JP6809907B2 - Drain pot and drain collection system - Google Patents

Description

The present application relates to a drain pot and a drain recovery system.

Conventionally, a drain collection system for collecting drains from a drain distribution section such as a drain header with an apparatus has been known. In such a drain recovery system, two devices, a main device and a backup device, may be provided in consideration of the fact that the device becomes inoperable due to a failure or the like. In that case, for example, as disclosed in Patent Document 1, the two devices (pressure pumps) are connected to the drain flow section (liquid tank) by the inflow pipe, respectively. In the drain storage section, the inflow pipe for backup equipment has a higher opening position than the inflow pipe for main equipment. By doing this, if the main device breaks down, the drain in the drain distribution section will not be collected by the main device, so the water level will rise, but if the drain water level rises to the opening position of the inflow pipe for the backup device, the drain will back up. Collected by equipment. In this way, the drain can be discharged in the drain distribution section, and a new drain can be distributed.

Japanese Unexamined Patent Publication No. 2013-130147

By the way, in the drain distribution section, the drain water surface may not be uniform and may sway. Then, in the above-described configuration, the drain may flow into the backup device even though the main device has not failed, that is, the drain water level has not substantially risen to a predetermined position. There is. As a result, the backup device operates unnecessarily, leading to failure of the backup device and shortening of its life.

The technique disclosed in the present application has been made in view of such circumstances, and the purpose is to ensure that the backup device operates unnecessarily in a system equipped with a main device and a backup device for collecting the drain of the drain distribution section. It is to prevent.

The drain pot of the present application includes a drain storage portion, an inflow pipe, and a pressure equalizing pipe. The storage unit has an upstream passage, a downstream passage, an inlet, an outlet, and an exhaust port. The upstream passage and the downstream passage extend in the vertical direction and communicate with each other at the lower end. The inflow port is formed in the upstream passage. The outlet is formed at a position higher than the inlet in the downstream passage. The exhaust port is formed at the upper end of the downstream passage. The inflow pipe is connected to the inflow port. The pressure equalizing pipe communicates the exhaust port with the inflow pipe.

Further, the drain collection system of the present application includes a drain distribution unit, a main system, and a backup system. The main system is connected to a main pipe connected to a position lower than the top of the drain distribution section, and the drain of the drain distribution section flows in through the main pipe, and the drain flows into the main pipe. It has a main discharge device that discharges to the outside. The backup system is connected to the above-mentioned drain pot connected to the drain distribution section, a backup pipe connected to the outlet of the drain pot, and the backup pipe, and the drain of the drain distribution section is connected to the drain pot. It also has a backup discharge device that flows in through a backup pipe and discharges the inflowing drain to the outside. The drain pot is installed so that the inflow pipe is connected to the top of the drain flow section and the position of the outlet is higher than the top of the drain flow section.

According to the drain pot and drain recovery system of the present application, it is possible to prevent the backup machine discharge device from operating unnecessarily.

FIG. 1 is a piping system diagram showing a schematic configuration of a drain pot and a drain recovery system according to an embodiment. FIG. 2 is a piping system diagram showing a schematic configuration of a drain pot and a drain recovery system according to an embodiment.

Hereinafter, embodiments of the present application will be described with reference to the drawings. It should be noted that the following embodiments are essentially preferred examples and are not intended to limit the scope of the techniques disclosed in the present application, their applications, or their uses.

The drain recovery system 1 of the present embodiment recovers the drain generated by the steam-using equipment 11, and supplies the recovered drain to the equipment used. Boiler equipment is an example of equipment used. As shown in FIG. 1, the drain recovery system 1 includes a recovery pipe 12, a drain header 14, a main system 20 for collecting (discharging) the drain of the drain header 14, and a backup system 30.

