CN214296381U - Water life-saving system - Google Patents

Abstract

The application relates to the technical field of water lifesaving, provides a water lifesaving system, includes: a controller; the monitoring equipment is in communication connection with the controller and is used for monitoring the water surface condition in real time; the throwing box is provided with a containing cavity, and a throwing device is arranged in the containing cavity and can be driven by the controller; the lifesaving robot can be accomodate in accomodating the chamber to can be put in with intelligent lifesaving people on water by the input device. The water lifesaving system can rapidly put in the lifesaving robot when people fall into water, the response rescue speed is faster, the success rate of rescue is improved, and the drowning of people is reduced.

Description

Water life-saving system

Technical Field

The application belongs to the technical field of water lifesaving, and more specifically relates to a water lifesaving system.

Background

Swimming is a very pleasant thing in summer, but there are always drowning accidents every year in summer. Drowning rescue needs timely discovery and timely rescue, but the existing water lifesaving equipment is not satisfactory in rescue speed, and rescue failure is often caused.

SUMMERY OF THE UTILITY MODEL

An object of the embodiment of the application is to provide a water life-saving system to solve the technical problem that rescue fails due to the fact that water life-saving equipment in the prior art is slow in rescue speed.

In order to achieve the purpose, the technical scheme adopted by the application is as follows: there is provided a water life saving system comprising:

a controller;

the monitoring equipment is in communication connection with the controller and is used for monitoring the water surface condition in real time;

the throwing box is provided with a containing cavity, a throwing device is arranged in the containing cavity, and the throwing device can be driven by the controller;

the lifesaving robot can be accommodated in the accommodating cavity and can be thrown to water by the throwing device so as to intelligently rescue people.

In a possible embodiment, the water life-saving system further comprises an electric power storage device, and the electric power storage device is respectively in communication connection with the controller, the monitoring equipment and the warning device.

In a possible embodiment, the water lifesaving system further comprises a warning device and a remote controller, the warning device is in communication connection with the controller and is used for giving out a warning when someone falls into water, and the remote controller is stored in the throwing box and is used for controlling the lifesaving robot.

In a possible embodiment, the surface of the throwing box is provided with an installation cavity for accommodating the remote controller, the outer cover of the installation cavity is provided with a cover body, the cover body is locked through an electric lock, and the electric lock is in communication connection with the controller.

In a possible embodiment, the launch box comprises:

a box body;

the box cover is arranged on the box body in a covering mode and forms the containing cavity with the box body in an enclosing mode;

the suction component is in communication connection with the controller and is used for sucking or separating the box cover from the box body;

and the supporting component is connected between the box body and the box cover and can automatically support the box cover after the box cover and the box body lose suction force.

In a possible embodiment, the delivery device comprises:

a support frame;

the bracket is arranged on the supporting frame in a sliding mode and can slide out from the containing cavity to the throwing port; the lifesaving robot is arranged on the bracket in a sliding manner and can slide into the water surface from the bracket;

a first release assembly for restraining the tray on the support bracket and releasing the tray after the lid is opened;

a second release assembly for restraining the lifesaving robot on the carriage and releasing the lifesaving robot when the carriage slides to an extreme position.

In a possible embodiment, a first slide rail is arranged on the support frame, a second slide rail is arranged on the bracket, and the second slide rail is slidably arranged on the first slide rail; the top of the bracket is also provided with a third sliding rail, and the lifesaving robot is arranged on the third sliding rail in a sliding manner; the extension directions of the first slide rail, the second slide rail and the third slide rail are the same, and the first slide rail, the second slide rail and the third slide rail extend downwards in an inclined manner from the inside of the containing cavity to the direction of the throwing opening.

In a possible embodiment, the first release assembly comprises:

one end of the first pull wire is fixed on the box cover;

the first lock catch is arranged on the support frame, the first lock catch is provided with a first pull buckle, the other end of the first pull wire is fixed on the first pull buckle, and a first bayonet is formed in the first lock catch;

the bracket is provided with a pull rod which can be clamped by the first bayonet, the first pull wire is stretched when the box cover is opened to the limit position, and the first pull buckle can be pulled to enable the first bayonet to release the pull rod.

