CN211611422U - Circular anti-freezing system for molten iron fire-fighting ring pipe - Google Patents

Abstract

The utility model relates to a subway fire control technical field provides a subway water fire control ring canal circulation system of preventing frostbite, including former fire-fighting pipeline, still including add in former fire-fighting pipeline easily freeze section department and with the bypass branch pipe of section intercommunication easily freezes, do provide the feed arrangement at frostproofing water source in the bypass branch pipe, and control the bypass branch pipe with the water valve component of the break-make of section easily freezes, the bypass branch pipe with the section of easily freezing forms circulation flow path. The utility model discloses a ground molten iron fire control ring canal circulation anti-freezing system can not change the subway fire control through addding the bypass branch pipe and adopt wet-type system, also does not change the characteristic that the fire-fighting pipeline becomes the looped netowrk, consequently does not influence normal work and reliability of subway fire hydrant system, has also saved cost, easy to carry out moreover.

Description

Circular anti-freezing system for molten iron fire-fighting ring pipe

Technical Field

The utility model relates to a subway fire control technical field specifically is a molten iron fire control ring canal circulation anti-freezing system.

Background

Underground rail transit engineering is an important public place with extremely high fire protection requirements, and a fire protection system must be guaranteed to normally operate at any time.

In winter, when the environmental temperature is low, if anti-freezing measures are not taken, the fire-fighting pipeline has the risk of being frozen; once the fire-fighting pipeline is frozen, the fire hydrant system cannot be normally used in a fire disaster, and great hidden danger is brought to subway safety.

The anti-freezing measures of the traditional fire fighting pipeline comprise the following steps:

(1) the dry fire hydrant system is characterized in that liquid in a pipeline is emptied after a dry alarm valve, a deluge valve or a quick opening and closing device such as an electromagnetic valve and an electric valve and the like are arranged on a water supply main pipe of the system, so that the liquid is prevented from being frozen when the outside air temperature is low; when in fire, the exhaust valve exhausts the air in the pipeline, the fire-fighting pipe network is quickly filled with water, and in order to ensure that the fire hydrant system can play a role in time during the fire, the water filling time is required to be not more than 5min according to the standard. The Tianjin No. 2 and No. 3 lines adopt a dry fire hydrant system in the interval tunnel, a wet system is still adopted in the station, and a quick opening and closing valve is arranged at the position where the station is connected with the interval. The main drawbacks of this system compared to a wet system are: in case of fire, the system is converted into a wet system, which requires a certain water filling time, resulting in a time lag in using the hydrant system compared to the wet system. Meanwhile, the exhaust valve is likely to be blocked, air in the fire fighting pipeline cannot be effectively discharged during water filling, and phenomena of water flow interruption, unstable holding and aerial fog of a pipeline water outlet plug port can be caused; and the water hammer causes damage to the pipeline joint. Thirdly, when water flow is filled into the low-temperature pipeline, the freezing risk still exists. Therefore, the anti-freezing measure of the dry fire hydrant system is less adopted in the subway projects at home and abroad.

(2) The heat preservation of the heat insulating material refers to that the heat insulating material is wound outside the fire fighting pipeline, so that the heat exchange thermal resistance between cold air and liquid in the fire fighting pipeline is increased, and the falling speed of the temperature of the liquid in the pipeline is reduced. The heat insulation material is adopted for heat insulation, so that the heat dissipation can be delayed, and the liquid in the fire fighting pipeline can be frozen finally in the areas like Harbin in continuous cold weather. Therefore, the heat insulation material is adopted for heat preservation and is often used as an auxiliary measure for preventing the water pipe from freezing in hot summer, cold winter areas.

(3) The antifreezing agent is added, and the antifreezing agent has the function of lowering the freezing point of water, so that the cold resistance of the fire hydrant system is improved. The glycol can be mixed with water in any proportion, is the most common antifreeze, and when the antifreeze is prepared by mixing 40% of glycol and 60% of soft water, the freezing point is-25 ℃; when the proportion of ethylene glycol and water in the antifreeze is 50 percent respectively, the freezing point is-35 ℃. The antifreezing agent is added, so that the antifreezing protection effect can be achieved, but due to the water leakage of the pipe network and the requirement of frequent inspection, ethylene glycol needs to be continuously supplemented into the pipe network, the concentration control of the ethylene glycol is difficult, and the environmental pollution is caused during the use. Therefore, the method of adding the antifreeze agent is less adopted in subway engineering.