One end (upstream end) of the recovery pipe 12 is connected to the steam-using device 11, and the other end (downstream end) is connected to the drain header 14. The steam-using device 11 is, for example, a heat exchanger, and steam is supplied from another facility, and the steam dissipates heat to the object and condenses, and the object is heated. Steam becomes a drain (condensate) by condensing. That is, in the steam-using device 11, the object is heated (latent heat heating) by the latent heat of condensation of steam.

The recovery pipe 12 collects (condenses) the drain (condensate) generated by the condensation of steam in the steam-using equipment 11. A steam trap 13 is provided in the middle of the recovery pipe 12. In the steam trap 13, drain generated by the steam-using device 11 flows into the steam trap 13 through the recovery pipe 12. The steam trap 13 automatically discharges only the inflowing drain to the downstream side due to the pressure difference between the upstream and downstream sides (the difference between the pressure on the upstream side and the pressure on the downstream side). In fact, the drain mixed with steam flows into the steam trap 13.

The recovery pipe 12 is connected to the top 16 of the drain header 14. In the drain header 14, the drain generated by the steam-using device 11 flows in through the recovery pipe 12 and is temporarily stored. The drain header 14 corresponds to the drain distribution unit according to the claim of the present application. In the present application, the drain distribution unit means a place where drain flows, a place where drain is stored, a place where drain is generated and collected, and the like.

The main system 20 includes an inflow pipe 21 and a main discharge device 22. One end (upstream end) of the inflow pipe 21 is connected to the bottom 15 of the drain header 14, and the other end (downstream end) is connected to the main discharge device 22. The inflow pipe 21 corresponds to the main pipe according to the claim of the present application.

The main discharge device 22 is a liquid pumping device that introduces a working gas and discharges a drain by the pressure of the working gas. The main discharge device 22 has a drain inlet 23 to which the inflow pipe 21 is connected, a drain pressure feed port 24, a working gas introduction port 26, and a working gas discharge port 25. A pumping pipe 27 is connected to the pumping port 24. Further, although not shown, the main discharge device 22 has a drain storage space formed inside, and floats that rise and fall according to the drain water level of the storage space are housed in the storage space. Further, although not shown, the main discharge device 22 has an opening / closing mechanism for opening and closing the discharge port 25 and the introduction port 26 by raising and lowering the float.

In the main discharge mechanism 20, when the drain is not accumulated in the storage space, the float is located at the bottom of the storage space. In this state, the introduction port 26 is closed and the discharge port 25 is open. Then, the drain of the drain header 14 flows in from the inflow port 23 through the inflow pipe 21 and accumulates in the storage space. The float rises as the drain accumulates in the storage space. In the storage space, the working gas is discharged from the discharge port 25 as the drain accumulates. Then, when the drain water level in the storage space reaches a predetermined high water level, the introduction port 26 is opened and the discharge port 25 is closed by the opening / closing mechanism.

When the introduction port 26 is opened, the working gas flows in from the introduction port 26 and is introduced into the upper part of the storage space. As a result, the drain accumulated in the storage space is pushed downward by the pressure of the introduced working gas and discharged from the pressure feeding port 24. The drain discharged from the pumping port 24 is supplied to the equipment used through the pumping pipe 27. When the drain water level in the storage space drops due to drainage, the float drops. Then, when the drain water level in the storage space reaches a predetermined low water level, the introduction port 26 is closed and the discharge port 25 is opened by the opening / closing mechanism. In this way, in the main discharge device 22, the drain inflow operation and the drain operation are alternately repeated.

In this way, the main discharge device 22 collects (discharges) the drain of the drain header 14 by using the pressure of the introduced working gas as a power source. That is, the main discharge device 22 is a non-electric (power-free) device. The high-pressure steam used in the equipment in which the drain recovery system 1 is incorporated is introduced into the introduction port 26 as a working gas.