In a possible embodiment, the first latch comprises:

the first clamping piece is hinged on the bracket;

one end of the second clamping piece is hinged to the bracket, the first pull buckle is arranged at the other end of the second clamping piece, and the second clamping piece and the first clamping piece are mutually clamped and enclosed to form the first bayonet;

the two ends of the first torsion spring are respectively connected with the first hinge shaft of the first clamping piece and the bracket;

and two ends of the second torsion spring are respectively connected with the second hinge shaft of the second clamping piece and the bracket.

In a possible embodiment, the second release assembly comprises:

one end of the second pull wire is fixed on the support frame;

the second lock catch is arranged on the bracket and provided with a second pull buckle, the other end of the second pull wire is fixed on the second pull buckle, and a second bayonet is formed on the second lock catch;

a release fence installed on the bracket and capable of restraining the lifesaving robot; the release railing can be clamped by the second bayonet, the second pull wire can pull the second pull buckle when the bracket slides to the limit position, the second bayonet releases the release railing, and the release railing falls down to release the lifesaving robot.

The application provides a life-saving system on water's beneficial effect lies in: the life-saving system on water that this application embodiment provided, through controller, supervisory equipment, put in case and life-saving robot's setting, can discover in time through supervisory equipment the personnel that fall into water, can in time put in life-saving robot to aquatic through putting in the case to reach quick life-saving's purpose, its response rescue speed is faster, then rescue speed is just faster, and then has improved the success rate of rescue, reduces the drowned personnel.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the embodiments or the prior art descriptions will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without inventive exercise.

Fig. 1 is a perspective view of a water life-saving system provided by an embodiment of the application;

FIG. 2 is a schematic diagram of the electric circuit of the water lifesaving system in FIG. 1;

fig. 3 is a back schematic view of the water life saving system of fig. 1;

FIG. 4 is a schematic structural diagram of the dispensing device of FIG. 1;

FIG. 5 is a schematic view of the carriage of FIG. 1 shown in a position slid to an extreme position;

FIG. 6 is a schematic view of the carriage of FIG. 4 in a state slid to an extreme position;

fig. 7 is a structural schematic view of the first latch of fig. 4.

Wherein, in the figures, the respective reference numerals:

10. a controller; 20. monitoring equipment; 30. a warning device; 40. a lifesaving robot; 50. a throwing box; 51. a box body; 52. a box cover; 53. a receiving cavity; 54. a throwing port; 55. a suction assembly; 551. an electromagnet; 552. a second iron block; 56. a support assembly; 561. a gas support rod; 57. a cover body; 58. a mounting cavity; 59. an electric lock; 591. a magnetic switch; 592. a first iron block; 60. a delivery device; 61. a support frame; 611. a guide block; 62. a bracket; 621. a support block; 622. a connecting rod; 63. a first release assembly; 631. a first pull wire; 632. a first lock catch; 6321. a first clip member; 6322. a second clip member; 6323. a first torsion spring; 6324. a second torsion spring; 6325. a first hinge shaft; 6326. a second hinge shaft; 6327. a first tab; 6328. a first bayonet; 64. a second release assembly; 641. a second pull wire; 642. a second lock catch; 6421. a second tab; 6422. a second bayonet; 643. releasing the fence; 6431. erecting a rod; 6432. a rail; 65. a first slide rail; 66. a second slide rail; 67. a third slide rail; 671. a trough body; 672. a roller; 70. a mounting frame; 80. a solar charging panel; 90. a remote controller; x, a first direction; y, second direction.

Detailed Description

In order to make the technical problems, technical solutions and advantageous effects to be solved by the present application clearer, the present application is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or be indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or be indirectly connected to the other element.

It will be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like, as used herein, refer to an orientation or positional relationship indicated in the drawings that is solely for the purpose of facilitating the description and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be considered as limiting the present application.

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 one or more of that feature. In the description of the present application, "a plurality" means two or more unless specifically limited otherwise.

Referring to fig. 1, a water life-saving system provided by the embodiment of the application will be described. The water life-saving system is generally arranged on the water side of areas which are easy to fall into water, such as lake sides, river sides, swimming pool sides or areas close to bank sides, and the like, and is used for quickly saving people after people fall into water, so that the life-saving efficiency and the life-saving success rate are improved.

