CN214130012U - Fire-fighting operation system - Google Patents

Abstract

The utility model provides a fire control operation system, include: the transportation platform is provided with a supercharging device; the fire-fighting robot can be carried on a transportation platform for transportation, and is communicated with a water source through a supercharging device. The utility model provides a fire control operation system sets up supercharging device on transportation platform, on the basis of guaranteeing the remote operation of putting out a fire of fire-fighting robot, can put away the reliance of fire-fighting robot high-pressure water supply to fire-fighting truck when putting out a fire the operation, relies on the water source of tank wagon or fire hydrant to provide, and transportation platform and fire-fighting robot cooperation can be carried out the operation of putting out a fire to can realize narrow complicacy, short environment operation of putting out a fire.

Description

Fire-fighting operation system

Technical Field

The utility model relates to a fire extinguishing systems technical field particularly, relates to a fire control operating system.

Background

At present, the fire fighting robot is a development trend for fire fighting. The fire-fighting robot mostly adopts a crawler-type walking mechanism, has a low moving speed, and is usually transported to a fire scene by adopting a special transport vehicle. The fire-fighting robot is connected with a fire truck through a fire hose after getting off the fire-fighting robot, and pressurized water flow provided by the fire truck is sprayed to extinguish fire through a water gun on the machine body.

The fire-fighting robot is required to be transported to the site through a transport vehicle when working due to the mode, the pressure of the fire hydrant is not enough to meet the pressure requirement of a fire water monitor, the fire-fighting vehicle is required to be pressurized for water supply, and the whole fire-fighting system is huge. And when meeting narrow complex environment fire engine and can't get into, fire-fighting robot receives fire hose length restriction, and the radius of fighting is limited.

Therefore, a complete set of simplified fire-fighting operation system with a fire-fighting robot, which has the passability in a narrow and low environment, is very necessary.

SUMMERY OF THE UTILITY MODEL

The utility model discloses aim at solving one of the technical problem that exists among the prior art at least.

Therefore, the utility model provides a fire-fighting operation system.

The utility model provides a fire control operation system, include: the transportation platform is provided with a supercharging device; the fire-fighting robot can be carried on a transportation platform for transportation, and is communicated with a water source through a supercharging device.

The utility model provides a fire control operation system includes transportation platform and fire-fighting robot. The transportation platform can transport the fire-fighting robot, so that the fire-fighting robot can quickly arrive at an operation site; be provided with supercharging device on the transportation platform, the fire-fighting robot is linked together through supercharging device and water source, under the circumstances of guaranteeing the water source supply, pressurizes for liquid through supercharging device, and then has enlarged fire-fighting robot's the scope of putting out a fire, realizes the remote operation of putting out a fire.

Particularly, the supercharging device is directly arranged on the transportation platform, and supercharging can be realized through the transportation platform, so that the defect that the fire-fighting robot needs to be equipped with a fire truck for operation is overcome. In addition, the transportation platform is smaller than the size of fire engine, can directly carry the fire-fighting robot to get into narrow complicated, short environment, has reduced the requirement of fire-fighting operation system to the operation place to a very big degree, promotes fire-fighting operation system's adaptability simultaneously. In particular, the fire-fighting robot may rely on a tanker truck or a fire hydrant to ensure that the water source is provided.

The utility model provides a fire-fighting operation system, which is characterized in that a supercharging device is arranged on a transportation platform, on the basis of ensuring the remote fire-fighting operation of a fire-fighting robot, the transportation platform and the fire-fighting robot can be used for carrying out the fire-fighting operation by means of the water source of a water tank truck or a fire hydrant and the dependence on the high-pressure water supply of a fire-fighting truck during the fire-fighting operation of the fire-fighting robot can be released; and can realize the fire extinguishing operation in narrow, complex and low environments.

According to the utility model discloses above-mentioned technical scheme's fire control operating system can also have following additional technical characteristic:

in the above technical solution, the fire-fighting operation system further includes: the gearbox is arranged on the transportation platform; the power takeoff is arranged on the transportation platform and is connected with the gearbox and the supercharging device, and the power takeoff can drive the supercharging device to work under the driving of the gearbox.