The backup system 30 collects (discharges) the drain of the drain header 14 instead of the main system 20 when the main discharge device 22 becomes inoperable due to a failure or the like. When the main discharge device 22 becomes inoperable, the drain of the drain header 14 is not collected by the main system 20, so that the drain water level rises in the drain header 14 and eventually becomes full. Then, the drain generated in the steam-using device 11 cannot flow into the drain header 14, which causes a problem. When the drain header 14 is full, the backup system 30 collects (discharges) the drain from the drain header 14 and enables the drain to flow from the steam-using device 11 to the drain header 14.

The backup system 30 includes an outflow pipe 31, a backup discharge device 32, and a drain pot 40. One end (upstream end) of the outflow pipe 31 is connected to the drain pot 40, and the other end (downstream end) is connected to the backup discharge device 32. The outflow pipe 31 corresponds to the backup pipe according to the claim of the present application.

The backup discharge device 32 has the same configuration as the main discharge device 22, and is a liquid pumping device that introduces a working gas and discharges a drain by the pressure of the working gas. That is, the backup discharge device 32 has a drain inlet 33 to which the outflow pipe 31 is connected, a drain pressure feed port 34, a working gas introduction port 36, and a working gas discharge port 35. A pumping pipe 37 is connected to the pumping port 34. Although not shown, the backup discharge device 32 has a drain storage space formed inside, and the float accommodated in the storage space and the opening / closing opening / closing of the discharge port 35 and the introduction port 36 by ascending / descending the float. It has a mechanism and performs inflow and discharge operations similar to those of the main discharge device 22.

The drain pot 40 is connected between the drain header 14 and the outflow pipe 31. The drain pot 40 prevents the drain of the drain header 14 from flowing into the outflow pipe 31 when the drain of the drain header 14 is not full (that is, the drain water level of the drain header 14 does not reach the top 16). Then, the drain pot 40 allows the drain of the drain header 14 to flow into the outflow pipe 31 when the drain of the drain header 14 is full (that is, the drain water level of the drain header 14 reaches the top 16). The drain pot 40 includes a storage unit 41, an inflow pipe 49, a pressure equalizing pipe 51, and a check valve 52.

The storage unit 41 is formed in a columnar container having a vertically long outer shape for temporarily storing the drain. The storage unit 41 is provided with a partition member 42 inside. The partition member 42 is a member that extends in the vertical direction and partitions the inside of the storage unit 41 in the horizontal direction. The inside of the storage unit 41 is partitioned into an upstream passage 43 and a downstream passage 44 by a partition member 42. The partition member 42 is provided at a distance from the bottom plate of the storage portion 41. This interval is a communication portion 45 in which the upstream passage 43 and the downstream passage 44 communicate with each other at the lower end. In this way, a substantially U-shaped fluid passage is formed in the storage portion 41 by the upstream side passage 43, the communication portion 45, and the downstream side passage 44.

The upstream side passage 43 and the downstream side passage 44 are passages (spaces) extending in the vertical direction. Further, the upstream passage 43 is formed in the storage portion 41 from the bottom plate to the substantially central portion, and the downstream passage 44 is formed in the storage portion 41 from the bottom plate to the upper plate. That is, the upstream side passage 43 is shorter than the downstream side passage 44, and the upper end of the upstream side passage 43 is lower than the upper end of the downstream side passage 44. The lower end of the upstream passage 43 and the lower end of the downstream passage 44 have the same installation height. On the side wall of the storage portion 41, a drain inlet 46 that opens above the upstream passage 43 and a drain outlet 47 that opens above the downstream passage 44 are formed. Further, an exhaust port 48 that opens into the downstream passage 44 is formed on the upper plate of the storage portion 41. That is, the exhaust port 48 is provided at the upper end of the downstream passage 44.

The inflow pipe 49 is connected between the drain header 14 and the storage unit 41. That is, one end (upstream end) of the inflow pipe 49 is connected to the top 16 of the drain header 14, and the other end (downstream end) is connected to the inflow port 46 of the storage unit 41. The pressure equalizing pipe 51 communicates the exhaust port 48 and the inflow pipe 49. That is, one end (upstream end) of the pressure equalizing pipe 51 is connected to the exhaust port 48, and the other end (downstream end) is connected in the middle of the inflow pipe 49. An outflow pipe 31 is connected to the outflow port 47 of the storage unit 41.

