KR20230114012A - Smart Steam Trap - Google Patents

Abstract

The smart steam trap of the present invention includes a steam inlet 11, a steam outlet 12, an inlet pipe connection 13 connected to the pipe, and a discharge pipe connection 14 connected to the pipe. A steam flow body portion 10 which is provided to form a flow path through which steam flows; A steam separator 20 to separate steam and condensed water; Located between the steam inlet 11 and the steam outlet 12 of the steam flow body 10, branched from the steam flow body 10, and separated by the steam separator 20 A condensed water outlet 30 for discharging condensed water from the steam flow body 10; A steam inlet temperature measuring unit 40 installed from the outside of the steam flow body 10 to the inside of the steam inlet 11 and measuring the temperature of the steam flowing into the steam inlet 11; A steam discharge temperature measurement unit 50 installed from the outside of the steam flow body 10 to the inside of the steam discharge unit 12 and measuring the temperature of the steam discharged to the steam discharge unit 12; The steam inlet temperature measured by the steam inlet temperature measurement unit 40 is compared with the steam discharge temperature measured by the steam discharge temperature measurement unit 50, and the condensate discharge unit 30 is clogged according to the temperature drop. and a controller 60 for determining the mixing state of live steam when the condensate is discharged by the condensate discharge unit 30.

Description

Smart Steam Trap

The present invention relates to a smart steam trap installed in an energy line that uses steam as a heat source and capable of monitoring the operating state of a steam trap that discharges condensate contained in flowing steam through an orifice nozzle.

In the energy line that uses steam as a heat source, the pipe is wrapped with an insulating material to suppress heat release as much as possible. If the condensed water is not discharged, a hammering phenomenon occurs, which causes problems such as rupture of pipes and damage to air vents.

In general, a steam trap is a device installed in an energy line that utilizes steam as a heat source to discharge condensate contained in flowing steam through an orifice nozzle.

These steam traps leak steam depending on the degree of abrasion caused by the period of use, but it is not easy to determine the replacement time.

There are several diagnostic methods to determine when to replace a steam trap.

As the first diagnosis method to determine when to replace the steam trap, there is visual diagnosis.

The visual diagnosis method is a method of checking the operating state of the steam trap by opening the outlet pipe of the steam trap and monitoring the discharge state of the condensate. In this method, it is not easy to grasp the discharge state of condensate with the naked eye, and it is difficult to make an accurate diagnosis because a diagnosis expert also relies on experience.

As a second diagnosis method to determine the replacement time of the steam trap, there is a diagnosis method by a condensate collection test.

The diagnosis method is a method of quantitatively grasping live steam loss by analyzing the amount of heat in the condensate.

The diagnosis method by this condensate collection test is to install a device for collecting condensate, collect condensate, measure temperature in turn, conduct at least three times for accuracy, and dismantle the device for collecting condensate when the test is completed. will do

The leakage amount of live steam is calculated and derived using the collected amount of condensate, time, and temperature measured in this way.

However, this method takes time to perform a series of processes, and since it is performed manually, there is a problem in that accuracy is lowered.

The third diagnosis method to determine when to replace the steam trap is thermography that measures the surface temperature of the pipe using an infrared detector or the surface of the pipe through a contact thermometer to measure the surface temperature of the pipe There is a way to measure temperature.

This method is inevitably inaccurate in relation to measuring the temperature outside the pipe, and there are frequent problems in diagnosis due to the influence of the environment outside the pipe, etc., but the diagnosis method is relatively simple and is preferred.

This is to improve the problem of the surface temperature measurement method of the pipe, which is the third diagnosis method to determine the replacement time of the steam trap. There is, which is shown in Figure 1.

The live steam leak check device of the steam trap is in the form of a tube having an inlet end connected to the steam trap and a discharge end corresponding to the inlet end, and the condensed water of the steam trap is introduced into the inlet end and discharged through the discharge end. The body 10 making; The horn portion 20 has a hollow structure and protrudes from the middle of the body to communicate with the inside of the body; A first air water separator 30 formed on an inner surface of the body and separating flash steam re-evaporated from the condensate flowing through the body; a second rider 40 formed on an inner surface of the horn head and separating flash steam separated from the first rider rider in the first rider rider rising to the top of the horn rider 40; And a temperature measuring means installed on the top of the horn rod and located inside the horn rod to check whether live steam is leaked from the steam trap by measuring the internal temperature of the upper part of the horn rod and transmitting the temperature to the outside. (50).