Referring to fig. 1 and 2, the water life-saving system includes a controller 10, a monitoring device 20, a throwing box 50 and a life-saving robot 40. The controller 10 is communicatively connected to a monitoring device 20, and the monitoring device 20 is used to monitor the water surface condition in real time. The throwing box 50 is provided with a containing cavity 53, a throwing device 60 is arranged in the containing cavity 53, and the throwing device 60 can be driven by the controller 10; the lifesaving robot 40 can be received in the receiving cavity 53 and can be launched on water by the launching device 60 to save people intelligently.

It should be noted that the releasing device 60 can be driven by the controller 10 to include two layers, the first layer means that the releasing device 60 can be directly driven by the controller 10, and then the releasing device 60 is in communication connection with the controller 10; the second layer means that the dispensing device 60 can be indirectly driven by the controller 10, and the dispensing device 60 and the controller 10 have no direct connection relationship. In the present application, the controller 10 drives the dispensing device 60 indirectly through the dispensing box 50, and specifically, refer to the following description of the dispensing box 50 and the dispensing device 60.

In practical applications, the throwing box 50 may be placed in the edge area of various water areas prone to falling into water, and both the controller 10 and the monitoring device 20 may be installed in the throwing box 50. Of course, in other embodiments of the present application, the controller 10 and the monitoring device 20 may be disposed at a position other than the throwing box 50 according to practical rescue convenience, for example, the monitoring device 20 may be placed at a higher position on the shore or erected above the water, so as to monitor the water surface condition more comprehensively.

When the water lifesaving system works specifically, firstly, the water surface condition is monitored in real time through the monitoring equipment 20, the falling-water information is sent to the controller 10 when a person falls into the water, the controller 10 sends a control command to drive the throwing device 60 when receiving the falling-water information, the throwing device 60 starts to throw the lifesaving robot 40 into the water after being driven, and the lifesaving robot 40 automatically rescues the person.

The water lifesaving system in the embodiment can find people falling into water in time through the monitoring device 20 and can put the lifesaving robot 40 into water in time through the arrangement of the controller 10, the monitoring device 20, the putting box 50 and the lifesaving robot 40, so that the purpose of quickly rescuing people is achieved, and the response rescue speed is higher, the success rate of rescue is improved, and drowning of people is reduced.

In a specific embodiment, referring to fig. 1 and 3, the monitoring device 20 is a 360-degree panoramic camera, the 360-degree panoramic camera can monitor a coverage area of about 400 square meters without blind spots, and is provided with a fisheye lens having a 360-degree panoramic view. A360 degree panoramic camera can replace many ordinary cameras, has accomplished seamless control to the situation of the control surface of water that can be more comprehensive has ensured people's life safety. It is understood that in other embodiments of the present application, the monitoring device 20 may be a plurality of common cameras, which is not limited herein.

Referring to fig. 1 and 3, in order to improve the view of the monitoring device 20, a mounting bracket 70 is vertically installed at the top of the drop box 50, and the monitoring device 20 is mounted on the mounting bracket 70. The specific height of the mounting bracket 70 can be set according to actual experiments, and the mounting bracket 70 can also be detachably and/or height-adjustable, so that the monitoring device 20 can be conveniently installed and height-adjusted by workers according to actual needs.

In an embodiment, referring to fig. 1 and fig. 3, the water life-saving system further includes an electrical storage device, and the electrical storage device is in communication connection with the controller 10 and the monitoring device 20, respectively. Specifically, the electric power storage device is a solar charging panel 80, the solar charging panel 80 can convert solar energy into electric energy and store the electric energy, and can supply power to the monitoring device 20 and the controller 10, so that the electric energy can be saved, and meanwhile, the water life-saving system can be arranged at any required position without being arranged close to a power supply. It is to be understood that in other embodiments of the present application, the power storage device may also be a battery, and is not limited herein.

Specifically, two solar charging panels 80 are provided, and the two solar charging panels 80 are respectively and symmetrically installed on the mounting frame 70 and are arranged facing the sun.