(4) The electric tracing heat preservation is that heat is generated through a heating cable, so that heat dissipation compensation is carried out on the fire fighting pipeline, an anti-freezing protection effect is achieved, and the electric tracing heat preservation is a relatively effective anti-freezing measure. The subway fire-fighting pipeline in northern cities in China generally adopts a mode of combining electric tracing heat preservation and heat preservation by heat insulation materials. Meanwhile, the electric tracing system also has the following problems: firstly, the maintenance is difficult, the electric heat tracing heat preservation system winds heating cables on pipelines, and each heat tracing pipeline is provided with a temperature sensor. Because the temperature sensor and the heating cable are coated in the heat insulation material, if the temperature sensor is connected with a wire and the heating cable is broken, the broken position cannot be accurately determined, and the difficulty is increased for maintenance; the reliability of the control system is poor, the electric heat tracing heat preservation system is provided with an automatic control and accident alarm system, the temperature of the pipeline is monitored in real time through a temperature sensor, and the control system of the heating cable is invalid due to the fact that the temperature sensor is likely to be disconnected in wiring and the disconnection position is difficult to find, and temperature feedback signals are distorted, even the heating cable always heats, and the danger of fire disaster due to overhigh temperature exists; the engineering investment is large, the initial investment of the electric heat tracing heat preservation engineering is large, the power supply distance of power distribution is long, and the requirement on the engineering implementation quality is high; the service life of a common heating cable is 8 years, the original electric tracing heat insulation system needs to be modified after the heating cable reaches the service life or fails, the heating cable and the heat insulation material need to be comprehensively replaced at the moment, and the engineering quantity is large.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a ground molten iron fire control ring canal circulation anti-freezing system can solve partial defect among the prior art at least.

In order to achieve the above object, the embodiment of the present invention provides the following technical solutions: the circulating anti-freezing system for the firefighting ring pipe of the molten iron comprises an original firefighting pipe, a bypass branch pipe, a supply device and a water valve assembly, wherein the bypass branch pipe is additionally arranged at an easy-freezing section of the original firefighting pipe and is communicated with the easy-freezing section, the supply device is used for providing an anti-freezing water source for the bypass branch pipe, the water valve assembly is used for controlling the on-off of the bypass branch pipe and the easy-freezing section, and the bypass branch pipe and the easy-freezing section form a circulating flow path.

Further, the supply device comprises a hot water storage tank communicated with the bypass branch pipe and a circulating water pump arranged on the bypass branch pipe.

Further, the water valve assembly comprises a first electric water valve arranged on the bypass branch pipe and a flow path of the freezing-prone section.

Furthermore, the water valve component also comprises a second electric water valve which is arranged on the easy-freezing section and the flow path of other pipe bodies of the original fire fighting pipeline.

The water valve assembly is characterized by further comprising a control cabinet, wherein the control cabinet is provided with a water valve control unit for controlling the work of the water valve assembly and a circulation control unit for controlling a circulation process.

Further, the heat source unit is used for providing heat compensation for the supply device.

Further, the control cabinet is also provided with a heat source control unit for controlling the work of the heat source unit.

Further, a first temperature sensor for monitoring the temperature of the antifreeze water source of the supply device is included.

Further, a second temperature sensor for monitoring the temperature in the pipe of the easy freezing section is further included.

Furthermore, the bypass branch pipe is coated with a heat insulation material.

Compared with the prior art, the beneficial effects of the utility model are that:

1. by additionally arranging the bypass branch pipe, a wet system adopted for subway fire protection is not changed, and the characteristic of a fire protection pipeline looped network is not changed, so that the normal work and the reliability of a subway fire hydrant system are not influenced, the cost is saved, and the implementation is easy.

2. The device has no hidden equipment, is convenient to overhaul, and is convenient to transform after the equipment reaches the service life or breaks down.

3. The mode that adopts the water source directly replaces or the water source in the easy freezing section of neutralization, compares in the mode through carrying out the heat transfer to liquid, and is more direct, quick, especially to the sudden climate condition, and it is effectual to prevent frostbite, does not need heating cable, has reduced the investment, has also reduced the risk of electric wire conflagration.

4. The water source is easy to heat, so that the mode of providing the heat source is not limited any more, the heat source is more flexible, the waste heat or the waste heat can be fully utilized as the heat source for places with waste heat or waste heat, the heat of equipment heating of a subway equipment area can be recovered by utilizing an air conditioning system, and the heat recovery system is energy-saving and environment-friendly.