In the technical scheme, the fire-fighting operation system further comprises a gearbox and a power takeoff. The gearbox is arranged on the transportation platform to ensure the transportation platform to work; the power takeoff is arranged on the transportation platform and is connected with the gearbox and the supercharging device. The supercharging device directly takes power from a gearbox inherent to the transportation platform through a power takeoff; the pressurizing device can be driven only by additionally arranging a power takeoff on the transportation platform. Under the condition of ensuring that the transportation platform has a pressurization function, the transportation platform is simple in structure, the modification difficulty of the transportation platform is reduced, and the design cost and the manufacturing cost of a fire-fighting operation system are reduced.

In any one of the above technical solutions, the fire-fighting operation system further includes: and the hydraulic motor is arranged on the transportation platform and is connected with the supercharging device, and the hydraulic motor can drive the supercharging device to work.

In this technical scheme, fire control operation system still includes hydraulic motor. Wherein, the hydraulic motor is arranged on the transportation platform and is connected with the supercharging device. That is, drive supercharging device work through hydraulic motor, can guarantee the drive power to supercharging device, and then guarantee supercharging device to the pressure boost effect of liquid, and then guarantee fire-fighting robot's working distance.

In any of the above technical solutions, the fire fighting operation system includes a transmission, a power takeoff and a hydraulic motor, and the booster device is driven to operate selectively by the power takeoff and/or the hydraulic motor.

In any one of the above technical solutions, the fire-fighting operation system further includes: the inlet of the pipeline is communicated with a water source, and the supercharging device is communicated with the pipeline; the inlet of the fire hose is communicated with the outlet of the pipeline, and the outlet of the waterproof belt is communicated with the fire-fighting robot.

In the technical scheme, the fire-fighting operation system further comprises a pipeline and a fire hose. The inlet of the pipeline is communicated with a water source, the outlet of the pipeline is communicated with the inlet of a fire hose, the outlet of the fire hose is communicated with a fire-fighting robot, and the supercharging device is arranged on the pipeline. In the working process of the fire-fighting operation system, liquid passes through the pipeline and the fire hose in sequence and is sprayed from the fire-fighting robot under the pressurization effect of the pressurization device, so that the remote fire-fighting operation is realized, and the remote operation is realized.

Particularly, the pipeline is directly arranged on the transportation platform, and the pressurizing device is communicated with the pipeline, so that the pressurizing effect of the liquid provided by the water source is ensured; the fire hose connecting pipeline is used by the fire-fighting robot, the working distance of the fire-fighting robot is further increased under the condition that the fire-fighting robot can spray liquid through water pressure remotely, and the fire-fighting robot can be ensured to go deep into the fire scene for internal fire extinguishment.

In any one of the above technical solutions, the number of the fire-fighting robots is one; or the number of fire-fighting robots is a plurality of, and the number of fire-fighting hoses is a plurality of, and the import of a plurality of fire-fighting hoses is linked together with the export of pipeline simultaneously, and the export of a plurality of fire-fighting hoses communicates with a plurality of fire-fighting robots respectively.

In this technical scheme, the quantity of fire control robot can set up according to actual conditions, can be one, also can be a plurality of. When the transportation platform carries and transports a fire-fighting robot, the fire-fighting robot is directly communicated with the pipeline through the fire hose; when a plurality of fire-fighting robots are carried and transported on the transportation platform, each fire-fighting robot is provided with a fire hose, and the inlets of the fire hoses are communicated with the outlet of the pipeline simultaneously, so that the operating efficiency of the fire-fighting operating system is improved.

In any one of the above technical solutions, the fire fighting robot includes: the moving body is provided with a crawler belt or a wheel shaft; and the water gun is arranged on the moving body and communicated with the supercharging device.

