EP2927437A1 - Cooling water conduit with ascending and descending shaft - Google Patents

Abstract

The invention relates to a cooling water pipe (1) for a power plant, which is connected to a condenser (2) and in which, during normal operation, upstream of the condenser (2) comprises a riser duct (10) with a chute (11) arranged downstream therefrom is, and a feed pump (12) which is arranged such that in the riser shaft (10) or upstream of the riser shaft (10) in the cooling water line (1) cooling water (5) can be acted upon by a flow.

Description

The present invention relates to a cooling water pipe for a power plant and a power plant comprising such a cooling water pipe.

The cooling water supply in a power plant takes place via a cooling water pipe. For applying the cooling water in the cooling water line with a flow, suitable pumps are typically provided, via which the flow rate or the flow behavior of the cooling water can be set significantly. In particular, in power plants with a steam part and a water-cooled condenser connected thereto, the pumps for providing cooling water have an essential task. Namely, such pumps fail due to the damage, the entire power plant must be shut down at least partially within a short time, since the capacitor can not be supplied with sufficient cooling power. In order to prevent such incidents, redundant pumps with hydraulically operated adjustment flaps, in particular flaps (including counterweight), which are designed as combined shut-off / non-return flaps or motor-operated shut-off flaps (eg 2 × 50%), are used in modern cooling water lines a pump to be able to maintain at least the cooling water supply partially using the other pump.

The adjustment flaps are typically located at the exit of the pumps and initially serve to shut off the out of service pump to prevent backflow of the cooling water through the pump. In addition, the adjustment flaps are designed to close in case of pump failure controlled to avoid in particular pressure surges. Especially close to the end position of the adjustment flaps this has to be done slowly enough. By a suitable adjustment of the adjustment flaps, the still in operation pumps also be operated within a permissible working range. In the case of empty or partially emptied cooling water lines, a controlled filling of the cooling water lines can also be achieved without, however, operating the pump in impermissible working areas, which could result in pressure surges, for example.

Such pressure surges are to be avoided in the cooling water line, since the forces occurring here can have destructive effect. In order to better adjust the flow characteristics of the cooling water in the cooling water pipe, therefore, the adjustment flaps are provided in the cooling water pipe, which restrict the flow cross section in the cooling water pipe changeable and targeted.

A disadvantage of these known from the prior art technical adjustment flaps, however, is that these are sometimes prone to failure even as active components and are subject to a risk of failure. Thus, the hydraulic or motorized operation of the adjustment flaps can be prevented, for example during a fault in the electrical energy supply and thus have the failure of the pump result. Moreover, because of the sometimes large line cross sections of the cooling water lines, the adjustment flaps are very expensive components, in particular if they are moved hydraulically, the operation of which also requires regular maintenance.

In order to avoid these known from the prior art disadvantages, a cost-effective technical solution is to be proposed, which also allows to ensure safe operation of the cooling water pipe even in case of failure. In addition, the occurrence and propagation of pressure surges in the cooling water pipe should be largely avoided.

These objects of the invention are achieved by a cooling water pipe according to claim 1 and a power plant according to claim 10.

In particular, the objects underlying the invention are achieved by a cooling water line for a power plant, which is connected to a capacitor, and in which in normal operation upstream of the condenser, a riser shaft with respect to downstream arranged chute is included, and a feed pump, the like is arranged, that in the riser shaft or upstream of the riser shaft in the cooling water line cooling water can be supplied with a flow.

Furthermore, the objects underlying the invention are achieved by a power plant, which includes such a previously as well as below described cooling water pipe.

At this point, it should be noted that the normal operation refers to a normal cooling water operation in which cooling water in the cooling water pipe is conveyed in a predetermined direction from the riser to the chute and to the condenser.

A cooling water line for a power plant relates in particular to a cooling water line of a power plant.

The arrangement of the feed pump upstream of the riser takes place according to execution in a region in which the cooling water temperature has at most 60 ° C. In particular, the feed pump is connected between the riser shaft and a cooling tower.

The flow application by means of the feed pump according to the invention is designed such that cooling water is conveyed into the riser and is transferred from there into the chute. In the chute, due to earth gravity, the cooling water falls to a lower location, from where the cooling water continues to sink or flow out. In particular, the riser is at least partially disposed in the chute. However, riser and chute may be both be interconnected only by a suitable overflow pipe, so that a spatial integration of the riser in the chute is not essential.