5. A temperature sensor is adopted to monitor the temperature in the pipe of the easy freezing section, and the control action can be carried out by matching with a control cabinet; similarly, the temperature sensor is adopted to monitor the temperature of the anti-freezing water source of the supply device, and the heat compensation can be provided by matching with the heat source unit. The system is more intelligent by adopting the control cabinet, the temperature sensor and the heat source unit, and the automation degree is improved.

Drawings

Fig. 1 is a schematic diagram of a circulating anti-freezing system for a fire-fighting ring pipe of molten iron provided by an embodiment of the present invention;

fig. 2 is a flowchart illustrating steps of a circular anti-freezing method for a fire-fighting ring pipe of molten iron according to an embodiment of the present invention;

in the reference symbols: 1-original fire-fighting pipeline; 2-a bypass branch pipe; 3-a first service water valve; 4-a first temperature sensor; 5-a heat storage water tank; 6-circulating water pump; 7-a second temperature sensor; 8-a first electrically operated water valve; 9-a second service water valve; 10-a heat source unit; 11-a second electrically operated water valve; 12-a thermal insulation material; 13-power supply air switch; 14-a first electric water valve control module; 15-a second electric water valve control module; 16-a circulating water pump control module; 17-a power system control module; 18-a first electrically operated water valve actuator; 19-a second electrically operated water valve actuator; 20-circulating water pump actuator; 21-power supply system actuator; 22-a control cabinet; an X-easy freezing section.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

Referring to fig. 1, an embodiment of the present invention provides a circulating anti-freezing system for a fire-fighting ring pipe of molten iron, which includes an original fire-fighting pipeline 1, a bypass branch pipe 2, a supply device, and a water valve assembly. The bypass branch pipe 2 is additionally arranged at the easy freezing section X of the original fire fighting pipeline 1 and is communicated with the easy freezing section X, the supply device provides an anti-freezing water source for the bypass branch pipe 2, and the bypass branch pipe 2 is communicated with the easy freezing section X, so that the anti-freezing water source also flows into the easy freezing section X after the bypass branch pipe 2 is controlled to be communicated with the easy freezing section X through the water valve assembly, and the situation of freezing in the easy freezing section X is prevented. The selection of the easy freezing section X can be obtained according to common experience or measured by an instrument, and in actual operation, if the easy freezing section X has a plurality of sections, if the sections are adjacent, because the easy freezing section X is originally taken from the original fire fighting pipeline 1 and is the same pipeline, the sections can be considered to be connected into a whole to be additionally provided with the bypass branch pipe 2, namely, the head end of the first easy freezing section X is taken as the head end of the bypass branch pipe 2, the tail end of the last easy freezing section X is taken as the tail end of the bypass branch pipe 2, and if the intervals of the easy freezing sections X are larger, a plurality of sets of the parts can be considered, and the bypass branch pipe 2, the supply device and the water valve assembly are considered as one set of parts. The bypass branch pipe 2 and the freezing-prone section X form a circulating flow path, so that the provided anti-freezing water source can completely replace cold water in the freezing-prone section X or neutralize the cold water more uniformly, the temperature of the water in the moving connection section is effectively increased, and the water is prevented from freezing. The source of anti-freeze water may be hot water, principally above zero degrees centigrade, but considering the need for neutralization, higher temperature hot water is often used as the anti-freeze water source. In order to control whether an anti-freezing water source needs to be provided for the easy-freezing section X for anti-freezing treatment according to requirements, a water valve assembly can be arranged to control the on-off condition of the bypass branch pipe 2 and the easy-freezing section X, the anti-freezing water source is provided when the bypass branch pipe is switched on, and the anti-freezing water source is not provided when the bypass branch pipe is switched off. The original fire fighting pipeline 1 can be connected with a fire pump room or other fire fighting ring pipe networks, and in addition, a certain fire fighting ring pipe network is connected at the easy freezing section X, which are indicated by and indicated in a block in figure 1. So far, this embodiment not only can not change the subway fire control and adopt wet-type system, also does not change the characteristic that the fire-fighting pipeline becomes the looped netowrk, consequently does not influence the normal work of subway fire hydrant system and reliability, has also saved cost, easy to carry out moreover, does not have any hidden equipment moreover, and it is convenient to overhaul, and after equipment reached life or broke down, it is convenient to reform transform. In addition, the water source mode is adopted to directly replace or neutralize the water source in the easy freezing section X, compared with the mode of carrying out heat transfer on liquid, the method is more direct and rapid, particularly has good anti-freezing effect on sudden climate conditions, does not need heating cables, reduces investment, also reduces the risk of electric wire fire, and because the water source is easy to be heated, the mode of providing the heat source is not limited any more and is more flexible, and for places with waste heat or waste heat, the waste heat or waste heat can be fully utilized as the heat source, and an air conditioning system can also be utilized to carry out heat recovery on equipment heating quantity in a subway equipment area, thereby saving energy and protecting environment.