In this technical scheme, fire-fighting robot includes removal main part and squirt. The moving body is provided with a track or a wheel shaft, so that the movement of the fire-fighting robot is realized, and the fire-fighting robot can enter the interior of an operation site to operate and extinguish fire after being separated from the transportation platform; the squirt setting is on removing the main part to be linked together through fire hose and pipeline and supercharging device, the liquid after the supercharging device pressure boost can be followed the squirt and sprayed, has enlarged fire-fighting robot's the scope of putting out a fire.

In any of the above technical solutions, the transportation platform further includes: a chassis; the carriage is arranged on the chassis, and the fire-fighting robot can be carried in the carriage; the storage space is arranged on the chassis, and the supercharging device is arranged in the storage space.

In this technical scheme, transportation platform still includes chassis, carriage and storing space. Wherein, carriage and storing space all set up on the chassis, and the carriage can be used to place fire-fighting robot, and storing space can be used to place supercharging device. Particularly, because the setting of storing space for supercharging device and fire-fighting robot save in the space of difference, avoid supercharging device and fire-fighting robot to be in same space together, can effectively avoid the unexpected striking supercharging device of robot in the transportation, and then guarantee transport platform's security performance.

In any of the above technical solutions, the transportation platform further includes: the fixing device is arranged in the carriage, and the fire-fighting robot is limited by the fixing device; the overturning baffle is arranged on the chassis, and the fire-fighting robot can move out of the carriage from the overturning baffle.

In the technical scheme, the transportation platform further comprises a fixing device and a turnover baffle. The fixing device is arranged in the carriage and protrudes out of the chassis; place at the inside back in carriage when fire-fighting robot, fire-fighting robot and fixing device looks butt, and then make fixing device play good positioning action, guarantee that fire-fighting robot appears removing the condition of striking in the transportation at the inside position relatively fixed in carriage.

In addition, the turnover baffle is arranged on the chassis and is positioned at the tail part of the chassis. In the process that the fire-fighting robot enters the carriage or is separated from the carriage, the turnover baffle is turned over and is in contact with the ground, and then the fire-fighting robot enters the carriage through the turnover baffle or moves out of the carriage.

In any of the above technical solutions, the roll-over damper includes: one end of the first baffle is connected with the chassis; one end of the second baffle plate is rotatably connected with the other end of the first baffle plate, and the other end of the second baffle plate can be in contact with the ground.

In the technical scheme, the overturning baffle comprises a first baffle and a second baffle which are matched for use. Wherein, the one end of first baffle is connected with the chassis, and the one end of second baffle and the other end rotatable coupling of first baffle, the other end of second baffle uses as the free end.

When the fire-fighting robot needs to enter the carriage or be separated from the carriage, the other end of the second baffle plate is in contact with the ground, so that the fire-fighting robot can enter the carriage or be separated from the carriage after moving along the turnover baffle plate; when the transportation platform transports the fire-fighting robot, the other end of the second baffle is separated from the ground, and the second baffle can also play a certain blocking role at the moment, so that the fire-fighting robot is prevented from accidentally falling off.

In any of the above technical solutions, the transportation platform is a vehicle; and/or the boosting device is a booster pump.

In the technical scheme, the transportation platform is a vehicle. Furthermore, the supercharging device is a booster pump. Specifically, the pressurizing device may be a water pump, a plunger pump, or the like, as long as pressurization can be achieved.

Additional aspects and advantages of the invention will be set forth in part in the description which follows, or may be learned by practice of the invention.

Drawings

The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

fig. 1 is a schematic view (in a transport state) of a fire fighting system according to an embodiment of the present invention;

fig. 2 is a schematic view (in an operating state) of a fire fighting system according to an embodiment of the present invention.

