CN211132789U - Built-in liquefied medium self-expansion type foam fire-fighting system - Google Patents

Abstract

The utility model discloses a built-in liquefied medium self-expansion type foam fire-fighting system, which comprises a foam generating device and a fire monitoring device, wherein the foam generating device comprises a foam mixed liquid storage device and a liquefied medium storage device; the foam mixing device comprises a foam mixing liquid storage device, a foam outlet, a foam liquid inlet, a liquefied gas inlet and a gas-liquid mixer, wherein the foam mixing liquid storage device is provided with a foam liquid inlet, a liquefied gas inlet and a foam outlet; the fire monitoring equipment comprises a fire detection module and a control module connected with the foam generating equipment, the control module controls the liquefied medium storage device to be communicated with the foam mixed liquid storage device during fire, and liquefied media in the liquefied medium storage device automatically enter the foam mixed liquid storage device under the action of gas pressure.

Description

Built-in liquefied medium self-expansion type foam fire-fighting system

Technical Field

The utility model relates to a technical field that puts out a fire specifically relates to a built-in liquefaction medium is from expanding type foam fire extinguishing system.

Background

The existing compressed gas foam fire extinguishing mainly adopts a mode of mixing gas and foam mixed liquid to generate foam to extinguish fire. The specific compressed gas foam fire extinguishing mode mainly comprises two modes of normal pressure compressed gas foam fire extinguishing and gas storage type foam fire extinguishing.

The normal pressure type compressed gas foam fire extinguishing generally adopts a compressor or a compressed gas steel cylinder to supply gas, the pressure is basically kept unchanged in the injection process, the gas supply quantity of the compressor and the compressed gas steel cylinder is limited, the requirement of large-flow high-pressure gas supply cannot be met, if the large-flow high-pressure gas supply is required, a plurality of compressors or compressed gas steel cylinders are required to be arranged (for example, a foam fire truck with the flow rate of 150L/S is taken as an example, the gas supply flow rate is 1050L/S, and the gas supply needs to be supplied by a plurality of large-scale air compressors), the occupied space is large, no space is arranged in an oil depot tank area and an apparatus area, and the field arrangement is not facilitated.

The other gas storage type foam fire extinguishing method is characterized in that compressed gas is stored in a fire extinguishing agent container, when the compressed gas is sprayed at a large flow, the compressed gas is consumed greatly, the spraying pressure is reduced greatly along with the continuous spraying, at the moment, in order to ensure the high-pressure spraying of the fire extinguishing agent, the compressed gas needs to be supplemented into the fire extinguishing agent container in time, under the large-flow spraying state, sufficient supplement of the compressed gas cannot be ensured by only an air compressor and a compressed gas steel cylinder, the high-pressure spraying requirement cannot be effectively realized, the fire extinguishing effect is affected, when a large-flow foam fire is extinguished, large-flow foam fire is required to be produced, at the moment, the flow of foam mixed liquid is increased, the gas supply amount of the compressed gas is increased, the existing compressed gas foam generating mode cannot realize the supply of the large-flow high-pressure compressed gas, the flow of the foam mixed liquid is only 20-30L/s, the existing compressed gas foam generating mode is mainly applied to fire extinguishing of common scale, such as building fire extinguishing, small-scale flow of ground, and the like, and cannot be applied to large-scale ground fire extinguishing.

Therefore, a new foam generating method is needed to overcome the defects of the prior art that foam fire extinguishment by compressed gas and foam fire extinguishment by gas storage are adopted.

SUMMERY OF THE UTILITY MODEL

The utility model aims at overcoming the defects that the occupied space is large, extra power is needed and the like in the mode of generating foam by compressed gas in the prior art.

In order to achieve the above object, the present invention provides a built-in liquefied medium self-expansion type foam fire fighting system, which includes a foam generating apparatus, wherein the foam generating apparatus includes a foam mixed liquid storage device for containing a foam mixed liquid and a liquefied medium storage device for containing a liquefied medium and being capable of injecting the liquefied medium into the foam mixed liquid storage device; the foam generating equipment also comprises a gas-liquid mixer with a gas-liquid mixing cavity, and a foam mixed liquid inlet, a liquefied gas inlet and a foam outlet are communicated with the gas-liquid mixing cavity;

the gas-liquid mixer is positioned in a storage chamber of the foam mixed liquid storage device, the foam mixed liquid inlet is communicated with a liquid phase of the foam mixed liquid storage device to input foam mixed liquid in the foam mixed liquid storage device into the gas-liquid mixer, the liquefied gas inlet is communicated with a gas phase space in the foam mixed liquid storage device to input liquefied gas generated by gasifying the liquefied medium in the foam mixed liquid storage device into the gas-liquid mixer, and foam generated by mixing the foam mixed liquid and the liquefied gas in the gas-liquid mixer is sprayed out from the foam outlet;

the foam fire-fighting system further comprises fire monitoring equipment, the fire monitoring equipment comprises a fire detection module and a control module connected with the foam generating equipment, the control module controls the liquefied medium storage device to be communicated with the foam mixed liquid storage device when the fire detection module detects a fire, and liquefied media in the liquefied medium storage device can automatically enter the foam mixed liquid storage device under the action of gas pressure.