In a specific embodiment, referring to fig. 1 and fig. 3, the water lifesaving system further includes a warning device 30 and a remote controller 90, the warning device 30 is in communication connection with the controller 10 and is used for warning when someone falls into water to remind a lifesaving person, the remote controller 90 is also accommodated in the throwing box 50, and the remote controller 90 is used for controlling the lifesaving robot 40. In actual rescue, when someone falls into water, the controller 10 sends a control command to the warning device 30 after receiving the water falling information, the warning device 30 sends a warning to remind the life-saving person to start saving the person after receiving the control command, when the life-saving person hears the warning sound, the remote controller 90 is taken out of the throwing box 50, the life-saving robot 40 is thrown into the water by the throwing device 60, and the life-saving person can control the life-saving robot 40 to rapidly reach the rescue position through the remote controller 90 and implement intelligent rescue. This application can in time remind the lifesaving personnel to implement the rescue through warning device 30, reaches quick lifesaving people's purpose, also accomodates remote controller 90 in putting in case 50 simultaneously to make the lifesaving personnel can take remote controller 90 the very first time, also can avoid remote controller 90 to lose simultaneously.

In the present application, the warning device 30 may be installed in the drop box 50, but in other embodiments of the present application, the warning device 30 may also be installed at a position other than the drop box 50, for example, the warning device 30 is installed at a position close to the lifesaver, so that the lifesaver can receive the warning signal in time. In addition, the power storage device may supply power to the warning device 30.

In this embodiment, please refer to fig. 1 and fig. 3, the warning device 30 is a warning lamp, which is also installed on the top of the mounting frame 70, and when someone falls into water, the warning lamp flashes and gives a warning sound, so as to prompt the life-saving person quickly. In other embodiments of the present application, the warning device 30 may also be a flashlight and/or a buzzer, etc., which is not limited herein.

Referring to fig. 2 and 3, an installation cavity 58 is formed in the surface of the drop box 50, specifically, the installation cavity 58 is formed in the top of the back of the drop box 50, the installation cavity 58 is used for accommodating a remote controller 90, a cover 57 is covered on the installation cavity 58, the cover 57 is locked by an electric lock 59, and the electric lock 59 is in communication connection with the controller 10. In actual rescue, when the controller 10 receives the information of falling into water, a control command is sent to the electric lock 59, and the electric lock 59 opens the cover 57, so that the life-saving person can conveniently obtain the remote controller 90 from the throwing box 50.

Specifically, the electric lock 59 includes a magnetic switch 591 and a first iron block 592, one end of the cover 57 is rotatably disposed on the releasing box 50, a third torsion spring is disposed on a rotating shaft at one end of the cover 57, and the first iron block 592 is disposed at the other end of the cover 57. Under normal conditions, the first iron block 592 is attracted to the magnetic switch 591, so that the cover 57 covers the installation cavity 58; when the controller 10 sends a control command to the magnetic attraction switch 591, the magnetic attraction switch 591 is powered on and de-energized, and the cover 57 is bounced off under the action of the third torsion spring, so that the life saving personnel can take out the remote controller 90 conveniently. It should be understood that in other embodiments of the present application, the electric lock 59 may be any other locking structure capable of locking the cover 57 to the drop box 50 and receiving a control command from the controller 10, and is not limited herein.

In an embodiment, referring to fig. 1 to 3, the drop box 50 includes a box body 51, a box cover 52, an engaging assembly 55 and a supporting assembly 56. The size and the shape of the box body 51 can be set according to the size and the shape of the launching device 60 and the lifesaving robot 40, the box cover 52 is covered on the box body 51, the box cover 52 and the box body 51 enclose to form a containing cavity 53, the attraction component 55 is in communication connection with the controller 10 and is used for attracting or separating the box cover 52 and the box body 51, and the support component 56 is connected between the box body 51 and the box cover 52 and can automatically support the box cover 52 after attraction force between the box cover 52 and the box body 51 is lost. In actual rescue, the controller 10 sends a control command to the attraction component 55, the attraction component 55 is powered off to lose attraction force between the box cover 52 and the box body 51, and the support component 56 automatically supports the box cover 52, so that the launching device 60 can launch the lifesaving robot 40 on the water surface.

Specifically, referring to fig. 4, the attraction assembly 55 includes an electromagnet 551 and a second iron block 552, one side of the box 51 is provided with a feeding opening 54 communicated with the accommodating cavity 53, the electromagnet 551 is mounted on the box 51 and located at the position of the feeding opening 54, one end of the box cover 52 is hinged to the box 51, and the other end of the box cover 52 is provided with the second iron block 552. Under the normal state, the electromagnet 551 and the second iron block 552 attract each other, so that the other end of the cover 57 and the box body 51 are attracted and locked, when the controller 10 sends a control command to the electromagnet 551, the electromagnet 551 loses magnetism and releases the second iron block 552, so that attraction force between the box cover 52 and the box body 51 is lost, and at this time, the support assembly 56 can automatically support the box cover 52. It is understood that in other embodiments of the present application, the engaging component 55 may be any other locking structure capable of locking the box cover 52 to the box body 51 and receiving a control command from the controller 10, and is not limited herein.