The live steam leakage check device of the steam trap measures the temperature of the live steam by the temperature measuring means 50 installed inside the horn rod 20 to check whether the live steam leaks from the steam trap. are doing

However, there is a problem in that live steam may also contain condensate, making it difficult to measure the temperature of only the live steam, and thus reducing the accuracy of checking whether the live steam leaks.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a smart steam trap that can accurately check whether live steam leaks when discharging condensate by a steam trap.

Another object of the present invention is to provide a smart steam trap that can be solved by itself without separately supplying power for driving a sensor for measuring whether or not live steam is leaking.

The smart steam trap of the present invention for achieving the above object is a steam inlet 11 into which steam is introduced on one side, a steam outlet 12 into which steam is discharged on the other side, and the steam inlet 11 An inlet-side pipe connection part 13 provided at the inlet-side end and connected to the pipe, and a discharge-side pipe connection part 14 provided at the discharge-side end of the steam outlet 12 and connected to the pipe, A steam flow body portion 10 forming a flow path through which steam flows; A steam separation unit 20 provided inside the steam flow body 10 and separating steam and condensed water; Located between the steam inlet 11 and the steam outlet 12 of the steam flow body 10, branched from the steam flow body 10, and separated by the steam separator 20 A condensed water outlet 30 for discharging condensed water from the steam flow body 10; A steam inlet temperature measuring unit 40 installed from the outside of the steam flow body 10 to the inside of the steam inlet 11 and measuring the temperature of steam flowing into the steam inlet 11; A steam discharge temperature measurement unit 50 installed from the outside of the steam flow body 10 to the inside of the steam discharge unit 12 and measuring the temperature of the steam discharged to the steam discharge unit 12; The steam inlet temperature measured by the steam inlet temperature measurement unit 40 is compared with the steam discharge temperature measured by the steam discharge temperature measurement unit 50, and the condensate discharge unit 30 is clogged according to the temperature drop. and a controller 60 for determining the mixing state of live steam when the condensate is discharged by the condensate discharge unit 30.

In addition, the controller 60 has a temperature drop range between the steam inlet temperature measured by the steam inlet temperature measurement unit 40 and the steam discharge temperature measured by the steam discharge temperature measurement unit 50 within a certain range. If it exceeds or is less than a certain range, a notification unit for notifying an administrator is further provided.

In addition, the controller 60 is fixed to the lower part of the smart steam trap, and the controller 60 is accommodated in the accommodating part 71, and is formed extending upward from one side of the upper part of the accommodating part 71, A first fixing part 72 for fixing the accommodating part 71 to the outside of the steam inlet part 11 of the steam flow body part 10, and extending from one side of the upper part of the accommodating part 71 to the side A controller fixing bracket 70 made of a second fixing part 73 to be fixed to the outside of the condensate discharge part 30; is characterized in that it is further provided.

In addition, the steam inlet temperature measurement unit 40 and the steam discharge temperature measurement unit 50 ) It is characterized in that a thermoelectric element 80 is further provided to supply electricity for operation.

In addition, the installation height of the steam inlet temperature measuring unit 40 into the steam inlet 11 is 1/3 from the top of the steam inlet 11, and the steam discharge temperature measuring unit 50 It is characterized in that the installation height into the inside of the steam outlet 12 is the lower end of the inside of the steam outlet 12.

The smart steam trap of the present invention according to the above configuration measures the steam inlet temperature and the steam discharge temperature, but directly measures the temperature of the inlet steam flowing into the steam inlet and the exhaust steam discharged into the steam outlet, thereby reducing the temperature Depending on the range, it is possible to determine whether or not live steam is mixed or whether the condensate discharge unit 30 is clogged when the condensate is discharged by the condensate discharge unit 30, thereby checking the operating state of the steam trap more accurately to obtain accurate steam. It has the effect of predicting the replacement time of the trap.

In addition, the present invention can be solved by itself without separately supplying power for driving a sensor for measuring leaks of live steam, and also has an energy saving effect because electricity is supplied by generating power using waste heat.

1 is a view showing a conventional steam trap.
Figure 2 is a perspective view showing the appearance of the smart steam trap of the present invention.
Figure 3 is an exploded perspective view of the smart steam trap of the present invention.
Figure 4 is an exploded perspective view showing the controller fixing bracket of the smart steam trap of the present invention.
5 and 6 are views showing the internal structure of the smart steam trap of the present invention.

Hereinafter, the steam trap of the present invention will be described in detail with reference to the drawings.