According to the invention, it is therefore provided that a cooling water line for a power plant has a riser shaft and a downwardly arranged chute. When pumping cooling water by means of the feed pump in this case the cooling water is moved in the riser shaft against the acceleration of gravity upwards. After reaching the upper limit of the riser, the water is transferred to the chute. From there, the water can be transported further in the cooling water line. The further transport takes place here due to the geodetic pressure conditions in the chute.

If, for example, a power plant, which has a cooling water line according to the invention, approached, there is, for example, cooling water in the riser at a height level which is lower than the level of the upper boundary of the riser. Only by operating the feed pump so much water is conveyed into the riser that this flows over after reaching the upper limit in the chute. The overflowing cooling water also raises the height level of the cooling water in the chute to a height level at which the geodesic pressure conditions in the chute are sufficient to carry the cooling water in the chilled water pipe further. The level of this desired cooling water level is reached when the geodetic pressure in the chute sufficient to overcome the pressure losses in the cooling water pipe and the subsequent possibly existing height differences in the cooling water pipe with a sufficient amount of cooling water.

Due to the well-controlled overflow of cooling water from the riser shaft in the chute, even in the presence of pressure fluctuations, such as due to the different operating conditions of the feed pump, a reproduction be prevented by pressure surges in the cooling water pipe. Riser shaft and chute thus decouple the pump from all downstream of the riser shaft arranged components of the cooling water circuit Since there is no continuous water column between the condenser and pump, pressure surges can not propagate between the riser and the chute. Likewise, it can be avoided during the startup or shutdown phase that such pressure surges are transmitted. Especially during the start-up phase, during which insufficient cooling water is initially present in the riser shaft in order to cause an overflow into the chute, an effective fluid-dynamic decoupling and flow regulation in the cooling water line can be achieved.

In addition, the solution according to the invention can completely dispense with the provision of an adjustment flap, as a result of which maintenance-related and safety-related advantages are the result.

In addition, riser and chutes can be built relatively inexpensively depending on the choice of material. Maintenance of these components of the power plant can be achieved relatively quickly and inexpensively due to their simple geometry.

By decoupling the feed pump from the downstream of the riser shaft arranged components of the cooling water circuit, it can not come to high pressures there, as about shut-off valves (eg the butterfly valves on the condenser) are closed and the pump pressure may reach the zero head. In such a case, the cooling water level in the chute would rise until it overflows, insofar as the height of the chute defines the maximum pressure in the cooling water system and no longer the zero head of the cooling water pump. This has the advantage that in particular cooling water lines, water chamber lid on the condenser, etc. can be designed to a lower pressure and can be manufactured correspondingly cheaper. Furthermore causes the defined height of the overflow from the riser into the chute that the cooling water pump can not run out of the curve, as always a height of the riser shaft corresponding minimum pressure can be maintained.

In addition, the cooling water pipe and the condenser in power plants where the water distribution in the cooling tower is the highest point in the cooling water system, (this is the normal case) always completely filled even at a standstill, since the level in the chute automatically lowers only to the height of the water distribution and stays there. This can be dispensed with vacuum breaker and ventilation lines on the condenser in a cooling tower.

It should also be pointed out that due to the simplified fluid-dynamic conditions in the present invention, no complex calculations and project planning have to take place which can greatly delay the completion and exact design of a cooling water line for a power plant.

According to a first particularly preferred embodiment of the invention it is provided that the feed pump is designed as a shaft pump, which is arranged in particular in the riser shaft. A shaft pump should be understood in this case in the sense of a submersible pump, which can be arranged completely in the cooling water or is. In this respect, therefore, the drive unit and the pump unit are arranged completely in the cooling water line. If such a shaft pump provided in the riser, this is typically done in the base region of the riser, so where the static pressures are greatest. To remove such a shaft pump, it is sometimes sufficient already, by means of a suitable fastening device from the riser shaft from above about by means of a crane, which is often readily available in power plants, pull out. As a result, the maintenance and repair work on the pump can be made relatively easily without that pipe connections must be dismantled. In this respect, downtimes can be significantly reduced and the availability of suitable cooling water flow in the cooling water line can be improved.