Referring to fig. 4, the support assembly 56 includes two gas support rods 561 symmetrically disposed on two sides of the box cover 52, and the two gas support rods 561 are respectively supported between two edge positions of the box cover 52 in the width direction and the box body 51. When the box cover 52 is attracted to the box body 51, the gas support rod 561 is linearly contracted and stores gas pressure inside, when attraction force between the box cover 52 and the box body 51 is lost, the gas support rod 561 linearly extends under the action of the gas pressure stored inside and drives the box cover 52 to rotate and open, and when the box cover 52 is opened to a limit position, the gas support rod 561 keeps the action of supporting the box cover 52, so that the lifesaving robot 40 can be smoothly thrown. It is understood that in other embodiments of the present application, the support assembly 56 may also include an electric push rod or other self-retracting structure, which is not limited herein.

In one embodiment, referring to fig. 4, the releasing device 60 includes a supporting frame 61, a bracket 62, a first releasing component 63 and a second releasing component 64. The supporting frame 61 is arranged in the accommodating cavity 53, and the bracket 62 is arranged on the supporting frame 61 in a sliding manner and can slide out from the accommodating cavity 53 to the putting-in opening 54; the lifesaving robot 40 is slidably mounted on the bracket 62 and can slide from the bracket 62 into the water. The sliding direction of the bracket 62 is the same as the sliding direction of the lifesaving robot 40, and both slide in the second direction Y, which is specifically shown in fig. 4. The first release assembly 63 is used for limiting the bracket 62 on the support frame 61 and releasing the bracket 62 after the box cover 52 is opened, and the second release assembly 64 is used for limiting the lifesaving robot 40 on the bracket 62 and releasing the lifesaving robot 40 when the bracket 62 slides to the limit position. In the launching device 60 of the present application, in the initial state, the lifesaving robot 40 is limited on the bracket 62 by the second releasing component 64, the bracket 62 is limited on the supporting frame 61 by the first releasing component 63, and the supporting frame 61, the bracket 62 and the lifesaving robot 40 are all accommodated in the accommodating cavity 53; when the box cover 52 is opened under the control of the controller 10, the first releasing assembly 63 releases the bracket 62, the bracket 62 can slide on the supporting frame 61 together with the lifesaving robot 40, specifically, slide towards the throwing port 54 of the box body 51, when the bracket 62 slides to the extreme position, the bracket 62 does not slide forwards, the second releasing assembly 64 releases the lifesaving robot 40, the lifesaving robot 40 can slide on the bracket 62, specifically, slide towards the water surface from the throwing port 54, until the bracket 62 slides into the water surface, and then the lifesaving robot 40 can be controlled by the remote controller 90. The launching device 60 of the application firstly takes the lifesaving robot 40 to slide out of the box body 51 through the bracket 62, so that the bracket 62 can be tracked with the water surface, then the lifesaving robot 40 slides into the water surface from the bracket 62, namely, the transition connection between the lifesaving robot 40 and the water surface is formed through the bracket 62, and then the lifesaving robot 40 can fall onto the water surface quickly and stably. It is understood that, in other embodiments of the present application, when the length of the lifesaving robot 40 is long enough and the position of the supporting frame 61 is low enough, the lifesaving robot 40 can be directly slid on the supporting frame 61, and the bracket 62 is omitted, which is not limited herein.

In a specific embodiment, referring to fig. 5 and fig. 6, a first slide rail 65 is disposed on the supporting frame 61, a second slide rail 66 is disposed on the bracket 62, and the second slide rail 66 is slidably disposed on the first slide rail 65; the top of the bracket 62 is also provided with a third slide rail 67, and the lifesaving robot 40 is slidably arranged on the third slide rail 67; the first slide rail 65, the second slide rail 66 and the third slide rail 67 extend in the same direction, extend in the second direction Y, and each extend obliquely downward from the inside of the storage cavity 53 toward the input port 54. When the lifesaving robot slides, the bracket 62 can slide out downwards from the support frame 61 under the action of gravity, and the lifesaving robot 40 can slide into the water surface downwards from the bracket 62 under the action of gravity, so that the lifesaving robot 40 can slide into the water surface stably, and meanwhile, the principle of gravity is utilized, the driving device is saved, and the cost is reduced.