Preferably, automatic control valves are respectively arranged on a pipeline between the liquefied medium storage device and the foam mixed liquid storage device and a pipeline connected with the foam outlet, and each automatic control valve is connected with the control module so that the control module controls the on-off of the automatic control valve.

Preferably, a flow control valve for controlling the flow of the liquefied medium is further arranged on a pipeline between the foam mixed liquid storage device and the liquefied medium storage device, a pressure gauge for measuring the pressure in the gas phase space is arranged on the foam mixed liquid storage device, and the flow control valve adjusts the flow according to the pressure of the pressure gauge.

Preferably, the working pressure of the foam mixed liquid storage device is 0.4-1.4 Mpa.

Preferably, the working pressure of the foam mixed liquid storage device is 0.6-1.0Mpa, and the pressure fluctuation range of the foam mixed liquid storage device is +/-0.1 Mpa.

Preferably, one liquefied medium storage device is provided, one or more foam mixed liquid storage devices are provided, the liquefied medium storage devices are respectively connected with one or more foam mixed liquid storage devices, and an automatic control valve connected with the control module is respectively arranged between the liquefied medium storage device and each foam mixed liquid storage device;

or a plurality of liquefied medium storage devices are arranged in parallel, each liquefied medium storage device is connected with one or a plurality of foam mixed liquid storage devices respectively, and an automatic control valve connected with the control module is arranged between each liquefied medium storage device and each foam mixed liquid storage device respectively.

Each foam mixed liquid storage device is correspondingly provided with one gas-liquid mixer;

preferably, the fire monitoring apparatus further comprises an alarm module for alarming when a fire is detected by the fire detection module.

Preferably, one end of the gas-liquid mixer is provided with the foam mixed liquid inlet, the other end of the gas-liquid mixer is provided with the foam outlet, and the liquefied gas inlet is arranged on the side wall between the two ends of the gas-liquid mixer.

Preferably, the liquefied gas inlet is provided with one or more, and a plurality of the liquefied gas inlets are provided at intervals in the circumferential direction of the side wall of the gas-liquid mixer.

Preferably, the relationship between the area S1 of the foam mixed liquid inlet and the area S2 of the liquefied gas inlet is: S1/S2 is 10-60;

the relationship between the area of the foam outlet S4 and the area of the foam mixture inlet S1 is: S4/S1 is 1.5-6.

Preferably, the relationship between the area S1 of the foam mixed liquid inlet and the area S2 of the liquefied gas inlet is: S1/S2 is 16-40;

the relationship between the area of the foam outlet S4 and the area of the foam mixture inlet S1 is: S4/S1 is 2.5-5.

Preferably, a flow spoiler for disturbing liquid flow is arranged in the gas-liquid mixing cavity of the gas-liquid mixer, and the liquefied gas inlet is arranged on the side wall between the flow spoiler and the foam mixed liquid inlet.

Preferably, the spoiler is formed as a cone structure, a semi-spherical structure or a platform structure;

the top of the cone structure, the top of the sphere of the hemisphere structure or the top of the platform structure face the foam mixed liquid inlet.

Preferably, the relationship between the maximum cross section S3 of the turbulator and the area S1 of the foam mix inlet is: S3/S1 is 1.1-3.8.

Preferably, the relationship between the maximum cross section S3 of the turbulator and the area S1 of the foam mix inlet is: S3/S1 is 1.4-3.

Preferably, at least one porous structure arranged at intervals is arranged in the gas-liquid mixing cavity; each porous structure is provided with a plurality of holes; the pores of the porous structure face the foam mix inlet, and the top of the turbulator is closer to the foam mix inlet than the porous structure.

The utility model provides a built-in liquefaction medium is from expanding type foam fire extinguishing system when detecting the conflagration, can realize putting out a fire automatically to need not apply extra power. Additionally, the utility model provides a technical scheme still solved among the prior art when adopting compressed gas to produce the foam occupation space big and can't effectively realize the problem that high-pressure injection required.

Drawings

Fig. 1 is a schematic structural view of a foam generating apparatus according to an embodiment of the present invention;

fig. 2 is a schematic structural view of a foam generating apparatus according to another embodiment of the present invention;

FIG. 3 is a schematic structural diagram of a gas-liquid mixer;

FIG. 4 is a schematic layout of a liquefied gas inlet of a gas-liquid mixer;

FIG. 5 is a schematic view of one configuration of a spoiler;

FIG. 6 is a schematic view of another spoiler construction;

fig. 7 is a schematic view of another spoiler structure.