As an optimization scheme of the embodiment of the present invention, please refer to fig. 1, the supply device includes a hot water storage tank 5 connected to the bypass branch pipe 2 and a circulating water pump 6 disposed on the bypass branch pipe 2. In the embodiment, the antifreezing water source is provided by the heat storage water tank 5, hot water is stored in the heat storage water tank 5 at any time, and the hot water can be timely supplied when the movable segment needs to be subjected to antifreezing treatment. The circulating water pump 6 is adopted to circulate the anti-freezing water source in the bypass branch pipe 2 and the cold water in the easy freezing section X.

As an optimized scheme of the embodiment of the present invention, please refer to fig. 1, the water valve assembly includes a first electrically operated water valve 8 disposed on the bypass branch pipe 2 and the flow path of the easy-to-freeze section X. In the embodiment, the electric water valve is used for controlling the conduction of the bypass branch pipe 2 and the easy freezing section X, the electric water valve is easy to control, and automatic control can be realized.

In order to further optimize the above scheme, please refer to fig. 1, the water valve assembly further includes a second electrically operated water valve 11 disposed on the flow path between the easy-freezing section X and the other pipe bodies of the original fire fighting pipeline 1. In this embodiment, the second electrically operated water valve 11 may be closed after the first electrically operated water valve 8 is opened, so as to block the easy-freezing section X from communicating with other pipe bodies of the original fire fighting pipeline 1, and thus the bypass branch pipe 2 may directly act on the easy-freezing section X to achieve targeted anti-freezing.

As an optimization scheme of the embodiment of the present invention, please refer to fig. 1, the system further includes a control cabinet 22, and the control cabinet 22 has a water valve control unit for controlling the operation of the water valve assembly and a circulation control unit for controlling the circulation process. In this embodiment, the control cabinet 22 functions as a control to improve the degree of automation. Preferably, the water valve control unit comprises a first electrically operated water valve control module 14 and a first electrically operated water valve actuator 18, when the power supply air switch 13 in the control cabinet 22 is opened, the first electrically operated water valve control module 14 controls the opening of the first electrically operated water valve 8 through the first electrically operated water valve actuator 18, and the water valve control unit further comprises a second electrically operated water valve control module 15 and a second electrically operated water valve actuator 19, which can control the opening and closing of the second electrically operated water valve 11. And the circulation control unit comprises a circulation water pump control module 16 and a circulation water pump actuator 20, which cooperate to control the circulation water pump 6 to be started, and a certain delay, for example, 1 minute, may be set in the interval between the electric water valve and the circulation water pump 6 to ensure that the electric water valve completes the operation.

To further optimize the above solution, referring to fig. 1, the system further includes a heat source unit 10 for providing thermal compensation for the supply device. In this embodiment, the heat source unit 10 is used to provide thermal compensation for the supply device, that is, after the temperature of the anti-freezing water source is reduced, the anti-freezing water source is heated by using the heat source unit 10, and the heating manner is various, for example, electric heating, or reasonably using waste heat and waste heat generated in other processes, or heat recovery of equipment heating value of the subway equipment area by an air conditioning system, and the like are feasible thermal compensation manners.

To further optimize the above solution, referring to fig. 1, the control cabinet 22 further has a heat source control unit for controlling the operation of the heat source unit 10. In this embodiment, the control cabinet 22 may also control the heat source unit 10, specifically, the heat source control unit includes a power supply system control module 17 and a power supply system actuator 21, and the control is completed by cooperation of the two modules. The above mentioned modules may each include preset control logic, that is, when the condition occurs, the corresponding actuator is controlled to act to control the corresponding device, and such logic control is a common control manner in the art, and how to control is not described in detail here.

