CN109935128B - Container type simulated electric shock and electricity safety and safety helmet collision experience hall - Google Patents

Abstract

The invention discloses a container type simulated electric shock and electricity safety and safety helmet collision experience library, which comprises a box body capable of being carried by mechanical equipment, wherein an electric shock feeling simulation experience device, an electric overload electric leakage simulation device capable of simulating automatic tripping of a power distribution cabinet when electric leakage and overload occur to electric equipment are arranged in the box body, and an electric safety helmet collision experience device capable of simulating automatic tripping of an object collision head are arranged in the box body. The invention has the advantages of comprehensive experience items, safety, reliability, working of laminating constructors and good safety education effect.

Description

Container type simulated electric shock and electricity safety and safety helmet collision experience hall

Technical Field

The invention belongs to the technical field of safety simulation experience equipment, and particularly relates to a container type simulation electric shock and electricity utilization safety and safety helmet collision experience hall.

Background

Currently, the construction industry is entering a transition high-speed development period. The building department provides the building industry with the problems of extensive development mode, low skill quality of building workers and the like in the building industry. The safety experience equipment for the building engineering is generated, so that all participants in the construction activities, especially peasant construction workers, can personally experience electric shock, electricity consumption or head impact injuries in the construction production activities, thereby leading the participants to experience the importance of the correct and standardized construction activities. The construction engineering safety experience equipment plays an important role in cultivating the safety consciousness of constructors and improving the safety quality of construction workers.

However, the existing security experience devices still have the following drawbacks during actual use: 1. the safety experience content is incomplete, the safety experience of the existing simulation electric shock and electricity consumption safety related experience equipment is only simple to perform electric shock experience, and the related electricity consumption safety experience equipment in actual construction operation is not provided; 2. the existing experience equipment has weak guidance on safe construction, the existing simulation electric shock and electricity safety and safety cap collision experience equipment deviates from daily work content of constructors and is disjointed from actual construction conditions, and the constructors cannot be helped to experience improper electricity consumption and have no harm to themselves caused by the safety cap, so that the guidance meaning on the safe construction of the constructors on the construction site is lower.

Disclosure of Invention

The invention aims to overcome the defects in the prior art, and provides a container type simulated electric shock and electricity safety and safety helmet collision experience hall which has the advantages of comprehensive experience items, safety and reliability, working of laminating constructors and good safety education effect.

In order to achieve the above purpose, the invention adopts the following technical scheme: the utility model provides a house is experienced with crash of helmet to container formula simulation electric shock and power consumption safety, its characterized in that: including the box that can carry with the help of mechanical equipment, be provided with in the box and supply alone to experience the simulation electric shock that electric shock felt and experience the device, can supply alone to experience the simulation construction electricity that the switch board automatic trip was used to live and is experienced the device and can supply two human body to examine the simulation safety helmet striking experience device of object striking head when electric leakage and overload appear, the box includes right side board, bottom plate, backplate, the left side board that sets up relatively with the right side board, the roof that sets up relatively with the bottom plate and the rolling slats door that sets up relatively with the backplate, right side board, left side board, bottom plate, roof, backplate and rolling slats door enclose into the box of a cuboid structure jointly, the front side of roof and the housing fixed connection of rolling slats door, the rear side is provided with the baffle in the box, the baffle is parallel and be located the place ahead of backplate, leave the distance between baffle and the backplate, the simulation construction electricity is used to live the device nestification and is experienced the right side of baffle, the simulation construction electricity is experienced the right side board and is used the device and is fixed on the inner wall of baffle.