Description of the reference numerals

1-a foam mixed liquor storage device; 2-a liquefied medium storage device; 3-gas-liquid mixer; 31-foam mixed liquor inlet; 32-liquefied gas inlet; 33-foam outlet; 34-a spoiler; 35-porous structure; 4-a pressure gauge; 5-a first automatic control valve; 6-second automatic control valve; 7-third automatic control valve; 8-a foam sprayer; 9-flow control valve.

Detailed Description

The following describes the embodiments of the present invention in detail. It is to be understood that the description of the embodiments herein is for purposes of illustration and explanation only and is not intended to limit the invention.

In the description of the present invention, it is to be understood that the terms "central," "upper," "lower," "vertical," "horizontal," "top," "bottom," "axial," "radial," "circumferential," "inner," "outer," and the like are used in the orientation or positional relationship indicated in the drawings, which are merely for convenience in describing the present invention and for simplicity in description, and are not intended to indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.

The utility model provides a built-in liquefied medium self-expansion type foam fire-fighting system, which comprises a foam generating device, as shown in figure 1, the foam generating device comprises a foam mixed liquid storage device 1 for containing foam mixed liquid and a liquefied medium storage device 2 for containing liquefied medium and injecting the liquefied medium into the foam mixed liquid storage device 1; the foam generating system also comprises a gas-liquid mixer 3 with a gas-liquid mixing cavity, and a foam mixed liquid inlet 31, a liquefied gas inlet 32 and a foam outlet 33 are arranged in communication with the gas-liquid mixing cavity;

wherein, the gas-liquid mixer 3 is located the storage chamber of the foam mixed liquid storage device 1, and the foam mixed liquid inlet 31 is set up to be able to communicate with the liquid phase in the foam mixed liquid storage device 1 so as to input the foam mixed liquid in the foam mixed liquid storage device 1 into the gas-liquid mixer 3, and the liquefied gas inlet 32 is set up to be able to communicate with the gas phase space in the foam mixed liquid storage device 1 so as to be used for inputting the liquefied gas generated by the gasification of the liquefied medium in the foam mixed liquid storage device 1 into the gas-liquid mixer 3, the foam mixed liquid and the foam generated by the mixing of the liquefied gas in the gas-liquid mixer 3 are sprayed out from the foam outlet 33.

The foam fire-fighting system further comprises fire monitoring equipment, the fire monitoring equipment comprises a fire monitoring module and a control module connected with the foam generating equipment, the control module controls the liquefied medium storage device 2 to be communicated with the foam mixed liquid storage device 1 when the fire monitoring module detects a fire, and liquefied media in the liquefied medium storage device 2 can automatically enter the foam mixed liquid storage device 1 under the action of gas pressure.

The technical scheme provided by the utility model, when the conflagration produced, conflagration supervisory equipment's fire detection module can detect the conflagration, for example, fire detection module can include smoke detector, heat detector and photosensitive detector etc., the conflagration information transmission of this module sensing is to control module, control module can control automatic control valve according to this information makes liquefaction medium storage device 2 that holds liquefaction media such as liquid nitrogen or liquid carbon dioxide communicate with foam mixed liquid storage device 1, thereby the liquefaction medium that stores in liquefaction medium storage device 2 gets into in foam mixed liquid storage device 1 under the promotion of gas pressure (for example pressure that liquefaction medium self gasification produced or other gas pressure), then the liquefaction medium self-expanding gasification produces gas in foam storage device 1, make the pressure in foam mixed liquid storage device 1 rise, therefore, the liquefied gas and the foam mixed liquid which are self-expanded and gasified in the foam mixed liquid storage device 1 enter the gas-liquid mixer 3 through the foam mixed liquid inlet 31 and the liquefied gas inlet 32 respectively under the pressure, so that the liquefied gas and the foam mixed liquid can be mixed and foamed in the gas-liquid mixer 3, foam is sprayed out, and fire is extinguished.

Therefore the utility model provides a foam fire extinguishing system, when detecting the conflagration, can realize extinguishing automatically, and need not apply extra power, the liquefied medium that only need set up the interior storage of liquefied medium storage device 2 when liquefied medium storage device 2 communicates with the mixed liquid storage device of foam 1 can be under the effect of gas pressure in the automatic mixed liquid storage device of entering foam 1, then the foam mixed liquid in the mixed liquid storage device of foam 1 and liquefied gas also can be under the pressure that the gasification of liquefied medium produced the automatic entering gas-liquid mixer 3 and produce the automatic fire extinguishing foam.

The utility model provides a technical scheme need be equipped with air compressor machine, compressed gas steel bottle and the occupation space who leads to is big and need the problem of power when having solved the adoption compressed gas production foam among the prior art, moreover the utility model discloses in the pressure that produces through the gasification of liquefied medium can last to impress the liquefied medium foam and mix liquid storage device 1 and produce the foam to solved and leaned on air compressor machine and compressed gas steel bottle can not guarantee compressed gas's capacity replenishment among the prior art, leaded to the unable problem that effectively realizes the high-pressure injection requirement.