Wherein, the correspondence between the reference numbers and the component names in fig. 1 and fig. 2 is:

102 transport platform, 104 supercharging device, 106 fire-fighting robot, 106a first fire-fighting robot, 106b second fire-fighting robot, 108 pipeline, 110 fire hose, 112 moving body, 114 water gun, 116 chassis, 118 carriage, 120 storage space, 122 fixing device, 124 turnover baffle.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention more clearly understood, the present invention will be described in further detail with reference to the accompanying drawings and detailed description. It should be noted that the embodiments and features of the embodiments of the present application may be combined with each other without conflict.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, however, the present invention may be practiced in other ways than those specifically described herein, and therefore the scope of the present invention is not limited by the specific embodiments disclosed below.

A fire fighting operation system provided according to some embodiments of the present invention is described below with reference to fig. 1 and 2.

The first embodiment is as follows:

as shown in fig. 1, a first embodiment of the present invention provides a fire fighting system, including: a transport platform 102 and a fire fighting robot 106.

Wherein, as shown in fig. 1, the transportation platform 102 may transport the fire-fighting robot 106, ensuring that the fire-fighting robot 106 arrives at the operation site quickly; the transportation platform 102 is provided with the supercharging device 104, the fire-fighting robot 106 is communicated with a water source through the supercharging device 104, and liquid is pressurized through the supercharging device 104 under the condition that water source supply is guaranteed, so that the fire extinguishing range of the fire-fighting robot 106 is expanded, and long-distance fire extinguishing operation is realized.

In particular, since the pressurization device 104 is directly disposed on the transportation platform 102, pressurization can be achieved through the transportation platform 102, and the disadvantage that the fire-fighting robot 106 must be equipped with a fire truck for operation is eliminated. In addition, the transportation platform 102 is smaller than a fire fighting truck in size, and can directly carry the fire-fighting robot 106 to enter a narrow, complex and low environment, so that the requirement of the fire-fighting operation system on the operation site is greatly reduced, and the adaptability of the fire-fighting operation system is improved. Specifically, the fire fighting robot 106 may rely on a tanker truck or a fire hydrant to ensure that the water source is provided.

According to the fire-fighting operation system provided by the embodiment, the supercharging device 104 is arranged on the transportation platform 102, so that on the basis of ensuring the long-distance fire-fighting operation of the fire-fighting robot 106, the dependence on high-pressure water supply of a fire fighting truck during the fire-fighting operation of the fire-fighting robot 106 can be avoided, and the transportation platform 102 and the fire-fighting robot 106 can carry out the fire-fighting operation by means of water source supply of a water tank truck or a fire hydrant; and can realize the fire extinguishing operation in narrow, complex and low environments.

Example two:

as shown in fig. 1, a second embodiment of the present invention provides a fire fighting system, including: a transport platform 102, a fire fighting robot 106, a gearbox and a power takeoff.

Wherein, as shown in fig. 1, the transportation platform 102 may transport the fire-fighting robot 106, ensuring that the fire-fighting robot 106 arrives at the operation site quickly; the transportation platform 102 is provided with a supercharging device 104, the fire-fighting robot 106 is communicated with a water source through the supercharging device 104, and liquid is pressurized through the supercharging device 104 under the condition that the water source supply is ensured, so that the fire-fighting range of the fire-fighting robot 106 is expanded, and the long-distance fire-fighting operation is realized; the gearbox is arranged on the transportation platform 102 to ensure the transportation platform 102 to work; the power take-off is arranged on the transport platform 102 and is connected with the gearbox and the supercharging device 104.

That is, this embodiment compares in embodiment one, and supercharging device 104 directly takes power from the inherent gearbox of transportation platform 102 through the power takeoff, only needs to add a power takeoff at transportation platform 102, can realize the drive to supercharging device 104, under the circumstances of guaranteeing that transportation platform 102 is from taking the pressure boost function, guarantees transportation platform 102's simple structure to reduce transportation platform 102's the repacking degree of difficulty, be favorable to reducing fire control operation system's design cost and manufacturing cost.

Example three:

as shown in fig. 1, a third embodiment of the present invention provides a fire fighting system, including: a transport platform 102, a fire fighting robot 106, and a hydraulic motor.