Foretell container formula simulation electric shock and power consumption safety and helmet striking experience the pavilion, its characterized in that: the electric shock simulation device comprises an electric shock control module, an electric shock simulation device box, a touch power supply, an electric shock touch display screen and two discharge balls, wherein the electric shock touch display screen is arranged on the upper portion of the front side of the electric shock simulation device box, a drawer capable of being pulled is arranged in the middle of the front side of the electric shock simulation device box, the two discharge balls are fixed in the drawer, a distance is reserved between the two discharge balls, and the electric shock control module and the touch power supply are arranged in the electric shock simulation device box; the electric shock control module comprises an electric shock main control module, a direct current module, an alternating current module and a pulse current module, wherein the output end of the electric shock main control module is connected with the input end of the direct current module, the input end of the alternating current module and the input end of the pulse current module respectively to control the direct current module, the alternating current module and the pulse current module to work, the touch keys of the electric shock touch display screen comprise direct voltage electric shock keys, alternating voltage electric shock keys, pulse voltage electric shock keys, video keys and voice keys, the electric shock main control module is in bidirectional connection with the electric shock touch display screen and can receive experience instructions, voice instructions and video instructions sent by the electric shock touch display screen and send voice information and video information to the electric shock touch display screen to display and play, the output end of the electric shock main control module is also connected with the electric shock main control module and adjusts the voltage intensity of the electric shock main control module according to the instructions received by the electric shock main control module, the input end of the direct current module and the input end of the pulse current module are respectively transmitted to the direct current module, the electric shock main control module and the input end of the pulse current module and the pulse current module are respectively after the voltage intensity is adjusted by the main control module, the two electric shock main control module and the two electric current main control modules are respectively connected with the two electric ball-type electric shock main control module and the two electric ball electric shock main control module are respectively connected with the two electric ball electric balls respectively, the output end of the pulse current module is connected with the two discharge balls, and the input sensing power supply current is converted into pulse current and then is transmitted to the two discharge balls respectively.

Foretell container formula simulation electric shock and power consumption safety and helmet striking experience the pavilion, its characterized in that: the pulse current module is a MOS tube module, the discharge ball is a stainless steel ball, the diameter of the discharge ball is smaller than 80mm, and the inductive power supply is a 6V battery power supply.

Foretell container formula simulation electric shock and power consumption safety and helmet striking experience the pavilion, its characterized in that: the safety helmet impact experience device comprises an impact control module, two impact experience boxes, a remote controller capable of remotely controlling the operation of the impact experience boxes and two safety helmets for protecting heads during impact experience, the two impact experience boxes are identical in structure, each impact experience box comprises an impact experience box body, a solid hemisphere, an indicator light, a rope, an electromagnetic clutch, a motor and a guide wheel, the motor, the electromagnetic clutch and the guide wheels are all arranged in the impact experience box body, the motor is fixedly connected with the inner wall of the impact experience box body, the input end of the electromagnetic clutch is connected with the output shaft of the motor, the guide wheels are composed of a first guide wheel, a second guide wheel and a guide wheel shaft, the first guide wheel and the second guide wheel are respectively arranged at two ends of the guide wheel shaft, the output end of the electromagnetic clutch is connected with one end of the guide wheel shaft close to the electromagnetic clutch, the guide wheel shaft is connected with one end of the rope, the other end of the rope vertically penetrates through the lower part of the impact experience box body and then is connected with the center of the round surface of the solid hemisphere, and the indicator light is arranged at the outer side of the impact experience box body, and the indicator light is turned on after the power supply is turned on; the remote controller is in wireless connection with the impact control module and transmits a remote control instruction to the impact control module, the output end of the impact control module is connected with the electromagnetic clutch and controls the electromagnetic clutch to combine or separate the guide wheel shaft from the output end of the motor according to the remote control instruction, and the output end of the impact control module is also connected with the motor and controls the motor to start or stop according to the remote control instruction.

Foretell container formula simulation electric shock and power consumption safety and helmet striking experience the pavilion, its characterized in that: the impact control module is a two-way single-way control switch.