The utility model provides an among the foam fire extinguishing system, fire monitoring equipment still includes alarm module, and this alarm module can report to the police when fire detection module detects the conflagration to the personnel of putting out a fire can catch up to on-the-spot manual work and participate in putting out a fire.

The utility model discloses in, the foam mixed liquid in the foam mixed storage device 1 is mixed by the foam stoste of usefulness of putting out a fire and is produced with water mixing, and the liquefaction medium of storage in the liquefaction medium storage device 2 can be at least one in liquid nitrogen, liquid carbon dioxide, liquefied inert gas, the liquefied halohydrocarbon gas. Since the foam generated by mixing the liquefied medium and the foam mixture is used for extinguishing fire, the type of gas generated by the liquefied medium is limited to gas that is helpful for extinguishing fire, i.e., gas that can suppress and suffocate fire, and does not destroy the foam itself. Generally, liquid nitrogen, which is gasified to a gas at room temperature, is used as the liquefaction medium, and thus the gas can be obtained without additional operations. The liquid nitrogen has little maintenance in the storage process, and is convenient for users to use and manage. In addition, the gasification ratio of the liquid nitrogen is 710 times that of 700-710 times, and the liquid nitrogen in unit volume can be used for foaming the foam mixed liquid by more than 10 times.

In the preferred embodiment of the present invention, as shown in fig. 1, a first automatic control valve 5 is provided on the pipeline between the liquefied medium storage means 2 and the foam mixed liquid storage means 1 and on the pipeline connected to the foam outlet 33, a second automatic control valve 6 is provided on the pipeline connected to the foam outlet 33, and each automatic control valve is connected to the control module to control the on/off of each automatic control valve by the control module, thereby controlling whether the foam generating apparatus is operated.

Specifically, in the non-ignition state, the pressure in the foam mixed liquid storage device 1 is normal, the second automatic control valve 6 of the foam outlet 33 of the gas-liquid mixer 3 is in a normally closed state, and the first automatic control valve 5 between the liquefied medium storage device 2 and the foam mixed liquid storage device 1 is in a normally closed state. Wherein the liquefied medium storage means 2 may be provided with a self-pressurization means by itself, so that the liquefied medium can be easily gasified by the self-pressurization means to enable a high pressure to be maintained in the liquefied medium storage means 2, so that when the first automatic control valve 5 is opened, there can be sufficient air pressure in the liquefied medium storage means 2 to press the liquefied medium into the foam mixed liquid storage means 1. The self-pressurization device is not the focus of the present invention, and will not be described in detail herein.

When a fire disaster is detected, the control module controls a first automatic control valve 5 between the liquefied medium storage device 2 and the foam mixed liquid storage device 1 and a second automatic control valve 6 of the foam outlet 33 to be respectively opened, the liquefied medium enters the gas phase space of the foam mixed liquid storage device 1 under the pushing of the gas pressure in the gas phase space of the liquefied medium storage device 2, and immediately gasifies, after gasification, the pressure of the gas phase space in the foam mixed liquid storage device 1 continuously rises, after rising to a preset value, the foam mixed liquid in the foam mixed liquid storage device 1 is pressed into the gas-liquid mixer 3 through the foam mixed liquid inlet 31, and the liquefied gas is pressed into the gas-liquid mixer 3 through the liquefied gas inlet 32, and the foam mixture and the liquefied gas are mixed and foamed in the gas-liquid mixer 3 and then sprayed out from the foam sprayer of the foam outlet 3. After the injection is finished, the foam mixture is refilled.

In this embodiment, as shown in fig. 1, a flow control valve 9 for controlling the flow rate of the liquefied medium is further disposed on a pipeline between the foam mixed liquid storage device 1 and the liquefied medium storage device 2, a pressure gauge 4 for measuring the pressure in the gas phase space is disposed on the foam mixed liquid storage device 1, and the flow rate of the flow control valve 9 can be adjusted according to the pressure of the pressure gauge 4, so as to ensure that the pressure in the foam mixed liquid storage device 1 is constant or fluctuates within a certain range. When fire is extinguished, in the process of injecting the liquefied medium into the foam mixed liquid storage device 1, if the pressure in the foam mixed liquid storage device 1 is higher than a predetermined value (according to the pressure gauge 4), the control unit gives an instruction to control the opening degree of the flow control valve 9 to be smaller and reduce the flow of the liquefied medium, and conversely, control the opening degree of the flow control valve 9 to be larger and increase the flow of the liquefied medium.

