configured to minimize the discharge of steam and to discharge only the condensate, the housing 100, inlet pipe 200, discharge pipe 300, water level sensor ( 400) and on-off valve 500 is configured.

The housing 100 is formed in a hermetically sealed container, and a condensate 700 storage space is formed therein, and a separate inspection window 110 is formed at one side thereof so that the condensate storage state can be observed.

The inlet pipe 200 has one end coupled to the steam line 210 of the steam installation so that the condensed water 700 generated from the steam installation flows into the housing 100, and the other end thereof is penetrated through the housing 100.

The discharge pipe 300 has one end coupled to the housing 100 so that the condensed water 700 stored in the housing 100 can be discharged through the inlet pipe 200, and the other end is coupled to the discharge line 310 of the steam installation. do. The discharge line 310 may be circulated and supplied in a manner in which the discharge line 310 is recovered through a separate condensate recovery tube (not shown) and provided to the steam facility again.

The level sensor 400 is configured to generate different electrical signals according to the level of the condensate 700 stored in the housing 100, and detects the highest and lowest threshold level preset for the condensate 700 level. To generate different electrical signals in each state.

The open / close valve 500 operates to open and close the discharge pipe 300 according to the electrical signal generated by the water level detection sensor 400, and may be coupled to the discharge line 310 of the steam installation as illustrated in FIGS. 1 to 4. Alternatively, alternatively, the discharge pipe 300 may be directly coupled to operate. The open / close valve 500 may be configured in the form of a solenoid valve that operates according to an electrical signal. On the other hand, the electrical signal generated by the water level sensor 400 is applied to a separate control unit 600 composed of a microcomputer, etc., through the control unit 600 may be controlled to open and close the operation valve 500.

According to such a structure, the steam trap device according to an embodiment of the present invention is a condensed water 700 generated from the steam facility is introduced into the housing 100 through the inlet pipe 200 is stored above a certain level of water level sensor An electrical signal is generated by the 400, and the open / close valve 500 operates accordingly, and the condensate 700 is discharged through the discharge pipe 300. As the condensate 700 is discharged as described above, when the condensate 700 stored in the housing 100 decreases below a predetermined level, another electrical signal is generated by the water level detection sensor 400, and thus an open / close valve. 500 is closed and the discharge of the condensate 700 is blocked. When the discharge of the condensate 700 is blocked, the storage level of the condensate 700 is increased again in the housing 100, and then the opening / closing valve 500 is opened in accordance with the electrical signal by the level sensor 400 again. In operation, the condensed water 700 is repeatedly circulated in such a manner that the condensed water 700 is discharged through the discharge pipe 300.

Next, let's look at each configuration in more detail.

First, the inner space of the housing 100 may be divided into an inlet chamber 120 and an outlet chamber 130 through a separate separator plate 140 as shown in FIG. 2, and in the inlet chamber 120 The inlet pipe 200 may be communicatively coupled, and the outlet tube 300 may be communicatively coupled to the discharge chamber 130. At this time, the condensate flow hole 141 through which the condensate 700 passes so that the condensed water 700 introduced into the inlet chamber 120 through the inlet pipe 200 may flow into the discharge chamber 130. ) Is formed in plurality, and the water level detection sensor 400 is disposed in the discharge chamber 130.

According to this structure, the condensed water 700 introduced into the inlet chamber 120 through the inlet pipe 200 flows into the discharge chamber 130 through the condensed water flow hole 141 of the separating plate 140 and the housing 100. It indicates the level of water level in the whole interior space. That is, not only the condensate 700 but also a predetermined amount of steam flows in the inlet pipe 200 and flows into the housing 100. At this time, the steam flows in a high pressure state, so the vortex or turbulent flow inside the housing 100. This may cause the level measurement of the water level sensor 400 may not be accurate or may cause damage. Therefore, by separating the inner space of the housing 100 into the inlet chamber 120 and the discharge chamber 130 through the separator plate 140 according to an embodiment of the present invention, the condensed water introduced through the inlet pipe 200 ( 700) and steam are first introduced into the inlet chamber 120, and then stabilized to a normal state in the inlet chamber 120, and then flows to the discharge chamber 130, so that the condensate level is stable. In particular, by placing the water level sensor 400 in the discharge chamber 130, which is separate from the inlet chamber 120, it is possible to prevent damage to the water level sensor 400 by the high pressure steam flow. In addition, it is possible to perform the measurement operation on the condensate 700 level more accurately.