According to a further preferred embodiment of the invention, it is provided that no adjustment flap is provided between the pump and the condenser, in particular at the outlet of the feed pump. An embodiment adjustment flap would typically be hydraulically operable (see explanations above) and can also be opened or closed against the pressure of the feed pump. By avoiding the provision of an adjustment flap in the cooling water line thus costs can be saved as well as maintenance and fuse-related risks can be avoided. At this point, it should be noted that the execution adjustment flap in the sense of a butterfly valve and / or a non-return valve to be understood. In particular not included in this embodiment are closing flaps, which are associated with the capacitor.

According to a further preferred embodiment of the invention it is provided that the riser shaft has at least a minimum height of 8m and in particular has a maximum height of 30m.

According to a further advantageous embodiment of the invention, it is provided that a riser shaft at least two chutes is assigned such that when promoting cooling water through the riser the subsidized cooling water is divided on the at least two chutes. The two separate cooling water streams in the chutes can be used selectively to supply different condenser halves separately with cooling water.

Alternatively or in addition to this, it may be provided that a chute of the cooling water pipe is assigned at least two riser shafts such that when conveying Cooling water through the at least two risers the subsidized cooling water combined in a chute. With the provision of at least two risers, in particular exactly two risers, a higher redundancy factor can be achieved by providing several relatively smaller feed pumps in the risers which carry a comparable amount of cooling water as compared to possibly a larger pump in a single riser. Thus, in the event of failure of a feed pump, the entire cooling water supply system can continue to be maintained via the cooling water line, since the remaining feed pumps in the other riser shafts continue to convey cooling water into the common chute. Since the cooling water from the various risers is combined in a chute, no further precautions, such as the opening and closing of adjustment flaps, are required. This achieves an advantageously available system, which can dispense with active shut-off and allows a desired redundancy in the cooling water pump.

According to a further preferred embodiment of the cooling water pipe according to the invention it is provided that the at least one riser and / or chute comprises a tube comprising a glass fiber reinforced plastic or other composite material. Since these composite materials can be relatively easily manufactured and prefabricated, a riser and / or chute can be built in a short construction time. In addition, such pipes can be produced very inexpensively, so that there is an economic advantage.

Alternatively or additionally, it may be provided that the at least one chute and / or riser comprises a reinforced concrete structure. Even such structures can be made without relatively large construction effort, without causing high costs. Because in the course of building a power plant reinforced concrete structures anyway can be built in many places, the provision of a chute and / or riser shaft from just this material can be provided very economically and without further logistical precautions.

According to a particularly preferred embodiment of the invention it is provided that the at least one riser has a closable branch, in particular upstream of the feed pump, via which branch cooling water can be removed for the purpose of draining. Since during operation the cooling water is increasingly enriched with salts, it is necessary to replace this. For this purpose, the riser shaft targeted a portion of cooling water can be removed for draining via a corresponding branch, which is elsewhere replaced by fresh cooling water. The branch is, for example, closed by a suitable valve.

Furthermore, according to another embodiment, it can be provided that the at least one chute has a closable feed, via which chemical substances can be added to the cooling water for chemical treatment. Since in the chute sometimes a more turbulent flow prevails than in the downstream cooling water pipe areas, at this point of the chute added chemical substances can be particularly well mixed into the cooling water. In addition, the supply may be arranged at a location of the chute, which does not require the supply of chemical substances under elevated pressure. Addition of the chemicals at pressures slightly higher than the ambient pressure is possible.

According to another embodiment of the cooling water pipe is provided that a plurality of riser shafts is provided with each downstream arranged chutes and respectively associated feed pumps, wherein the plurality of chutes opens into a common inlet into the cooling water pipe. The majority of riser shafts also become typical supplied with cooling water through a common connection area according to a further embodiment of the cooling water line. Consequently, even in case of failure of feed pumps in a single riser further cooling water in the associated other chutes are promoted, but due to the common inlet, a merger of the cooling water of the different chutes is done, so that a mixture and supply of these amounts of cooling water via the inlet into the cooling water pipe can be easily achieved.

The invention will be explained in more detail below with reference to individual figures. It should be noted that the figures are to be understood only schematically and not limit the feasibility of the invention.

It should also be noted that the components in the following figures, which are provided with the same reference numerals, should have the same technical effects.

Furthermore, it should be noted that the technical features shown below should be claimed in any combination with each other, as far as they can solve the problems underlying the invention.