The flow rate of the liquefied medium injected therein depends on the size of the gas phase space of the foam mixed liquid storage apparatus 1 and the foam flow rate of the foam outlet 33. The amount of the injected liquefied medium is required to meet the requirement that the pressure in the foam mixed liquid storage device is constant or fluctuates within a preset range so as to meet the requirement of foam foaming. The flow rate of the liquefied medium can be adjusted by adjusting the opening degree of the flow rate control valve 9 by the control unit. Wherein the working pressure of the foam mixed liquid storage device 1 is preferably 0.4-1.4MPa, more preferably 0.6-1.0MPa, and the pressure fluctuation range is +/-0.1 MPa. The working pressure is the pressure in the foam mixed liquid storage device 1 when the foam generating device generates foam.

The utility model provides an easy operation of foam fire extinguishing system when putting out a fire can be by control module automatic start according to the detection of conflagration detection module, also can be after confirming the condition of a fire, by artifical manual start first automatic control valve 5 and second automatic control valve 6.

The utility model provides an among the foam production equipment, a liquefaction medium storage device 2 can be connected with the mixed liquid storage device 1 of a foam, also can be connected with the mixed liquid storage device 1 of a plurality of foams. Fig. 1 shows an embodiment in which one liquefied medium storage device 2 is connected to one foam mixture storage device 1, and fig. 2 shows an embodiment in which one liquefied medium storage device 2 is connected to a plurality of foam mixture storage devices 1.

As shown in fig. 2, one liquefied medium storage device 2 is provided, a plurality of foam mixed liquid storage devices 1 are provided, and the liquefied medium storage devices 2 are respectively connected to the plurality of foam mixed liquid storage devices 1 to supply liquefied medium to the plurality of foam mixed liquid storage devices 1; each of the foam mixture liquid storage apparatuses 1 is provided with a gas-liquid mixer 3 (the gas-liquid mixer 3 in the foam mixture liquid storage apparatus 1 is not shown in fig. 2, and the arrangement of the gas-liquid mixer in the foam mixture liquid storage apparatus 1 shown in fig. 1 may be combined). A foam sprayer 8 may be connected to the foam outlet 33 of each gas-liquid mixer 3 to facilitate the spraying of foam. Wherein, an automatic control valve connected with the control module is respectively arranged between the liquefied medium storage device 2 and each foam mixed liquid storage device 1. Specifically, the first automatic control valve 5 may be provided in the main line between the liquefied medium storage apparatus 2 and the foam mixed liquid storage apparatus 1, and the third automatic control valves 7 may be provided in the branch lines to control the flow rates of the liquefied medium to the respective foam mixed liquid storage apparatuses 1, respectively, or the third automatic control valves 7 may be provided only in the branch lines without providing the first automatic control valves 5.

In addition, a plurality of liquefied medium storage devices 2 may be provided to achieve continuous supply of liquefied medium, and the plurality of liquefied medium storage devices 2 are connected together by a confluence pipeline, and the confluence pipeline is connected with one or more foam mixed liquid storage devices 1. Similarly, each foam mixture storage device 1 is provided with a gas-liquid mixer 3. And an automatic control valve connected with the control module is arranged between each liquefied medium storage device 2 and the foam mixed liquid storage device 1.

The specific structure of the lower gas-liquid mixer 3 is described in detail below.

As shown in fig. 3, in the present embodiment, the gas-liquid mixer 3 is provided with a foam mixture inlet 31 at one end and a foam outlet 33 at the other end, and a liquefied gas inlet 32 is provided in a side wall between both ends of the gas-liquid mixer 3. Preferably, the gas-liquid mixer 3 has a cylindrical structure or a square cylindrical structure, the foam mixture inlet 31 is provided at one end of the cylindrical structure, and the foam outlet 33 is provided at the other end of the cylindrical structure.

The liquefied gas inlet 32 may be provided in one or more number, and in the case of providing a plurality of liquefied gas inlets 32, a plurality of liquefied gas inlets 32 are provided at intervals in the circumferential direction of the side wall of the gas-liquid mixer 3 (as shown in fig. 4). A plurality of the foam mixture liquid inlet 31 and the foam outlet 33 may be provided, and the arrangement of the ports is not limited to that in the present embodiment.

Preferably, the relationship between the area S1 of the foam mixed liquid inlet 31 and the area S2 of the liquefied gas inlet 32 is: S1/S2 is 10-60; the relationship between the area S4 of the foam outlet 33 and the area S1 of the foam mixed liquid inlet 31 is: S4/S1 is 1.5-6.

More preferably, the relationship between the area S1 of the foam mixed liquid inlet 31 and the area S2 of the liquefied gas inlet 32 is: S1/S2 is 16-40; the relationship between the area S4 of the foam outlet 33 and the area S1 of the foam mixed liquid inlet 31 is: S4/S1 is 2.5-5. The area proportional relation of each port is controlled, so that the flow relation of each port is controlled, the foaming is more sufficient, and the foam with higher quality is obtained. Here, the area of each port is the total area, and for example, the area of the liquefied gas inlet 32 is the total area of the plurality of liquefied gas inlets 32.