The water level detection sensor 400 is configured to detect the highest level and the lowest level of the condensate 700, which are set in advance, to generate an electrical signal. The guide rod 410, the movable bar 420, and the first and second levels It comprises a fixed contact (431,432).

The guide rod 410 is coupled to the housing 100 so as to penetrate the inside and the outside of the housing 100 and disposed in the vertical direction, and an electric wire (not shown) connected to the first and second fixed contacts 431 and 432 is inserted therein. It can be formed in the form of a hollow pipe. A separate electrode terminal 450 is formed at a portion protruding outside the housing 100 of the guide rod 410 so that an electrical signal of the water level sensor 400 can be transmitted to the outside. On the other hand, a separate support 440 is formed at the outer end of the guide rod 410, and a separate support pipe 441 is provided on the outer surface of the housing 100 to support the support 441. Can be mounted.

The movable buckle 420 is coupled to the guide rod 410 so as to be linearly movable in the vertical direction, and is configured to vertically move by buoyancy generated from the condensate 700. That is, the movable buckle 420 may be formed in the form of an airtight container in which an air layer is formed therein so that buoyancy may be relatively large, and as shown in FIG. Located in, and is configured to move up and down in a floating state on the surface of the condensate 700 according to the increase and decrease of the condensate 700 level. At this time, the movable contact 421 is mounted on the upper and lower ends of the movable bridle 420, respectively.

The first and second fixed contacts 431 and 432 are mounted to upper and lower ends of the guide rod 410, respectively, and may contact the movable contacts 421 of the movable bar 420 as the movable bar 420 moves up and down. So that it is formed. That is, when the movable portion 420 moves up and down in accordance with the increase or decrease of the condensate level, the movable contact 421 of the movable portion 420 contacts the first fixed contact 431 or the second fixed contact 432 and the electrical signal. Is configured to be generated.

According to this structure, the water level sensor 400 as shown in FIGS. 3 and 4 when the level of the condensate 700 is lowered and the movable portion 420 moves downward, the movable contact 421 of the movable portion 420. In contact with the second fixed contact 432 located at the lower end of the guide rod 410 to generate an electrical signal, when the condensate level is increased to move the movable portion 420, the movable contact of the movable portion 420 ( 421 contacts the first fixed contact 431 located at the upper end of the guide rod 410 to generate another electrical signal.

At this time, the electrical signal generated by the contact between the movable contact 421 and the second fixed contact 432 according to the decrease of the condensate 700 level is applied to a separate control unit 600, the control unit 600 is such an electrical signal As a control to the closing valve 500 of the discharge pipe 300 operates. Meanwhile, as the level of the condensate 700 increases, an electrical signal generated by contact between the movable contact 421 and the first fixed contact 431 is similarly applied to the controller 600, and in this case, the controller 600 controls the electrical signal. The open / close valve 500 of the discharge pipe 300 is controlled to open according to the signal.

Therefore, when the water level of the condensate 700 is stored above the predetermined level in the interior space of the housing 100, the movable contact 421 and the first fixed contact 431 are in contact with each other, and the opening / closing valve 500 is opened to open the discharge pipe 300. When the condensate 700 is discharged, and the condensate 700 is discharged, the level of the condensate 700 stored in the inner space of the housing 100 is reduced. As such, when the water level of the condensate 700 decreases, the movable contact 421 and the second fixed contact 432 contact each other, and the opening / closing valve 500 is closed to block the discharge of the condensate 700 through the discharge pipe 300. . As the condensate discharge is blocked as described above, the condensate 700 continues to flow from the steam facility through the inlet pipe 200, and thus the condensate 700 level is increased in the housing 100. When the water level of the condensate 700 reaches a certain level, the movable contact 421 and the first fixed contact 431 again contact each other, and the opening / closing valve 500 is opened to discharge the condensate 700 through the discharge pipe 300. do. Through such continuous repetitive circulation operation, the condensed water 700 introduced from the steam facility is repeatedly discharged through the discharge pipe 300.