Referring to fig. 4 and 6, the supporting frame 61 is formed by connecting and enclosing a plurality of rod members, the longitudinal section of the supporting frame 61 is trapezoidal, and the top of the supporting frame 61 has two guiding blocks 611 spaced along the first direction X. The number of the first slide rails 65 is two, and the first slide rails 65 are respectively arranged on the opposite inner sides of the two guide blocks 611, and the extending direction of the guide blocks 611 is the same as the extending direction of the first slide rails 65. The bracket 62 includes two supporting blocks 621 arranged at an interval along the first direction X and a connecting rod 622 connected between the two supporting blocks 621, the number of the second slide rails 66 is two and arranged at the lower sides of the two supporting blocks 621, and the number of the third slide rails 67 is two and arranged at the tops of the two supporting blocks 621 respectively. The first direction X is a width direction of the dispensing box 50, i.e., a front-back direction in fig. 4, and the first direction X is perpendicular to the second direction Y.

Referring to fig. 5, the third slide rail 67 includes two tank bodies 671 and a plurality of rollers 672, the two tank bodies 671 respectively extend along the second direction Y, the two tank bodies 671 are oppositely and obliquely arranged along the first direction X, a plurality of rollers 672 are distributed in each tank body 671 along the second direction Y, and the rollers 672 are accommodated in the tank bodies 671 and at least partially extend out of the tank bodies 671. The two bottoms of the lifesaving robot 40 in the first direction X are respectively received between the two tank bodies 671 and slide on the respective rollers 672. Through the arrangement of the rollers 672, the friction force between the lifesaving robot 40 and the bracket 62 is smaller, and the lifesaving robot 40 can easily slide from the bracket 62 to the water surface under the action of gravity.

In a specific embodiment, referring to fig. 4 and fig. 7, the first releasing assembly 63 includes a first pulling wire 631 and a first locking buckle 632, the first locking buckle 632 has a first pulling buckle 6327, the first locking buckle 632 further forms a first bayonet 6328, one end of the first pulling wire 631 is fixed on the case cover 52, the other end of the first pulling wire 631 is fixed on the first locking buckle 632, and the bracket 62 is provided with a pulling rod, which is the connecting rod 622. The pull rod can be clamped by the first bayonet 6328, when the cover 52 is opened to the limit position, the first pull wire 631 is straightened, the first pull wire 631 has a pulling force on the first pull buckle 6327, and the first pull buckle 6327 is pulled to open the first bayonet 6328 and release the pull rod. The first releasing component 63 of the present application, through the arrangement of the first pulling wire 631 and the first lock catch 632, can drive the first pulling wire 631 and the first lock catch 632 to release the bracket 62 when the box cover 52 is opened to the limit position, that is, the box cover 52 of the releasing box 50 is opened and the bracket 62 is released to form the linkage action, and the electric control is not needed, and the structure is simple. It is understood that in other embodiments of the present application, the first releasing component 63 may also be an electric control lock, and when the cover 52 is opened to the limit position, the electric control lock feeds back to the controller 10, and then the controller 10 controls the electric control lock to release the pull rod, which is not limited herein.

More specifically, referring to fig. 7, the first lock 632 includes a first clip 6321, a second clip 6322, a first torsion spring 6323 and a second torsion spring 6324, the first clip 6321 is hinged to the bracket 62 through a first hinge shaft 6325, two ends of the first torsion spring 6323 are respectively connected to the first hinge shaft 6325 and the bracket 62, one end of the second clip 6322 is hinged to the bracket 62 through a second hinge shaft 6326, the first pull tab 6327 is disposed at the other end of the second clip 6322, two ends of the second torsion spring 6324 are respectively connected to the second hinge shaft 6326 and the bracket 62, and the second clip 6322 and the first clip 6321 are mutually engaged and enclose to form a first bayonet 6328. In an initial state, the pull rod transversely penetrates through the first bayonet 6328 and is clamped by the first clamping piece 6321 and the second clamping piece 6322, when the first pull buckle 6327 is pulled upwards by the first pull wire 631, the second clamping piece 6322 rotates around the first hinge shaft 6325, the clamping positions of the second clamping piece 6322 and the first clamping piece 6321 are disengaged from each other, the first clamping piece 6321 rotates under the elastic action of the first torsion spring 6323, so that the pull rod is driven to be disengaged from the second clamping piece 6322, the pull rod loses the clamping force and is disengaged from the first clamping piece 6321, and the bracket 62 loses the pulling force and slides out of the support frame 61 under the action of gravity.