In the present embodiment, a turbulence generator 34 for disturbing a liquid flow is provided in the gas-liquid mixing chamber of the gas-liquid mixer 3 so that the foam mixture liquid and the liquefied gas are sufficiently mixed. Preferably, the liquefied gas inlet 32 is on the side wall between the spoiler 34 and the foam mixed liquid inlet 31.

Wherein the turbulence generator 34 may be formed as a conical structure (see fig. 5), a hemispherical structure (see fig. 6), or a plateau structure (see fig. 7), or other irregularly shaped structure, with the conical apex of the conical structure, the spherical apex of the hemispherical structure, or the plateau top surface of the plateau structure facing the foam mix inlet 31. The spoiler 34 is installed such that the top thereof faces the foam mixed liquid inlet 31, and the fluid mixed with the liquefied gas and the foam mixed liquid is flushed toward the spoiler 34, which facilitates the sufficient mixing of the liquefied medium and the foam mixed liquid to obtain foam with uniform foaming and good performance.

Preferably, the relationship between the maximum cross section S3 of the vortex generator 34 and the area S1 of the foam mix inlet 31 is: S3/S1 is 1.1-3.8, and more preferably S3/S1 is 1.4-3.

The ratio of the area S3 of the spoiler 14 to the area of the foam mixture inlet 31 is a preferable range, and if the ratio is out of balance, the foam foaming is insufficient, the resistance is increased, and the flow rate is decreased. For example, if the area of the spoiler is too small, foaming is insufficient, and if the area is too large, resistance is large, and the flow rate is reduced.

To install the spoiler 34, the spoiler 34 may be provided with an installation portion 341 for fixing in the foam generating chamber, such as each spoiler 34 shown in fig. 5 to 7.

Of course, the arrangement of the turbulence generator 34 is not limited to the above, for example, a plurality of turbulence generators may be arranged and distributed at different positions in the foam generating chamber, and any type of turbulence generator capable of disturbing the flow of liquid may be used.

In this embodiment, at least one porous structure 35 such as a perforated plate or a wire mesh and the like arranged at intervals is further arranged in the gas-liquid mixing cavity of the gas-liquid mixer 3, and each porous structure 35 is provided with a plurality of holes; the pores of the porous structure 35 face the foam mix inlet 31, and the top of the turbulator 34 is closer to the foam mix inlet 31 than the porous structure 35. The liquid flow broken up by the turbulence generator 34 continues to flow from the periphery of the turbulence generator 34 to the porous structure 35, and the liquid flow can be further disturbed by the porous structure 35 to be further mixed.

The application of the built-in liquefied medium self-expansion type foam fire-fighting system provided by the invention is described below by the specific embodiment.

Example one

The liquefied medium storage device 2 is connected with a foam mixed liquid storage device 1 for use and is used for protecting a gas station.

The liquefied medium storage device 2 has a volume of 80L, stores liquid nitrogen of 60L, and comprises a self-pressurization device, the liquid discharge amount of the liquefied medium storage device 2 to the foam mixed liquid storage device 1 is 0.4-0.8L/S, the liquid discharge pressure is 0.8MPa, the foam mixed liquid storage device 1 is 400L, stores foam mixed liquid of 320L, the injection flow rate of the foam mixed liquid to the gas-liquid mixer 3 is 4L/S, the injection pressure is 0.6MPa, the diameter of the foam mixed liquid inlet of the gas-liquid mixer 3 is 20mm, 2 liquefied gas inlets 32 are provided, the diameter of each gas inlet is 3.1mm, the area ratio of the foam mixed liquid inlet 31 to the liquefied gas inlet 32 is 21, the diameter of the foam outlet 33 of the gas-liquid mixer 3 is 50mm, the foam foaming control module is 7.5, after a tank fire occurs in a gas station tank area under a control valve, the area is about 10 meters, a temperature-sensitive fire sensor arranged at an oil tank port detects a fire signal, an alarm sends out a fire alarm signal, the fire signal is transmitted to a fire control module, the fire control module controls the automatic storage device to control valve between the liquefied medium storage device 2 and the first storage device to start the foam mixed liquid storage device and the foam mixed liquid storage device to enter a second storage device after the foam mixed liquid storage device 1 and the foam mixed liquid storage device 2, the foam mixed liquid storage device 2 and the foam mixed liquid storage device 2, the foam mixed liquid storage device 1 and the foam mixed liquid storage device 2 automatically control device, the foam mixed liquid storage device is started, the foam mixed liquid storage device 2.

Example two

The liquefied medium storage device 2 is connected with a foam mixed liquid storage device 1 for use and is used for protecting a 5000 vertical inner floating roof storage tank of an oil refinery. The storage tank has the diameter of 22m, the area of 380 square meters and the height of the tank wall of 15 m.