Meanwhile, the first and second fixed contacts 431 and 432 may be formed in a flat plate shape through which the guide rod 410 is penetrated to limit the vertical movement range of the movable buckle 420. Electrical contact between the 421 and the first and second fixed contacts 431 and 432 may be made more smoothly, and the water level sensor 400 may operate more accurately and stably.

In addition, the discharge pipe 300 is preferably disposed such that the inlet of the discharge pipe 300 is located below the second fixed contact 432 located at the lower end of the guide rod 410. That is, as shown in FIG. 2, the distance X2 from the bottom surface of the housing 100 to the inlet of the discharge pipe 300 is the distance X1 from the bottom surface of the housing 100 to the second fixed contact 432. Preferably, the discharge pipe 300 is disposed to be smaller than the discharge pipe 300.

According to this arrangement structure, the inlet of the discharge pipe 300 is always kept locked in the condensate 700, even if steam is introduced into the housing 100, the steam is not discharged through the discharge pipe 300, only the condensate 700 Only through the discharge pipe 300 is discharged.

In other words, the condensate 700 stored inside the housing 100 may be the same as the second fixed contact 432 by the operation of the water level sensor 400 and the opening / closing valve 500 as described above even in the case of the lowest water level. Since it does not decrease below the height, when the inlet of the discharge pipe 300 is located at a lower position than the second fixed contact 432, the inlet of the discharge pipe 300 is always kept submerged in the condensate 700. As such, when the inlet of the discharge pipe 300 is kept locked to the condensate 700, even if steam is introduced into the housing 100 through the inlet pipe 200, the steam is not discharged through the discharge pipe 300, but only the condensed water. Only 700 is discharged through the discharge pipe (300).

On the other hand, the inlet pipe 200 is the outlet of the upper portion of the interior space of the housing 100 so that the steam flowing into the housing 100 together with the condensate 700 can be located relatively in the upper space in the housing 100 It is preferably arranged to be located at.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas falling within the scope of the same shall be construed as falling within the scope of the present invention.

100: housing 120: inlet chamber
130: discharge chamber 140: separator plate
200: inlet pipe 300: discharge pipe
400: water level sensor 410: guide rod
420: movable bure 421: movable contact
431: first fixed contact 432: second fixed contact
500: on-off valve 600: control unit
700: condensate

Claims (5)

delete In the steam trap device for discharging condensate generated from the steam installation,
A housing having a condensate storage space formed therein;
An inlet pipe coupled to the housing such that condensed water enters the housing;
A discharge pipe coupled to the housing to discharge the condensed water stored in the housing;
A level sensor for generating an electrical signal according to the level of condensate stored in the housing; And
On / off valve operated to open and close the discharge pipe in accordance with the electrical signal of the water level sensor
Including,
A separate separator plate is mounted inside the housing such that the inner space of the housing is divided into an inflow chamber communicating with the inflow pipe and a discharge chamber communicating with the discharge pipe.
Condensate flow holes are formed in the separation plate to pass the condensate, the water level sensor is characterized in that the steam trap device located in the discharge chamber.
The method of claim 2,
The water level sensor
A guide rod penetrating the inside and the outside of the housing and disposed in a vertical direction;
A movable barre coupled to the guide rod so as to move upward and downward by a buoyancy generated from the condensate stored in the housing, the movable contact being mounted at upper and lower ends, respectively; And
First and second fixed contacts respectively mounted to upper and lower ends of the guide rods so as to be in contact with the movable contacts, respectively, as the movable bush moves up and down.
And a different electrical signal is generated as the movable contact selectively contacts the first and second fixed contacts.
The method of claim 3, wherein
The first and second fixed contact is a steam trap device, characterized in that formed to limit the vertical movement range of the movable portion.
The method of claim 4, wherein
The discharge pipe is a steam trap device, characterized in that the inlet of the discharge pipe is disposed below the second fixed contact located on the lower end of the guide rod.

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