In an embodiment, referring to fig. 4-6, the second release element 64 includes a second wire 641, a second lock 642 and a release bar 643. The second locking buckle 642 has a second pulling buckle 6421, and the second locking buckle 642 further has a second bayonet 6422, one end of the second wire 641 is fixed on the supporting frame 61, and the other end of the second wire 641 is fixed on the second locking buckle 642. The release rail 643 is mounted on the bracket 62, and the release rail 643 can be caught by the second catch 6422 to stand upright, thereby restraining the lifesaving robot 40 on the bracket 62. When the bracket 62 is slid to the limit position, the second wire 641 is pulled to straighten the second wire 641, the second wire 641 has a pulling force on the second tab 6421, the second tab 6421 is pulled to open the second notch 6422 and release the release strip 643, the release strip 643 loses the clamping force of the second notch 6422 and falls down laterally, and the lifesaving robot 40 is released to slide the lifesaving robot 40 from the bracket 62 to the water surface. The second release assembly 64 of the present application, through the arrangement of the second pull wire 641, the second lock 642 and the release bar 643, when the bracket 62 slides to the limit position, the second pull wire 641, the second lock 642 and the release bar 643 are driven to release the lifesaving robot 40, that is, the box cover 52 of the drop box 50 is opened, the release of the bracket 62 and the release of the lifesaving robot 40 form an interlocking action, and the structure is simple and does not need to be electrically controlled. It is understood that in other embodiments of the present application, the second releasing component 64 may also be an electrically controlled lock, and when the carriage 62 slides to the extreme position, the electrically controlled lock is fed back to the controller 10, and then the controller 10 controls the electrically controlled lock to release the releasing rail 643, which is not limited herein.

The structure of the second lock 642 is the same as that of the first lock 632 in this application, and the operation principle is the same, which will not be described repeatedly.

Referring to fig. 4 to 6, in order to make the restraining and releasing of the robot 40 uniform along the first direction X, two sets of the second releasing assemblies 64 are provided and spaced along the first direction X. Correspondingly, the release rail 643 includes two upright posts 6431 and a rail 6432, the two upright posts 6431 are spaced along the first direction X, and the rail 6432 is connected between the two upright posts 6431. Since the two second lock catches 642 are both arranged at a certain height of the bracket 62, when the upright post 6431 is clamped by the second lock catches 642, the upright post 6431 is in an upright state, and the rail 6432 extends in the first direction X and has a certain height, so as to block the sliding of the lifesaving robot 40; when the vertical rod 6431 is released by the second lock 642, the vertical rod 6431 falls down without supporting force, the rail 6432 falls down, the life-saving robot 40 is not blocked by the rail 6432, and the life-saving robot 40 slides to the water surface under the action of gravity.

The above description is only exemplary of the present application and should not be taken as limiting the present application, as any modification, equivalent replacement, or improvement made within the spirit and principle of the present application should be included in the protection scope of the present application.

Claims (10)

1. A water life saving system, comprising:

a controller (10);

a monitoring device (20) communicatively connected to the controller (10) and configured to monitor water surface conditions in real time;

a dosing box (50) having a receiving cavity (53), a dosing device (60) being arranged in the receiving cavity (53), the dosing device (60) being drivable by the controller (10);

and the lifesaving robot (40) can be accommodated in the accommodating cavity (53) and can be thrown onto water by the throwing device (60) to intelligently save people.

2. A water life-saving system as claimed in claim 1, further comprising an electrical storage device (80), the electrical storage device (80) being in communication with the controller (10) and the monitoring device (20), respectively.