Figure 2 is a perspective view showing the appearance of the smart steam trap of the present invention, Figure 3 is an exploded perspective view of the smart steam trap of the present invention, Figure 4 is an exploded perspective view showing the controller fixing bracket of the smart steam trap of the present invention, 5 and 6 are views showing the internal structure of the smart steam trap of the present invention.

Steam trap according to the present invention, as shown in Figures 2 to 3, the steam flow body portion 10; Air separation unit 20; Condensate discharge unit 30; Steam inlet temperature measuring unit 40; Steam discharge temperature measurement unit 50; Controller 60; is made including.

The steam flow body portion 10 is in the form of a straight tube and is installed on a pipe through which steam flows. The steam flow body 10 has a steam inlet 11 into which steam is introduced on one side, a steam outlet 12 into which steam is discharged on the other side, and an inlet end of the steam inlet 11. An inlet-side pipe connection part 13 provided and connected to the pipe, and a discharge-side pipe connection part 14 provided at the discharge-side end of the steam outlet 12 and connected to the pipe are provided, and steam flows form a euro

The inlet-side pipe connection part 13 and the discharge-side pipe connection part 14 connect pipes through which steam flows to each other, and are made in the form of screwing with the pipe, and have female or male threads.

The condensate discharge part for discharging the condensate generated from the steam flowing through the steam flow body part 10 and branched to one side from the steam flow body part 10 has various forms, and an example of this is a float type (float type). type), bucket type, bimetal type, bellows type, disc type, and fixed orifice type.

As an example, a bucket-type steam trap is described as follows. When steam flows into the bucket, the bucket rises, closes the ball valve associated with it, and is discharged through the orifice provided in the bucket, allowing the steam to flow. The condensed water is discharged through the vent hole by opening the ball valve.

In the buoyancy type steam trap, condensate is accumulated and the float rises by the buoyancy caused by the condensate to open the condensate discharge hole to discharge the condensate.

In the present invention, in a known structure of a disk-type orifice steam trap or a fixed orifice type steam trap, the condensate discharge part is branched to the lower part of the steam flow body part 10, and the steam discharge part of the steam flow body part 10 ( 12) and is formed to diverge by forming an acute angle.

The steam separator 20 is provided inside the steam flow body 10 and serves to separate steam and condensate, and has a known structure of a disk-type orifice steam trap or a fixed orifice type steam trip.

As shown in FIG. 5, the disk type orifice type steam trap has a strain 21 provided in the condensate discharge part 30 branched downward from the steam flow body part 10, and the steam inlet part An orifice 22 is provided at the upper portion between the 11 and the steam outlet 12, and an upper chamber 23 is provided at the upper portion of the discharge end of the orifice, and a disk 24 that moves up and down in the upper chamber 23 ) is provided, and steam is discharged from the upper chamber 23 to the steam outlet 12 by opening and closing the disk 24.

As shown in FIG. 6, in the fixed orifice type steam trip, a strain 21 is provided in the condensate outlet 30 branched downward from the steam flow body 10, and the steam inlet ( An orifice 22 is provided at the upper portion between 11) and the steam discharge part 12, and a protrusion 25 protruding downward is provided at the upper part of the discharge end of the orifice, and the flow path located in front of the protrusion 25 is steam It communicates with the discharge unit 12 and the condensed water separated steam is discharged.

The steam inlet temperature measurement unit 40 is installed from the outside of the steam flow body 10 to the inside of the steam inlet 11 and serves to measure the temperature of steam flowing into the steam inlet 11 do

The steam discharge temperature measuring unit 50 is installed from the outside of the steam flow body 10 to the inside of the steam discharge unit 12 and serves to measure the temperature of steam discharged to the steam discharge unit 12. do

The controller 60 compares the steam inlet temperature measured by the steam inlet temperature measurement unit 40 and the steam discharge temperature measured by the steam discharge temperature measurement unit 50 to discharge the condensed water according to the temperature drop. When the condensate is discharged by the unit 30, it serves to determine whether live steam is mixed or whether the condensate discharge unit 30 is clogged.

The smart steam trap of the present invention having the above structure measures the steam inlet temperature and the steam discharge temperature, but directly measures the temperature of the inlet steam flowing into the steam inlet and the exhaust steam discharged into the steam outlet, thereby reducing the temperature Depending on the range, it is possible to determine whether or not live steam is mixed or whether the condensate discharge unit 30 is clogged when the condensate is discharged by the condensate discharge unit 30, thereby checking the operating state of the steam trap more accurately to obtain accurate steam. It has the effect of predicting the replacement time of the trap.