The check valve 52 is provided in the pressure equalizing pipe 51, and allows only the flow of fluid from the exhaust port 48 side to the inflow pipe 49 side in the pressure equalizing pipe 51. The check valve 52 is closed by urging the valve body to the upstream side by the urging member. Then, when the fluid pressure on the upstream side rises above a predetermined value, the check valve 52 opens against the urging force of the urging member.

The drain pot 40 is installed so that the inflow port 46 of the storage unit 41 and the top 16 of the drain header 14 have the same installation height H1. Further, the drain pot 40 is set so that the installation height H2 of the outlet 47 of the storage unit 41 is higher than the installation height H1 of the top 16 of the drain header 14. That is, in the drain pot 40, the outflow port 47 is located higher than the inflow port 46.

<Driving operation>
First, a case where the main discharge device 22 can be operated will be described with reference to FIG. As shown by the thick arrow in FIG. 1, the drain generated by the steam-using device 11 flows into the drain header 14 via the recovery pipe 12 and is stored. The drain stored in the drain header 14 flows into the main discharge device 22 via the inflow pipe 21, is stored, and is eventually discharged. In this way, in the drain header 14, the drain flows in from the steam-using device 11, while the drain is discharged by the main discharge device 22. Therefore, the drain of the drain header 14 is not full.

On the other hand, in the drain pot 40, the drain is stored in the storage section 41 to a position higher than that of the communication section 45. That is, in the storage unit 41, the communication unit 45 is water-sealed by a drain. The steam existing in the upper part of the drain header 14 flows into the drain pot 40. Specifically, the steam existing in the drain header 14 flows into the upstream passage 43 of the storage unit 41 via the inflow pipe 49. The steam that has flowed into the upstream passage 43 does not flow into the downstream passage 44 because the communication portion 45 is water-sealed by the drain. Further, the steam of the drain header 14 also flows into the pressure equalizing pipe 51 via the inflow pipe 49. The steam flowing into the pressure equalizing pipe 51 does not flow into the downstream passage 44 of the storage unit 41 because the check valve 52 is closed. In this way, it is possible to prevent the steam existing in the drain header 14 from passing through the drain pot 40 and flowing into the backup discharge device 32.

Further, in the drain header 14, even if the drain water level does not substantially reach the top 16, the water surface of the drain may sway and the drain may flow into the inflow pipe 49 of the drain pot 40. In that case, the drain that has flowed into the inflow pipe 49 flows into the upstream passage 43 of the storage unit 41 and is stored. As a result, the stored water level of the drain of the storage unit 41 rises, but does not rise to the position of the outlet 47. That is, since the inflow port 46 has the same installation height H1 as the top 16 of the drain header 14 and the outflow port 47 is at a position higher than the inflow port 46, the storage water level of the drain in the storage section 41 is higher than the inflow port 46. It does not rise to a high position. In this way, even if the water surface sways in the drain header 14 and the drain flows into the inflow pipe 49, it is possible to prevent the drain from passing through the storage unit 41 and flowing into the backup discharge device 32. This makes it possible to prevent the backup discharge device 32 from operating unnecessarily.

Next, the case where the main discharge device 22 becomes inoperable will be described with reference to FIG. In this case, in the drain header 14, the drain flows in from the steam-using device 11, but the drain is not discharged by the main system 20. Therefore, in the drain header 14, the drain water level gradually rises, and eventually the drain becomes full. Then, as shown by the thick arrow in FIG. 2, the drain of the drain header 14 flows into the upstream passage 43 of the storage unit 41 through the inflow pipe 49. On the other hand, drain flows into the drain header 14 from the steam-using device 11.