Wherein, as shown in fig. 1, the transportation platform 102 may transport the fire-fighting robot 106, ensuring that the fire-fighting robot 106 arrives at the operation site quickly; the transportation platform 102 is provided with a supercharging device 104, the fire-fighting robot 106 is communicated with a water source through the supercharging device 104, and liquid is pressurized through the supercharging device 104 under the condition that the water source supply is ensured, so that the fire-fighting range of the fire-fighting robot 106 is expanded, and the long-distance fire-fighting operation is realized; the hydraulic motor is disposed on the transport platform 102 and is coupled to the booster device 104.

That is, in this embodiment, compared with the first embodiment, the hydraulic motor drives the supercharging device 104 to operate, so as to ensure the driving force for the supercharging device 104, further ensure the supercharging effect of the supercharging device 104 on the liquid, and further ensure the working distance of the fire-fighting robot 106.

In particular, the fire fighting operation system may also include a transmission, a power takeoff, and a hydraulic motor, and the booster 104 may be driven to operate selectively by the power takeoff and/or the hydraulic motor, so that the fire fighting operation system has both the above advantages.

Example four:

as shown in fig. 1 and 2, a fourth embodiment of the present invention provides a fire fighting system, including: a transport platform 102, a fire fighting robot 106, a pipeline 108, and a fire hose 110.

Wherein, as shown in fig. 1, the transportation platform 102 may transport the fire-fighting robot 106, ensuring that the fire-fighting robot 106 arrives at the operation site quickly; the transportation platform 102 is provided with a supercharging device 104, the fire-fighting robot 106 is communicated with a water source through the supercharging device 104, and liquid is pressurized through the supercharging device 104 under the condition that the water source supply is ensured, so that the fire-fighting range of the fire-fighting robot 106 is expanded, and the long-distance fire-fighting operation is realized; as shown in fig. 2, the fire fighting robot 106 is in communication with a pipeline 108 through a fire hose 110, and the booster 104 is disposed on the pipeline 108.

Specifically, as shown in fig. 2, an inlet of the pipeline 108 is communicated with a water source, an outlet of the pipeline 108 is communicated with an inlet of the fire hose 110, an outlet of the fire hose 110 is communicated with the fire-fighting robot 106, and the pressure boosting device 104 is disposed on the pipeline 108. During the working process of the fire-fighting operation system, liquid passes through the pipeline 108 and the fire hose 110 in sequence and is sprayed from the fire-fighting robot 106 under the pressurization effect of the pressurization device 104, so that the long-distance fire extinguishing operation and the long-distance operation are realized.

In particular, in the embodiment, the pipeline 108 is directly arranged on the transportation platform 102, and the pressurizing device 104 is communicated with the pipeline 108, so that the pressurizing effect on the liquid provided by the water source is ensured; the fire hose 110 is used for connecting the pipeline 108 and the fire-fighting robot 106, so that the working distance of the fire-fighting robot 106 is further increased under the condition that the fire-fighting robot 106 can spray liquid remotely through water pressure, and the fire-fighting robot 106 can be ensured to go deep into a fire scene to extinguish fire.

In a specific embodiment, the length of the fire hose 110 may be set according to actual conditions, so as to meet the requirements of fire extinguishing operations at different distances.

In this embodiment, further, the number of the fire-fighting robots 106 may be set according to actual conditions, and may be one or more.

When the transportation platform 102 carries and transports a fire-fighting robot 106, the fire-fighting robot 106 is directly communicated with the pipeline 108 through the fire hose 110.

When the transportation platform 102 carries and transports a plurality of fire-fighting robots 106, each fire-fighting robot 106 is configured with a fire hose 110, and the inlets of the fire hoses 110 are simultaneously communicated with the outlet of the pipeline 108, so as to improve the operation efficiency of the fire-fighting operation system.

In a specific embodiment, as shown in fig. 2, the transportation platform 102 carries and transports two fire-fighting robots 106, which are a first fire-fighting robot 106a and a second fire-fighting robot 106b, respectively, and the first fire-fighting robot 106a and the second fire-fighting robot 106b cooperate to participate in fire extinguishing work together. It should be noted that fig. 2 is only illustrated by taking two fire-fighting robots 106 as an example, and the fire-fighting operation system provided by the embodiment is not limited thereto.