In the controller 60, the temperature drop range between the steam inlet temperature measured by the steam inlet temperature measurement unit 40 and the steam discharge temperature measured by the steam discharge temperature measurement unit 50 exceeds a certain range. or less than a certain range is preferably further provided with a notification unit (not shown) to inform the manager.

The notification unit may be provided in a form of turning on a warning light, may be provided in a form of generating an alarm sound, and may notify a manager by a display unit such as an LCD window.

The notification unit determines whether the temperature drop range between the steam inlet temperature measured by the steam inlet temperature measurement unit 40 and the steam discharge temperature measured by the steam discharge temperature measurement unit 50 exceeds a certain range. Indicate whether it is less than or not.

When the temperature drop range between the steam inlet temperature measured by the steam inlet temperature measurement unit 40 and the steam discharge temperature measured by the steam discharge temperature measurement unit 50 exceeds a certain range, the condensed water is smoothly It can be determined that the condensate discharge unit 30 is clogged by not being discharged, and the steam inlet temperature measured by the steam inlet temperature measuring unit 40 and the steam discharge measured by the steam discharge temperature measuring unit 50 When the temperature drop range with the temperature is within a certain range, it is determined that the condensate is discharged by the condensate discharge unit 30 as a mixed state of live steam, and the steam inlet temperature measured by the steam inlet temperature measuring unit 40 and When the temperature drop range of the steam discharge temperature measured by the steam discharge temperature measuring unit 50 is less than a certain range, it is determined that the steam trap is in a normal operating state.

The controller 60 is preferably spaced apart and fixed to the lower part of the smart steam trap.

A controller fixing bracket 70 is used to fix the controller 60 to the lower part of the smart steam trap.

As shown in FIG. 4 , the controller fixing bracket 70 includes a receiving part 71 , a first fixing part 72 , and a second fixing part 73 .

The storage unit 71 accommodates a controller.

The first fixing part 72 extends upward from one side of the upper portion of the accommodating part 71 to place the accommodating part 71 outside the steam inlet 11 of the steam flow body 10. It acts as a fixation.

The second fixing part 73 extends from one side of the upper part of the receiving part 71 to the side and serves to be fixed to the outside of the condensate discharge part 30 .

In addition, in the present invention, a battery may be used to supply electricity for the operation of the steam inlet temperature measurement unit 40 and the steam discharge temperature measurement unit 50, or electricity may be supplied by wire.

Preferably, in contact with the outer circumferential surface of the steam flow body 10 or the condensate discharge part 30, power is generated by heat radiated to the outer circumferential surface of the steam inlet temperature measurement unit 40 and the steam discharge temperature measurement unit A thermoelectric element 80 for supplying electricity for operation of 50 is provided so that electricity is supplied by itself.

At this time, the thermoelectric element 80 may be in contact with the outer circumferential surface of the steam flow body 10 so that power is generated by radiated heat, but as shown in FIG. 2, on the outer circumferential surface of the condensate discharge unit 30 It is preferable to be installed so as to be in contact with each other so that power is generated by radiating heat.

When the thermoelectric element 80 is in contact with the outer circumferential surface of the condensate discharge unit 30 to generate power by heat dissipated, heat is not taken away from the steam passing through the steam flow body 10 to generate power, and when the condensate is discharged Since power is generated using waste heat radiated from condensate, thermal loss can be reduced as much as possible.

In the case of using the thermoelectric element 80, a battery 90 (see FIGS. 2 to 4) for storing electricity generated by the thermoelectric element 80 is further provided, and the battery 90 can be configured as described above. To be accommodated in the payment 71 (see Fig. 4).

In addition, the installation height of the steam inlet temperature measuring unit 40 into the steam inlet 11 is 1/3 point from the top of the steam inlet 11, and the steam discharge temperature measuring unit 50 It is preferable that the installation height of the inside of the steam discharge part 12 is the lower end of the inside of the steam discharge part 12.

When the installation height of the steam inlet temperature measuring unit 40 into the steam inlet 11 is higher than the 1/3 point from the top of the steam inlet 11, the flow rate slows toward the top of the pipe. Since the amount of steam produced is small, the temperature measurement becomes inaccurate.

In addition, when the installation height of the steam inlet temperature measuring unit 40 into the steam inlet 11 is lower than the 1/3 point from the top of the steam inlet 11 and between the 1/2 point, the inflow Since the speed of the steam is high, the amount of steam introduced is large, so accurate temperature measurement is not accurate.