Therefore, in the storage unit 41, the drain flows from the upstream side passage 43 to the downstream side passage 44, and the stored water level of the downstream side passage 44 rises. As the stored water level in the downstream passage 44 rises, the steam existing in the upper part of the downstream passage 44 is compressed and the pressure of the steam rises. Then, when the steam pressure rises to a predetermined value in the downstream passage 44, the check valve 52 opens, and the steam in the downstream passage 44 is discharged to the inflow pipe 49 via the pressure equalizing pipe 51. In this way, the steam is discharged from the downstream passage 44, so that the drain easily flows from the upstream passage 43 to the downstream passage 44, and the drain water level of the downstream passage 44 is more likely to rise. That is, in the storage unit 41, gas-liquid replacement is performed in which steam is discharged and drainage flows in.

Then, when the stored water level of the drain in the downstream passage 44 rises to the position of the outflow port 47, the drain in the downstream passage 44 flows into the backup discharge device 32 through the outflow pipe 31. In this way, when the drain in the drain header 14 is full, the drain in the drain header 14 automatically flows into the backup discharge device 32 and is discharged. In this way, even if the drain of the drain header 14 becomes full due to the inoperability of the main discharge device 22, the drain of the drain header 14 is discharged by the backup system 30.

As described above, the drain pot 40 of the above embodiment has an upstream passage 43 and a downstream passage 44 communicating with each other at the lower ends, an inflow port 46 formed in the upstream passage 43, and an inflow port in the downstream passage 44. A drain storage portion 41 having an outflow port 47 formed at a position higher than 46 and an exhaust port 48 formed at the upper end of the downstream passage 44 is provided. Further, the drain pot 40 includes an inflow pipe 49 connected to the inflow port 46 and a pressure equalizing pipe 51 that communicates the exhaust port 48 and the inflow pipe 49.

According to this configuration, the inflow pipe 49 is connected to the top 16 of the drain header 14 (drain distribution section), and the drain pot 40 is provided so that the inflow port 46 has the same installation height H1 as the top 16 of the drain header 14. By connecting between the drain header 14 and the backup discharge device 32, even if the water surface of the drain in the drain header 14 sways and the drain flows into the storage unit 41 through the inflow pipe 49, the drain is discharged to the storage unit 41. It can be prevented from flowing out from. This makes it possible to prevent the drain of the drain header 14 from flowing into the backup discharge device 32 when the main discharge device 22 is operable, that is, when the drain header 14 is not full. Therefore, it is possible to prevent the backup discharge device 32 from operating unnecessarily.

On the other hand, when the drain header 14 becomes full due to the inoperability of the main discharge device 22, the drain of the drain header 14 can be automatically passed through the drain pot 40 and flowed into the backup discharge device 32. In this way, the backup discharge device 32 can be operated only when necessary.

Further, in the drain pot 40 of the above embodiment, a check valve 52 is provided in the pressure equalizing pipe 51. According to this configuration, it is possible to prevent the steam existing in the drain header 14 from passing through the drain pot 40 and flowing into the backup discharge device 32. When steam flows into the stopped backup discharge device 32 for a long time, the inflowing steam condenses and becomes a drain. This drain causes rust on the backup discharge device 32, which causes a failure or a shortened life. In the above embodiment, it is possible to prevent such a failure or shortening of the life of the backup discharge device 32.

Further, the drain collection system 1 of the above embodiment includes a drain header 14 (drain distribution unit), a main discharge device 22 connected to a position lower than the top of the drain header 14 via an inflow pipe 21, and a drain header 14. The above-mentioned drain pot 40 connected to the drain pot 40 and a backup discharge device 32 connected to the outlet 47 of the drain pot 40 via an outflow pipe 31 are provided. The drain pot 40 is installed so that the inflow pipe 49 is connected to the top 16 of the drain header 14 and the position of the outlet 47 is higher than the top 16 of the drain header 14. According to this configuration, it is possible to provide the drain recovery system 1 that exerts the above-mentioned effect on the drain pot 40.