3. A water life-saving system as claimed in claim 1, further comprising a warning device (30) and a remote controller (90), wherein the warning device (30) is in communication with the controller (10) and is configured to warn when a person falls into water, and the remote controller (90) is received in the launch box (50) and is configured to control the life-saving robot (40).

4. The water life-saving system of claim 3, characterized in that the surface of the throwing box (50) is provided with a mounting cavity (58) for receiving the remote controller (90), the mounting cavity (58) is covered with a cover body (57), the cover body (57) is locked by an electric lock (59), and the electric lock (59) is in communication connection with the controller (10).

5. Water life-saving system according to any one of claims 1 to 4, wherein the launch box (50) comprises:

a case (51);

the box cover (52) is arranged on the box body (51) in a covering mode and forms the containing cavity (53) with the box body (51) in an enclosing mode;

the suction component (55) is in communication connection with the controller (10) and is used for sucking or separating the box cover (52) from the box body (51);

the supporting component (56) is connected between the box body (51) and the box cover (52) and can automatically support the box cover (52) after the box cover (52) and the box body (51) lose suction force.

6. A water life saving system as claimed in claim 5, wherein the launch device (60) comprises:

a support frame (61);

the bracket (62) is arranged on the supporting frame (61) in a sliding mode, and can slide out from the containing cavity (53) to the putting-in opening (54); the lifesaving robot (40) is arranged on the bracket (62) in a sliding manner and can slide into the water surface from the bracket (62);

a first release assembly (63) for restraining the bracket (62) on the support frame (61) and releasing the bracket (62) after the lid (52) is opened;

a second release assembly (64) for restraining the lifesaving robot (40) on the carriage (62) and releasing the lifesaving robot (40) when the carriage (62) slides to an extreme position.

7. The water lifesaving system of claim 6 wherein the support frame (61) is provided with a first slide rail (65), the bracket (62) is provided with a second slide rail (66), and the second slide rail (66) is slidably arranged on the first slide rail (65); the top of the bracket (62) is also provided with a third sliding rail (67), and the lifesaving robot (40) is arranged on the third sliding rail (67) in a sliding manner; the first slide rail (65), the second slide rail (66) and the third slide rail (67) extend in the same direction, and both extend obliquely downwards towards the throwing opening (54) from the inside of the accommodating cavity (53).

8. A water life saving system as claimed in claim 6, wherein the first release assembly (63) comprises:

a first pulling wire (631) having one end fixed to the case cover (52);

the first lock catch (632) is mounted on the support frame (61), the first lock catch (632) is provided with a first pull buckle (6327), the other end of the first pull wire (631) is fixed on the first pull buckle (6327), and a first bayonet (6328) is formed in the first lock catch (632);

the bracket (62) is provided with a pull rod which can be clamped by the first bayonet (6328), the first pull wire (631) is straightened when the box cover (52) is opened to the limit position, and the first pull buckle (6327) can be pulled to enable the first bayonet (6328) to release the pull rod.

9. The water life saving system of claim 8, wherein the first lock catch (632) comprises:

a first jaw (6321) hinged to said carriage (62);

one end of the second clamping piece (6322) is hinged to the bracket (62), the first pull buckle (6327) is arranged at the other end of the second clamping piece (6322), and the second clamping piece (6322) and the first clamping piece (6321) are clamped with each other and enclose to form the first bayonet (6328);

a first torsion spring (6323) having both ends connected to the first hinge shaft (6325) of the first clip piece (6321) and the bracket (62), respectively;

and the two ends of the second torsion spring (6324) are respectively connected with the second hinge shaft (6326) of the second clamping piece (6322) and the bracket (62).

10. A water life saving system as claimed in claim 6, wherein the second release assembly (64) comprises:

a second pull wire (641) having one end fixed to the support frame (61);

the second lock catch (642) is mounted on the bracket (62), the second lock catch (642) is provided with a second pull buckle (6421), the other end of the second pull wire (641) is fixed on the second pull buckle (6421), and a second bayonet (6422) is formed on the second lock catch (642);

a release fence (643) mounted on the bracket (62) and capable of restraining the lifesaving robot (40); the release rail (643) can be caught by the second catch (6422), the second pull wire (641) can pull the second pull buckle (6421) when the bracket (62) slides to the limit position so that the second catch (6422) releases the release rail (643), and the release rail (643) falls down to release the lifesaving robot (40).

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