As an optimization scheme of the embodiment of the present invention, please refer to fig. 1, the system further includes a first temperature sensor 4 for monitoring the temperature of the anti-freezing water source of the supply device. And a second temperature sensor 7 for monitoring the temperature in the tube of the easy freezing section X. What is mentioned in the above embodiments is that the temperature is monitored by the temperature sensor in the present embodiment when the temperature reaches a certain value, on one hand, an intuitive indication can be given, and on the other hand, automatic control can be performed in cooperation with the control cabinet 22. Therefore, the control cabinet 22, the temperature sensor and the heat source unit 10 are adopted, so that the system is more intelligent, and the automation degree is improved. For example, when the temperature signal fed back by the second temperature sensor 7 is lower than a certain value (for example, 5 ℃), the antifreeze system starts to operate. The power supply air switch 13 in the control cabinet 22 is turned on, the first electric water valve control module 14 controls the first electric water valve 8 to be turned on through the first electric water valve actuator 18, the second electric water valve control module 15 controls the second electric water valve 11 to be turned off through the second electric water valve actuator 19, after delaying for example 1 minute, the circulating water pump control module 16 controls the circulating water pump 6 to be turned on through the circulating water pump actuator 20, the power supply system control module 17 controls the power supply system to be turned on through the power supply system actuator 21, and the initial thermal compensation amount is set to be a certain value (for example, 50% of the maximum value). When the temperature signal fed back by the second temperature sensor 7 is higher than a certain value (for example, 10 ℃), the anti-freezing system stops working. The power supply system control module 17 controls the power supply system to be closed through the power supply system actuator 21, the circulating water pump control module 16 controls the circulating water pump 6 to be closed through the circulating water pump actuator 20, after delaying for 1 minute for example, the first electric water valve control module 14 controls the first electric water valve 8 to be closed through the first electric water valve actuator 18, the second electric water valve control module 15 controls the second electric water valve 11 to be opened through the second electric water valve actuator 19, and the power supply air switch 13 in the control cabinet 22 is closed. In operation, when the temperature signal fed back by the first temperature sensor 4 is lower than a certain value (for example, 12 ℃), the power system control module 17 controls the heat source system to increase a certain amount of thermal compensation (for example, 10% of the maximum value) to the maximum value through the power system actuator 21. In operation, when the temperature signal fed back by the first temperature sensor 4 is higher than a certain value (for example, 15 ℃), the power system control module 17 controls the heat source system to reduce a certain amount of thermal compensation (for example, 10% of the maximum value) through the power system actuator 21 until the heat source system is turned off.

As an optimized scheme of the embodiment of the present invention, please refer to fig. 1, the bypass branch pipe 2 is coated with a thermal insulation material 12 with a certain thickness, so as to alleviate heat dissipation.

As an optimization scheme of the embodiment of the present invention, please refer to fig. 1, the system further comprises an inspection water valve, which can inspect the pipeline. The number of the maintenance water valves is two, namely a first maintenance water valve 3 and a second maintenance water valve 9, and the first maintenance water valve 3 and the second maintenance water valve 9 are arranged at two ends of the heat storage water tank 5 respectively.

Referring to fig. 2, an embodiment of the present invention provides a circulating anti-freezing method for a fire-fighting ring pipe of molten iron, including the following steps:

s1, searching an easily frozen section X of the original fire fighting pipeline 1;

s2, communicating a bypass branch pipe 2 on the easy freezing section X, and controlling the connection and disconnection of the bypass branch pipe 2 and the easy freezing section X by adopting a water valve component;

s3, connecting a supply device which can provide an anti-freezing water source on the bypass branch pipe 2;

and S4, controlling the operation of the water valve assembly according to the temperature in the pipe body of the easy-freezing section X, and selecting whether to enable an anti-freezing water source to flow into the easy-freezing section X or not so as to enable the anti-freezing water source to circularly flow in the bypass branch pipe 2 and the easy-freezing section X or not.