Further, the drain recovery system 1 of the above embodiment is a non-electric device in which the main discharge device 22 and the backup discharge device 32 introduce a working gas and operate by the pressure of the working gas. Therefore, for example, it is difficult to detect the drain water level of the drain header 14 and operate the backup discharge device 32 based on the detection signal. In this respect, in the drain recovery system 1 of the above-described embodiment, by providing the above-mentioned drain pot 40, the backup discharge device 32 can be reliably operated when necessary without detecting the drain water level of the drain header 14. Can be done.

(Other embodiments)
The above embodiment may have the following configuration.

For example, the upstream passage 43 may be formed from the bottom plate to the top plate in the storage portion 41. In that case, the inflow port 46 is formed at a position lower than the outflow port 47 as in the above embodiment.

Further, in the above embodiment, the drain header 14 is illustrated as the drain distribution unit, but the technique disclosed in the present application is not limited to this, and the drain pipe through which the drain flows and the drain pool portion where the drain is generated and accumulated due to the condensation of steam are used. May be applied as a drain distribution unit.

Further, the main discharge device and the backup discharge device are not limited to the device that introduces the working gas and discharges (pressure feeds) the drain by the pressure of the working gas as described in the above embodiment, but only the inflowing drain such as the steam trap. It may be a drain trap that discharges the gas to the outside.

The techniques disclosed in this application are useful for drain pots and drain recovery systems.

1 Drain collection system 14 Drain header (drain distribution department)
16 Top 20 Main system 21 Inflow pipe (main pipe)
22 Main discharge equipment 30 Backup system 31 Outflow pipe (backup pipe)
32 Backup discharge device 40 Drain pot 41 Storage unit 43 Upstream side passage 44 Downstream side passage 46 Inflow port 47 Outlet 48 Exhaust port 49 Inflow pipe 51 Pressure equalizing pipe

Claims (5)

An upstream passage and a downstream passage that extend in the vertical direction and communicate with each other at the lower ends, an inflow port formed in the upstream passage, an outlet formed in the downstream passage at a position higher than the inflow port, and the above. A drain reservoir with an exhaust port formed at the top of the downstream passage,
The inflow pipe connected to the inflow port and
A drain pot including a pressure equalizing pipe for communicating the exhaust port and the inflow pipe. In the drain pot according to claim 1,
A drain pot provided on the pressure equalizing pipe and provided with a check valve that allows only the flow of fluid from the exhaust port side to the inflow pipe side of the pressure equalizing pipe. With the drain distribution department
A main pipe connected to a position lower than the top of the drain distribution unit, a main pipe connected to the main pipe, drain of the drain distribution unit flows in through the main pipe, and the inflowing drain is discharged to the outside. The main system with discharge equipment and
The drain pot according to claim 1 or 2, which is connected to the drain distribution section, a backup pipe connected to the outlet of the drain pot, and a drain connected to the backup pipe, the drain of the drain distribution section is connected to the drain pot and the drain pot. It is equipped with a backup system having a backup discharge device that flows in through a backup pipe and discharges the inflowing drain to the outside.
The drain pot is a drain collection system in which the inflow pipe is connected to the top of the drain flow section and the outlet is installed so as to be higher than the top of the drain flow section. In the drain collection system according to claim 3,
The main discharge device and the backup discharge device each have a drain inlet to which the main pipe and the backup pipe are connected, a drain pressure feed port, and a working gas introduction port, and also have a drain storage space inside. A drain recovery system formed, wherein a working gas is introduced into the storage space from the introduction port, and drain in the storage space is discharged from the pressure feeding port by the pressure of the working gas. In the drain collection system according to claim 3 or 4.
The drain distribution unit is a drain recovery system characterized in that the drain distribution unit is a drain header in which drain generated in a steam-using device that condenses steam flows in and is stored.

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