The liquefied medium storage device 2 has a volume of 800L, stores liquid nitrogen of 600L, and comprises a self-pressurization device, the liquid discharge amount of the liquefied medium storage device 2 to the foam mixed liquid storage device 1 is 4L/S, the liquid discharge pressure is 1.0MPa, the foam mixed liquid storage device 1 is 10000L, stores foam mixed liquid of 8000L, sprays foam mixed liquid to the gas-liquid mixer 3 at a flow rate of 40L/S, the spray pressure is 0.6MPa, the diameter of the foam mixed liquid inlet 31 of the gas-liquid mixer 3 is 60mm, only one liquefied gas inlet 32 is provided, the diameter of the liquefied gas inlet 31 is 13mm, the area ratio of the foam mixed liquid inlet 31 to the liquefied gas inlet 32 is 21, the diameter of the foam outlet 33 of the gas-liquid mixer 3 is 100mm, and the foam expansion ratio is 6.5 after a full-area fire occurs in the liquefied gas storage tank, a temperature-sensitive fire sensor provided in the oil tank detects a fire signal, the alarm sends out a fire alarm signal, the fire signal is transmitted to a control module, the control module controls the first automatic fire control valve 5 between the liquefied medium storage device 2 and the foam storage device 1, the foam storage device 2 and the foam mixed liquid storage device 2 is opened, the foam mixed liquid storage device 2 is started to enter a foam mixed liquid storage device after the foam mixed liquid storage device 2 and the foam mixed liquid storage device 2 is gasified, the foam mixed liquid storage device 2, the foam mixed liquid storage device is gasified liquid storage device.

EXAMPLE III

The liquefied medium storage device 2 is connected with a foam mixed liquid storage device 1 for use and is used for protecting 10000m of oil refinery³The vault storage tank of (1). The tank diameter is 26m and the tank wall height is 16 m.

The liquefied medium storage device 2 has a volume of 2000L, stores liquid nitrogen 1600L, includes a self-pressurization device, the liquid discharge amount of the liquefied medium storage device 2 to the foam mixed liquid storage device 1 is 12L/S, the liquid discharge pressure is 1.0MPa, the foam mixed liquid storage device 1 is 12000L, stores foam mixed liquid 9000L, sprays foam mixed liquid to the gas-liquid mixer 3 at 50L/S, the spray pressure is 0.6MPa, the diameter of the foam mixed liquid inlet 31 of the gas-liquid mixer 3 is 80mm, 4 liquefied gas inlets 32 are provided, the diameter of each gas hole is 9mm, the area ratio of the foam mixed liquid inlet 31 to the liquefied gas inlet 32 is 21, the diameter of the foam outlet 33 of the gas-liquid mixer 3 is 150mm, the foam expansion ratio is 6.2 after a full-area fire occurs in the liquefied gas-liquid storage device 1, a temperature-sensitive fire sensor provided in the oil tank detects a fire signal, the fire alarm signal is sent, the fire signal is transmitted to a control module, the control module controls the first self-control valve 5 between the liquefied medium storage device 2 and the foam storage device 1, the foam storage device 2 and the foam mixed liquid storage device 2 is opened, the foam mixed liquid storage device 2, the foam mixed liquid storage device is.

The preferred embodiments of the present invention have been described in detail with reference to the accompanying drawings, but the present invention is not limited thereto. The technical idea of the utility model within the scope, can be right the utility model discloses a technical scheme carries out multiple simple variant, makes up with any suitable mode including each concrete technical feature. In order to avoid unnecessary repetition, the present invention does not separately describe various possible combinations. These simple variations and combinations should also be considered as disclosed in the present invention, all falling within the scope of protection of the present invention.

Claims (14)

1. The built-in liquefied medium self-expansion type foam fire fighting system is characterized by comprising foam generating equipment, wherein the foam generating equipment comprises a foam mixed liquid storage device (1) for containing foam mixed liquid and a liquefied medium storage device (2) for containing liquefied medium and injecting the liquefied medium into the foam mixed liquid storage device (1); the foam generating equipment also comprises a gas-liquid mixer (3) with a gas-liquid mixing cavity, and a foam mixed liquid inlet (31), a liquefied gas inlet (32) and a foam outlet (33) are communicated with the gas-liquid mixing cavity;

the gas-liquid mixer (3) is positioned in a storage chamber of the foam mixed liquid storage device (1), the foam mixed liquid inlet (31) is arranged to be capable of being communicated with a liquid phase of the foam mixed liquid storage device (1) to input foam mixed liquid in the foam mixed liquid storage device (1) into the gas-liquid mixer (3), the liquefied gas inlet (32) is arranged to be capable of being communicated with a gas phase space in the foam mixed liquid storage device (1) to input liquefied gas generated by the gasification of the liquefied medium in the foam mixed liquid storage device (1) into the gas-liquid mixer (3), and foam generated by the mixing of the foam mixed liquid and the liquefied gas in the gas-liquid mixer (3) is sprayed out from the foam outlet (33);

the foam fire-fighting system further comprises fire monitoring equipment, the fire monitoring equipment comprises a fire detection module and a control module connected with the foam generating equipment, the control module is used for controlling the liquefied medium storage device (2) to be communicated with the foam mixed liquid storage device (1) when the fire detection module detects a fire, and liquefied media in the liquefied medium storage device (2) can automatically enter the foam mixed liquid storage device (1) under the action of gas pressure.