In this embodiment, the bypass branch pipe 2 is additionally arranged at the easy-freezing section X of the original fire fighting pipeline 1 and is communicated with the easy-freezing section X, the supply device provides an anti-freezing water source for the bypass branch pipe 2, and because the bypass branch pipe 2 is communicated with the easy-freezing section X, when the bypass branch pipe 2 is controlled to be communicated with the easy-freezing section X through the water valve assembly, the anti-freezing water source also flows into the easy-freezing section X, so that the situation that the interior of the easy-freezing section X is frozen is prevented. The selection of the easy freezing section X can be obtained according to common experience or measured by an instrument, and in actual operation, if the easy freezing section X has a plurality of sections, if the sections are adjacent, because the easy freezing section X is originally taken from the original fire fighting pipeline 1 and is the same pipeline, the sections can be considered to be connected into a whole to be additionally provided with the bypass branch pipe 2, namely, the head end of the first easy freezing section X is taken as the head end of the bypass branch pipe 2, the tail end of the last easy freezing section X is taken as the tail end of the bypass branch pipe 2, and if the intervals of the easy freezing sections X are larger, a plurality of sets of the parts can be considered, and the bypass branch pipe 2, the supply device and the water valve assembly are considered as one set of parts. The bypass branch pipe 2 and the freezing-prone section X form a circulating flow path, so that the provided anti-freezing water source can completely replace cold water in the freezing-prone section X or neutralize the cold water more uniformly, the temperature of the water in the moving connection section is effectively increased, and the water is prevented from freezing. The source of anti-freeze water may be hot water, principally above zero degrees centigrade, but considering the need for neutralization, higher temperature hot water is often used as the anti-freeze water source. In order to control whether an anti-freezing water source needs to be provided for the easy-freezing section X for anti-freezing treatment according to requirements, a water valve assembly can be arranged to control the on-off condition of the bypass branch pipe 2 and the easy-freezing section X, the anti-freezing water source is provided when the bypass branch pipe is switched on, and the anti-freezing water source is not provided when the bypass branch pipe is switched off. So far, this embodiment not only can not change the subway fire control and adopt wet-type system, also does not change the characteristic that the fire-fighting pipeline becomes the looped netowrk, consequently does not influence the normal work of subway fire hydrant system and reliability, has also saved cost, easy to carry out moreover, does not have any hidden equipment moreover, and it is convenient to overhaul, and after equipment reached life or broke down, it is convenient to reform transform. In addition, the water source mode is adopted to directly replace or neutralize the water source in the easy freezing section X, compared with the mode of carrying out heat transfer on liquid, the method is more direct and rapid, particularly has good anti-freezing effect on sudden climate conditions, does not need heating cables, reduces investment, also reduces the risk of electric wire fire, and because the water source is easy to be heated, the mode of providing the heat source is not limited any more and is more flexible, and for places with waste heat or waste heat, the waste heat or waste heat can be fully utilized as the heat source, and an air conditioning system can also be utilized to carry out heat recovery on equipment heating quantity in a subway equipment area, thereby saving energy and protecting environment.

As for other steps, please refer to the content of the first embodiment, which will not be described in detail herein.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (10)

1. The utility model provides a ground molten iron fire control ring canal circulation anti-freezing system, includes former fire-fighting pipeline, its characterized in that:

also comprises a bypass branch pipe which is additionally arranged at the easy freezing section of the original fire fighting pipeline and is communicated with the easy freezing section,

a supply device for providing an anti-freezing water source in the bypass branch pipe,

and a water valve component for controlling the on-off of the bypass branch pipe and the easy freezing section,

the bypass branch pipe and the freezing-prone section form a circulating flow path.

2. The subway water fire-fighting loop circulation anti-freezing system as claimed in claim 1, wherein: the supply device comprises a heat storage water tank communicated with the bypass branch pipe and a circulating water pump arranged on the bypass branch pipe.

3. The subway water fire-fighting loop circulation anti-freezing system as claimed in claim 1, wherein: the water valve assembly comprises a first electric water valve arranged on the flow path of the bypass branch pipe and the easy freezing section.

4. The subway water fire-fighting loop circulation anti-freezing system as claimed in claim 3, wherein: the water valve component further comprises a second electric water valve which is arranged on the flow path of the easy-freezing section and the flow path of other pipe bodies of the original fire fighting pipeline.

5. The subway water fire-fighting loop circulation anti-freezing system as claimed in claim 1, wherein: the water valve assembly is characterized by further comprising a control cabinet, wherein the control cabinet is provided with a water valve control unit for controlling the work of the water valve assembly and a circulation control unit for controlling a circulation process.

6. The subway water fire-fighting loop circulation anti-freezing system as claimed in claim 5, wherein: the heat source unit is used for providing heat compensation for the supply device.

7. The subway water fire-fighting loop circulation anti-freezing system as claimed in claim 6, wherein: the control cabinet is also provided with a heat source control unit for controlling the work of the heat source unit.

8. The subway water fire-fighting loop circulation anti-freezing system as claimed in claim 1, wherein: also included is a first temperature sensor for monitoring the temperature of the anti-freeze water source of the supply.

9. The subway water fire-fighting loop circulation anti-freezing system as claimed in claim 1, wherein: and a second temperature sensor for monitoring the temperature in the tube of the freezing-prone section.

10. The subway water fire-fighting loop circulation anti-freezing system as claimed in claim 1, wherein: the bypass branch pipe is coated with a heat insulation material.

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