In any of the above embodiments, further, as shown in fig. 1, the fire fighting robot 106 includes a moving body 112 and a lance 114. The moving body 112 is provided with a track or a wheel shaft, so that the movement of the fire-fighting robot 106 is realized, and the fire-fighting robot 106 can enter the interior of the operation site to operate and extinguish fire after being separated from the transportation platform 102; the water gun 114 is arranged on the moving body 112 and is communicated with the supercharging device 104 through the fire hose 110 and the pipeline 108, and liquid pressurized by the supercharging device 104 can be sprayed from the water gun 114, so that the fire extinguishing range of the fire-fighting robot 106 is expanded.

In an embodiment, the size of the water gun 114 may be selected according to actual conditions, so as to meet the requirements of fire extinguishing operations at different distances.

In any of the above embodiments, further, as shown in fig. 1, the transport platform 102 further includes a chassis 116, a car 118, and a storage space 120. Wherein, the carriage 118 and the storage space 120 are both disposed on the chassis 116, the carriage 118 can be used for placing the fire-fighting robot 106, and the storage space 120 can be used for placing the supercharging device 104. Particularly, due to the arrangement of the storage space 120, the supercharging device 104 and the fire-fighting robot 106 are stored in different spaces, the supercharging device 104 and the fire-fighting robot 106 are prevented from being located in the same space, the firefighting robot 106 is effectively prevented from accidentally striking the supercharging device 104 in the transportation process, and the safety performance of the transportation platform 102 is further ensured.

In any of the above embodiments, further, as shown in fig. 1, the transport platform 102 further comprises a fixture 122. Wherein the fixing device 122 is disposed in the vehicle cabin 118 and protrudes from the chassis 116; after the fire-fighting robot 106 is placed inside the carriage 118, the fire-fighting robot 106 abuts against the fixing device 122, so that the fixing device 122 has a good positioning effect, the position of the fire-fighting robot 106 inside the carriage 118 is relatively fixed, and the situation of moving impact in the transportation process is avoided.

In any of the above embodiments, further, as shown in fig. 1, the transport platform 102 further includes a roll-over damper 124. Wherein, the turnover baffle 124 is arranged on the bottom plate 116 and is positioned at the tail part of the bottom plate 116. During the process that the fire fighting robot 106 enters the carriage 118 or leaves the carriage 118, the roll-over flapper 124 rolls over and contacts the ground, thereby allowing the fire fighting robot 106 to move into the interior of the carriage 118 or out of the carriage 118 through the roll-over flapper 124.

Specifically, the roll-over damper 124 includes a first damper and a second damper that cooperate. Wherein, one end of the first baffle is connected with the chassis 116, one end of the second baffle is rotatably connected with the other end of the first baffle, and the other end of the second baffle is used as a free end.

When the fire-fighting robot 106 needs to enter the carriage 118 or leave the carriage 118, the other end of the second barrier is in contact with the ground, so that the fire-fighting robot 106 can enter the carriage 118 or leave the carriage 118 by moving along the overturning barrier 124; when the transportation platform 102 transports the fire-fighting robot 106, the other end of the second baffle is separated from the ground, and the second baffle can also play a certain blocking role at this time, so that the fire-fighting robot 106 is prevented from falling off accidentally.

In a specific embodiment, the retractable mechanism can be implemented by driving the flip plate 124 through a telescopic hydraulic cylinder.

In any of the above embodiments, further, as shown in fig. 1, the transport platform 102 is a vehicle.

In any of the above embodiments, further, the boosting device 104 is a booster pump.

Specifically, the pressure increasing device 104 may be a water pump, a plunger pump, or the like, as long as the pressure increase can be achieved.