When the installation height of the steam inlet temperature measuring unit 40 into the steam inlet 11 is 1/3 from the top of the steam inlet 11, it is close to the average flow rate of the incoming steam Accurate temperature measurement is possible.

When the installation height of the steam discharge temperature measuring unit 50 into the steam discharge unit 12 becomes the lower end of the steam discharge unit 12, the condensate has a higher specific gravity than steam and accumulates at the bottom. When the condensed water contained in the steam discharged to the steam discharge unit 12 is included, the temperature drop is large, so when the condensate is discharged by the condensate discharge unit 30 according to the temperature drop, whether or not live steam is mixed or the condensate is discharged It is advantageous to determine whether the part 30 is clogged.

Technical ideas should not be interpreted as being limited to the above-described embodiments of the present invention. Not only the scope of application is diverse, but also various modifications and implementations are possible at the level of those skilled in the art without departing from the gist of the present invention claimed in the claims. Therefore, such improvements and changes fall within the protection scope of the present invention as long as they are obvious to those skilled in the art.

10: steam flow body 11: steam inlet
12: steam discharge part 13: inlet pipe connection part
14: Discharge side piping connection 20: Air separation unit
21: strain 22: orifice
23: upper chamber 24: disk
25: protrusion 30: condensate discharge unit
40: steam inlet temperature measurement unit 50: steam discharge temperature measurement unit
60: controller 70: controller fixing bracket
71: storage unit 72: first fixing unit
73: second fixing part 80: thermoelectric element
90: battery

Claims (5)

A steam inlet 11 through which steam flows in on one side, a steam outlet 12 through which steam is discharged on the other side, and an inlet pipe provided at the inlet end of the steam inlet 11 and connected to the pipe. A steam flow body portion 10 provided with a connection part 13 and a discharge-side pipe connection part 14 provided at the discharge-side end of the steam discharge part 12 and connected to a pipe to form a flow path through which steam flows ;
A steam separation unit 20 provided inside the steam flow body 10 and separating steam and condensed water;
Located between the steam inlet 11 and the steam outlet 12 of the steam flow body 10, branched from the steam flow body 10, and separated by the steam separator 20 A condensed water outlet 30 for discharging condensed water from the steam flow body 10;
A steam inlet temperature measuring unit 40 installed from the outside of the steam flow body 10 to the inside of the steam inlet 11 and measuring the temperature of the steam flowing into the steam inlet 11;
A steam discharge temperature measurement unit 50 installed from the outside of the steam flow body 10 to the inside of the steam discharge unit 12 and measuring the temperature of the steam discharged to the steam discharge unit 12;
The steam inlet temperature measured by the steam inlet temperature measurement unit 40 is compared with the steam discharge temperature measured by the steam discharge temperature measurement unit 50, and the condensate discharge unit 30 is clogged according to the temperature drop. And a controller 60 for determining the mixing state of live steam when the condensate is discharged by the condensate discharge unit 30; Smart steam trap comprising a. The method of claim 1, wherein the controller 60,
If the temperature drop range between the steam inlet temperature measured by the steam inlet temperature measurement unit 40 and the steam discharge temperature measured by the steam discharge temperature measurement unit 50 exceeds a certain range or is less than a certain range, notify the manager Smart steam trap, characterized in that further provided with a notification unit to notify. According to claim 1,
The controller 60 is fixed to the lower part of the smart steam trap,
An accommodating part 71 in which the controller 60 is accommodated;
A first fixing part 72 extending upward from one side of the upper part of the accommodating part 71 so that the accommodating part 71 is fixed to the outside of the steam inlet 11 of the steam flow body 10 and,
A controller fixing bracket 70 formed of a second fixing part 73 extending from one upper side of the receiving part 71 to the side and being fixed to the outside of the condensate discharge part 30; characterized in that it is further provided. A smart steam trap with According to claim 1,
In contact with the outer circumferential surface of the steam flow body part 10 or the condensate discharge part 30, power is generated by the heat radiated to the outer circumferential surface of the steam inlet temperature measurement unit 40 and the steam discharge temperature measurement unit 50 A smart steam trap, characterized in that a thermoelectric element 80 is further provided to supply electricity for operation. According to claim 1,
The installation height of the steam inlet temperature measuring unit 40 into the steam inlet 11 is 1/3 from the top of the steam inlet 11,
Smart steam trap, characterized in that the installation height of the steam discharge temperature measurement unit 50 into the steam discharge portion 12 is the lower end of the steam discharge portion 12 inside.

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