2. Foam fire fighting system according to claim 1, characterized in that automatic control valves are provided on the pipeline between the liquefied medium storage means (2) and the foam mixed liquid storage means (1) and on the pipeline to which the foam outlet (33) is connected, respectively, each automatic control valve being connected with the control module to control the on/off of the automatic control valve by the control module.

3. The foam fire fighting system according to claim 2, wherein a flow control valve (9) for controlling the flow of the liquefied medium is further provided on a pipeline between the foam mixture storage device (1) and the liquefied medium storage device (2), a pressure gauge (4) for measuring the pressure in the gas phase space is provided on the foam mixture storage device (1), and the flow control valve (9) adjusts the flow according to the pressure of the pressure gauge (4).

4. The foam fire fighting system according to claim 1, characterized in that one liquefied medium storage device (2) is provided, one or more foam mixed liquid storage devices (1) are provided, the liquefied medium storage device (2) is connected with one or more foam mixed liquid storage devices (1), and an automatic control valve connected with the control module is respectively arranged between the liquefied medium storage device (2) and each foam mixed liquid storage device (1);

or a plurality of liquefied medium storage devices (2) are arranged, the plurality of liquefied medium storage devices (2) are connected together through a confluence pipeline, the confluence pipeline is connected with one or a plurality of foam mixed liquid storage devices (1), and an automatic control valve connected with the control module is arranged between each liquefied medium storage device (2) and each foam mixed liquid storage device (1);

wherein, each foam mixed liquid storage device (1) is correspondingly provided with one gas-liquid mixer (3).

5. The foam fire fighting system according to any one of claims 1 to 4, wherein the fire monitoring device further comprises an alarm module for alarming when a fire is detected by the fire detection module.

6. The foam fire fighting system according to any of claims 1 to 4, characterized in that the gas-liquid mixer (3) is provided with the foam mixture inlet (31) at one end and the foam outlet (33) at the other end, and the liquefied gas inlet (32) is provided on the side wall between the ends of the gas-liquid mixer (3).

7. The foam fire fighting system according to claim 6, characterized in that the liquefied gas inlets (32) are provided in one or more number, and a plurality of the liquefied gas inlets (32) are provided at intervals in the circumferential direction of the side wall of the gas-liquid mixer (3).

8. The foam fire fighting system of claim 6, wherein the relationship between the area S1 of the foam mixed liquid inlet (31) and the area S2 of the liquefied gas inlet (32) is: S1/S2 is 10-60;

the relationship between the area S4 of the foam outlet (33) and the area S1 of the foam mixture inlet (31) is: S4/S1 is 1.5-6.

9. The foam fire fighting system of claim 8, wherein the relationship between the area S1 of the foam mixed liquid inlet (31) and the area S2 of the liquefied gas inlet (32) is: S1/S2 is 16-40;

the relationship between the area S4 of the foam outlet (33) and the area S1 of the foam mixture inlet (31) is: S4/S1 is 2.5-5.

10. The foam fire fighting system according to claim 6, characterized in that a flow spoiler (34) for disturbing a liquid flow is provided in the gas-liquid mixing chamber of the gas-liquid mixer (3), the liquefied gas inlet (32) being on a side wall between the flow spoiler (34) and the foam mixed liquid inlet (31).

11. The foam fire fighting system of claim 10, wherein the spoiler (34) is formed as a cone structure, a semi-spherical structure, or a platform structure;

the conical top of the conical structure, the spherical top of the hemispherical structure or the top surface of the platform structure faces the foam mixed liquid inlet (31).

12. The foam fire fighting system of claim 10, wherein the relationship between the maximum cross section S3 of the spoiler (34) and the area S1 of the foam mix inlet (31) is: S3/S1 is 1.1-3.8.

13. The foam fire fighting system of claim 12, wherein the relationship between the maximum cross section S3 of the spoiler (34) and the area S1 of the foam mix inlet (31) is: S3/S1 is 1.4-3.

14. The foam fire fighting system of claim 10, wherein at least one spaced apart porous structure (35) is disposed within the gas-liquid mixing chamber; a plurality of holes are arranged on each porous structure (35); the pores of the porous structure (35) are directed towards the foam mix inlet (31) and the top of the turbulator (34) is closer to the foam mix inlet (31) than the porous structure (35).

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