The specific embodiment is as follows:

as shown in fig. 1 and fig. 2, the fire fighting system according to the present embodiment includes a transportation platform 102, a fire fighting robot 106, a pressure boosting device 104, a waterway system, a fire hose 110, and the like.

As shown in fig. 1, the transportation platform 102 includes a chassis 116 and a carriage 118, and the carriage 118 has a transportation space and a fixing device 122 therein to fix and transport the fire-fighting robot 106; the tail of the carriage 118 is provided with a turnover baffle 124, the turnover baffle 124 can be driven by a telescopic hydraulic cylinder to be retracted, and the fire-fighting robot 106 can enter and exit the carriage 118 through the completely opened turnover baffle 124.

As shown in fig. 1, the waterway system includes a pipe 108, a water inlet, and a water outlet. The water inlet can be connected with a fire hydrant or a water tanker, after water is pressurized, the water pressure requirement of fire extinguishing operation of the fire-fighting robot 106 is ensured through the connection of the fire hose 110 connected with the water outlet and the inlet of the water gun 114 of the fire-fighting robot 106. The transport platform 102 provides multiple sized water inlets, connects to the pressure boosting device 104 through a water trap, and provides multiple water outlets.

For example, more than two fire hoses 110 (the fire hose 110 with the outer diameter of 88.9 mm) of DN80 or more than one fire hose 110 (the fire hose 110 with the outer diameter of 101.6 mm) of DN90 are connected each time, so that the fire extinguishing operation requirement of the fire-fighting robot 106 with the flow rate of 80L/s can be met by one DN80 water outlet.

The storage space 120 on the transportation platform 102 may house the fire hose 110, fittings of the fire fighting robot 106, etc.

Each transport platform 102 can implement one-to-N, i.e., one transport platform 102 supports the fire fighting operation of more than two fire robots 106. This may be accomplished by increasing the tonnage size of the transport platform 102, as well as the number of pressure intensifiers 104 and lines 108, as needed.

The whole set of fire-fighting operation system is simple and convenient, the transportation platform 102 is smaller than a common fire truck in size, the fire-fighting robot 106 can be directly carried to enter a narrow, complex and low environment, under the condition that water source supply is guaranteed, water is pressurized through the self-pressurization device 104, the water cannon of the fire-fighting robot 106 is connected through the fire hose 110, and the fire extinguishing range is expanded.

Specifically, as shown in fig. 1, the fire fighting work system includes a transportation platform 102, a fire fighting robot 106, a pressurization device 104, a waterway system, and a fire hose 110. The transportation platform 102 comprises a chassis 116 and a carriage 118, wherein the carriage 118 has a transportation space, and the fire-fighting robot 106 is fixed and transported by a fixing device 122; the tail of the carriage 118 is provided with a turnover baffle 124, the folding and unfolding can be realized through a telescopic hydraulic cylinder, and the fire-fighting robot 106 can enter and exit the carriage 118 through the completely opened turnover baffle 124. The storage space 120 in the vehicle may house the fire hose 110, fittings of the fire-fighting robot 106, and the like. The fire-fighting robot 106 carries the water gun 114 and can walk by the crawler. The booster device 104 may take power from a gearbox in the chassis 116 or may be powered by a hydraulic motor. The waterway system comprises a pipeline 108, a water inlet and a water outlet, wherein the water inlet can be connected with a fire hydrant or a water tanker, after water is pressurized, the water is connected with a water gun 114 of the fire-fighting robot 106 through a fire hose 110 connected with the water outlet, and the hydraulic pressure requirement of the fire-fighting operation of the fire-fighting robot 106 is ensured. The transport platform 102 provides multiple sized water inlets, connects to the pressure boosting device 104 through a water collector, and provides multiple water outlets.

As shown in fig. 2, each transport platform 102 may implement one towing N, i.e., one transport platform 102 supports the fire fighting operation of more than two fire robots 106. The water provided by the tanker or hydrant is pressurized by the pressurizing device 104 of the transportation platform 102 and then connected to the water gun 114 of the fire-fighting robot 106 through the fire hose 110. If more fire-fighting robots 106 need to be carried, the tonnage and the size of the transportation platform 102 and the power of the supercharging device 104 can be increased, and the diameter of the pipeline 108 and the size of the water inlet and outlet are increased.