Figur 1

eine erste Ausführungsform der erfindungsgemäßen Kühlwasserleitung in schematischer Schnittansicht von der Seite;

Figur 2

eine weitere Ausführungsform der erfindungsgemäßen Kühlwasserleitung in schematischer Schnittansicht von der Seite (inkl. Abschlämm- und Chemikaliendosierungsanschluss);

Figur 3

eine darüber hinaus gehende Ausführungsform der erfindungsgemäßen Kühlwasserleitung in einer seitlichen schematischen Schnittansicht;

Figur 4

eine Querschnittsansicht durch Steigschacht und Fallschacht entsprechend einer besonders bevorzugten Ausführungsform der erfindungsgemäßen Kühlwasserleitung;

Figur 5

eine Querschnittsansicht durch Steigschacht und Fallschacht entsprechend einer anderen besonders bevorzugten Ausführungsform der erfindungsgemäßen Kühlwasserleitung;

Figur 6

eine weitere Ausführungsform der erfindungsgemäßen Kühlwasserleitung in einer schematischen Schnittansicht von einer Seite.

Hereby show:

FIG. 1

a first embodiment of the cooling water pipe according to the invention in a schematic sectional view from the side;

FIG. 2

a further embodiment of the cooling water pipe according to the invention in a schematic sectional view from the side (including Abschlämm- and chemical dosing port);

FIG. 3

a further embodiment of the inventive cooling water pipe in a lateral schematic sectional view;

FIG. 4

a cross-sectional view through riser and chute according to a particularly preferred embodiment of the cooling water pipe according to the invention;

FIG. 5

a cross-sectional view through riser and chute according to another particularly preferred embodiment of the cooling water pipe according to the invention;

FIG. 6

a further embodiment of the cooling water pipe according to the invention in a schematic sectional view from one side.

FIG. 1 shows a side sectional view through a first embodiment of the inventive cooling water pipe 1, which may be about from a steam part comprehensive power plant (not shown in the present case) may be included. The cooling water line 1 comprises a riser shaft 10, which is associated with a chute 11, wherein in the base region of the riser shaft 10, a feed pump 12 is arranged. The system of riser shaft 10, chute 11 and feed pump 12 are fluidly connected in the cooling water line such that the cooling water 5 is supplied via a cooling water inlet 3 to the riser 10 initially. When transferring the exiting the riser water into the chute 11 this flows geodetically into the chute 11 via a cooling water drain 4 to the condenser 2 and then continue via a cooling water discharge 13 back to the cooling tower (not shown). The condenser 2 is used in accordance with the provision to supply the steam part of a not further provided with reference numerals power plant with cooling power.

During the continuous continuous operation, the feed pump 12 promotes cooling water 5 such that it is continuous is transferred to the chute 11 at the upper limit of the riser shaft 10. Due to the height conditions or pressure loss ratios in the cooling water pipe 1, a substantially constant level in the chute 11 settles in the course of operation of the cooling water pipe 1. This is sufficient to build up a static pressure in the base region of the chute 11, so that the cooling water located there in the cooling water line 1 can be transported further in the direction of the condenser 2 and to these subsequent systems or system sections.

Should a malfunction of the feed pump 12 occur, and they can no longer afford their conveying work, the filling level in the riser 10 drops, so that no further cooling water 5 is transferred into the chute 11. The thereby changing pressure conditions in the riser 10 can cause the feed pump 12 sometimes transmits pressure fluctuations on the cooling water column in the riser. However, these are not transmitted to the water column in the chute, and therefore can not propagate towards the condenser. In this respect, the feed pump 12 is decoupled from the condenser 2.

If the feed pump can then again transport cooling water 5 into the riser shaft 10 after renewed operation, the fill level in the riser shaft 10 rises again until it reaches the upper limit of the riser shaft 10, after which it is transferred into the chute 11. If, during this starting process, the feed pump 12 again transfers pressure fluctuations to the cooling water column in the riser 10 due to the changing pressure conditions, these pressure changes or pressure surges can also not be transferred to the condenser 2 or only greatly reduced.

FIG. 2 shows a further embodiment of the cooling water pipe 1 according to the invention in a schematic sectional view of the side, wherein the embodiment shown differs from the in FIG. 1 shown embodiment differs only in that in the riser 10, a branch 15 is provided, via which cooling water 5 can be removed for the purpose of drainage. The branch 15 may in this case be provided with a valve not shown, which designed the branch 15 closable.

Next, the in FIG. 2 shown embodiment of the cooling water pipe 1, a feed 16, which is also designed to be closed via a valve not shown. In particular, chemical substances can be introduced into the cooling water 5 via the supply 16 so that a mixture of both liquids or substances can take place in the region of the chute 11.