In the fire-fighting operation system provided by the embodiment, the supercharging device 104 is additionally arranged on the transportation platform 102, so that the dependence on high-pressure water supply of a fire fighting truck during fire fighting operation of the fire-fighting robot 106 can be avoided, and the fire fighting operation can be carried out by a complete set of solution method and system formed by the transportation platform 102 and the fire-fighting robot 106 by means of water source supply of a water tank truck or a fire hydrant. The pressurizing device 104 added to the transportation platform 102 can realize self-pressurization, so that the water pressure of a water monitor of the fire-fighting robot 106 is guaranteed, and a fire-fighting truck is not needed; the transport platform 102 and the fire-fighting robot 106 may undertake fire-fighting tasks as a basic fire-fighting unit.

In the description of the present invention, the terms "plurality" or "a plurality" refer to two or more, and unless otherwise specifically limited, the terms "upper", "lower", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are merely for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention; the terms "connected," "mounted," "secured," and the like are to be construed broadly and include, for example, fixed connections, removable connections, or integral connections; may be directly connected or indirectly connected through an intermediate. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

In the description of the present specification, the description of the terms "one embodiment," "some embodiments," "specific embodiments," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The above is only a preferred embodiment of the present invention, and is not intended to limit the present invention, and various modifications and changes will occur to those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (7)

1. A fire fighting operation system, comprising:

the transportation platform is provided with a supercharging device;

the fire-fighting robot can be carried on the transportation platform for transportation, and is communicated with a water source through the supercharging device;

the gearbox is arranged on the transportation platform;

the power takeoff is arranged on the transportation platform and is connected with the gearbox and the supercharging device, and the power takeoff can be driven by the gearbox to drive the supercharging device to work;

the transport platform further comprises:

a chassis;

the carriage is arranged on the chassis, and the fire-fighting robot can be carried in the carriage;

the storage space is arranged on the chassis, and the supercharging device is arranged in the storage space;

the upset baffle set up in on the chassis, fire-fighting robot can certainly the upset baffle shifts out the carriage, the upset baffle includes:

one end of the first baffle is connected with the chassis;

the one end of second baffle with the other end rotatable coupling of first baffle, the other end of second baffle can contact with ground the transportation platform transportation when the fire-fighting robot, the second baffle can play the effect of blockking.

2. A fire fighting operation system according to claim 1, further comprising:

the hydraulic motor is arranged on the transportation platform and connected with the supercharging device, and the hydraulic motor can drive the supercharging device to work.

3. A fire fighting operation system according to claim 1, further comprising:

the inlet of the pipeline is communicated with the water source, and the supercharging device is communicated with the pipeline;

and the inlet of the fire hose is communicated with the outlet of the pipeline, and the outlet of the fire hose is communicated with the fire-fighting robot.

4. A fire fighting working system according to claim 3,

the number of the fire-fighting robots is one; or the like, or, alternatively,

the fire-fighting robot is characterized in that the number of the fire-fighting robots is multiple, the number of the fire-fighting hoses is multiple, the inlets of the fire-fighting hoses are communicated with the outlets of the pipelines at the same time, and the outlets of the fire-fighting hoses are communicated with the fire-fighting robots respectively.

5. A fire fighting operation system according to claim 1, wherein the fire fighting robot includes:

the moving body is provided with a crawler belt or a wheel shaft;

and the water gun is arranged on the moving body and communicated with the supercharging device.

6. A fire fighting operating system according to any one of claims 1 to 5, wherein the transport platform further comprises:

and the fixing device is arranged in the carriage, and the fire-fighting robot is limited by the fixing device.

7. A fire fighting working system according to any one of claims 1 to 5,

the transportation platform is a vehicle; and/or the presence of a gas in the gas,

the supercharging device is a booster pump.

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