FIG. 3 shows a further embodiment of the cooling water pipe 1 according to the invention in a lateral sectional view, which differs from the in FIG. 1 shown embodiment differs in that the arrangement of riser 10 to chute 11 has a different geometry. Is at the in FIG. 1 shown embodiment of the riser 10 provided centrally in the chute 11 and substantially without contact of the respective walls is in the in FIG. 3 shown embodiment, a portion of the wall of the riser 10 with a portion of the inner wall of the chute 11 in contact. Preferably, the riser 10 may be designed as a plurality of risers 10. Also, most preferably, the chute 11 may be configured as a plurality of chutes 11. Such embodiments are described below.

FIG. 4 shows a cross-sectional view through an embodiment of the inventive cooling water pipe 1 as in FIG. 3 is shown. Here, the cross section shown in FIG FIG. 4 on the IV-IV designated cutting plane in FIG. 3 , As can be clearly seen, the embodiment has only one riser 10, wherein the riser 10 are assigned two juxtaposed separated chutes 11. When cooling water emerges in the region of the upper boundary of the riser shaft 10, the cooling water is split between the two gravity wells 11 and can be removed separately. Thus, for example, the capacitor 2 not shown can be supplied via two separate streams with cooling water.

FIG. 5 shows an embodiment according to FIG. 4 Alternative embodiment of the arrangement of riser 10 and chute 11. In accordance with the present invention, two separate risers 10 are provided which share a lateral wall. The overflowing from the riser shafts 10 in the upper region of the boundary cooling water flows into the common chute 11 a. Consequently, the mixed from the two risers 10 in the chute 11 mixed cooling water. An advantage of such an embodiment, the provision of a possible redundancy of feed pumps, which are associated with the riser shafts 10, since in case of failure of a feed pump, a riser 10 can be taken out of service, but without having to interrupt the operation of the entire cooling water pipe 1.

FIG. 6 shows a side sectional view of another possible embodiment of the invention, which in addition to two risers 10 (dashed lines) each have a chute 11 associated therewith. However, the two chutes 11 have a common inlet 20, via which the discharged into the chutes 11 cooling water 5 can be mixed, about about the cooling water discharge 4 (frontal view) to the capacitor 2 (not shown here) to be dissipated.

Further embodiments emerge from the subclaims.

Claims (10)

Cooling water line (1) for a power plant, which is connected to a condenser (2), and wherein in normal operation upstream of the condenser (2) comprises a riser shaft (10) with respect to downstream arranged chute (11), as well as a Feed pump (12) which is arranged such that in the riser shaft (10) or upstream of the riser shaft (10) in the cooling water line (1) cooling water (5) can be acted upon by a flow. Cooling water line (1) according to claim 1,
characterized in that
the feed pump (12) is designed as a shaft pump, which is arranged in particular in the riser shaft (10). Cooling water line (1) according to one of the preceding claims,
characterized in that
between the feed pump (12) and the condenser (2), in particular at the outlet of the feed pump (12) no adjustment flap is provided. Cooling water line (1) according to one of the preceding claims,
characterized in that
a riser shaft (10) at least two chutes (11) is assigned such that when pumping cooling water through the riser shaft (10) the subsidized cooling water is divided on the at least two chutes (11). Cooling water line (1) according to one of the preceding claims,
characterized in that
a chute (11) is associated with at least two riser shafts (10) in such a way that when cooling water (5) is conveyed by the at least two riser shafts (10) the subsidized cooling water (5) in the one chute (11) united. Cooling water line (1) according to one of the preceding claims,
characterized in that
the at least one riser (10) and / or chute (11) comprises a tube comprising a glass fiber reinforced plastic or other composite material. Cooling water line (1) according to one of the preceding claims,
characterized in that
the at least one chute (11) and / or riser (10) comprises a reinforced concrete structure. Cooling water line (1) according to one of the preceding claims,
characterized in that
the at least one riser shaft (10) has a closable branch (15), in particular upstream of the feed pump (12), via which cooling water (5) can be removed for the purpose of bleeding. Cooling water line (1) according to one of the preceding claims,
characterized in that
the at least one chute (10) has a closable feed (16), via which chemical substances can be added to the cooling water (5) for chemical treatment. Power plant comprising a cooling water pipe (1) according to one of the preceding claims.

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