Foretell container formula simulation electric shock and power consumption safety and helmet striking experience the pavilion, its characterized in that: the overload leakage experience device comprises an overload leakage touch display screen, an overload leakage control module, a plurality of breakers, three simulation overload resistors, an electric welding indicator lamp simulating an electric welding working state and an illumination indicator lamp simulating an illumination lamp working state, wherein the overload leakage control module comprises an overload leakage main control module, a first transformer, a second transformer and a third transformer, the output end of the overload leakage main control module is connected with the first transformer, the second transformer and the third transformer and respectively controls the first transformer, the second transformer and the third transformer to work, the overload leakage touch display screen is provided with a second-level power distribution overload key, a third-level illumination leakage key, a third-level electric welding overload key, a third-level electric welding leakage key and a reset key, the overload leakage main control module is in bidirectional connection with the overload leakage touch display screen and can receive experience instructions and reset instructions sent by the overload leakage touch display screen and send data information corresponding instructions to the overload leakage touch display screen to be displayed by the overload leakage touch display screen, and the overload leakage main control module is connected with the overload main control module; the three simulated overload resistors comprise a second-stage simulated overload resistor, a third-stage lighting simulated overload resistor and a third-stage electric welding simulated overload resistor, the plurality of circuit breakers comprise a second-stage total circuit breaker, a second-stage overload circuit breaker, a second-stage electric leakage circuit breaker, a third-stage lighting overload circuit breaker, a third-stage lighting electric leakage circuit breaker and a third-stage electric welding electric leakage circuit breaker, one end of the second-stage simulated overload resistor is connected with the positive electrode of the second-stage total circuit breaker, the negative electrode of the second-stage total circuit breaker is connected with the positive electrode of the second-stage overload circuit breaker, so that the negative electrode of the second-stage overload circuit breaker is connected with the positive electrode of the second-stage electric leakage circuit breaker, and the other ends of the second-stage electric leakage circuit breaker and the second-stage simulated overload resistor are connected with a first transformer and the first transformer is controlled by an overload electric leakage main control module to work and the second-stage total circuit breaker, the second-stage overload circuit breaker and the second-stage electric leakage circuit breaker are subjected to power-off protection by increasing the input current of the second-stage simulated overload resistor; one end of the three-level lighting simulation overload resistor is connected with the positive electrode of the three-level lighting overload breaker, the negative electrode of the three-level lighting overload breaker is connected with the positive electrode of the three-level lighting leakage breaker, the other end of the three-level lighting simulation overload resistor and the negative electrode of the three-level lighting leakage breaker are connected with the second transformer, the overload leakage master control module controls the second transformer to work, and the input current of the three-level lighting simulation overload resistor is increased to enable the three-level lighting overload breaker and the three-level lighting leakage breaker to perform power-off protection; one end of the three-stage electric welding simulation overload resistor is connected with the positive electrode of the three-stage electric welding overload breaker, the negative electrode of the three-stage electric welding overload breaker is connected with the positive electrode of the three-stage electric welding leakage breaker, the other end of the three-stage electric welding simulation overload resistor and the negative electrode of the three-stage electric welding leakage breaker are connected with the third transformer, the third transformer is controlled to work by the overload leakage main control module, and the three-stage electric welding overload breaker and the three-stage electric welding leakage breaker are subjected to power-off protection by increasing the input current of the three-stage electric welding simulation overload resistor.

Foretell container formula simulation electric shock and power consumption safety and helmet striking experience the pavilion, its characterized in that: the power distribution pictures are adhered to the outer sides of the partition boards, the power distribution pictures comprise transformer pictures, primary distribution box pictures, secondary distribution box pictures, tertiary illumination distribution box pictures, tertiary electric welding distribution box pictures, electric welding tool pictures and illumination lamp pictures, and the secondary analog overload resistor, the secondary total circuit breaker, the secondary overload circuit breaker and the secondary electric leakage circuit breaker are nested on the partition boards at the positions of the secondary distribution box pictures; the three-level illumination simulated overload resistor, the three-level illumination overload breaker and the three-level illumination leakage breaker are nested on a partition board at the picture position of the three-level illumination distribution box; the electric welding device comprises an electric welding tool picture, an electric welding display screen, a transformer picture, a primary distribution box picture, a secondary distribution box picture, a tertiary electric welding tool picture, an electric welding tool picture and an illumination lamp picture, wherein the electric welding simulation overload resistor, the tertiary electric welding overload circuit breaker and the tertiary electric welding leakage circuit breaker are all nested on a partition board at the picture position of the tertiary electric welding distribution box picture, the illumination lamp is nested on the partition board at the picture position of the illumination lamp picture, the electric welding display screen is nested on the partition board and surrounded by the transformer picture, the primary distribution box picture, the secondary distribution box picture, the tertiary electric welding distribution box picture, the electric welding tool picture and the illumination lamp picture, and the electric welding leakage control module is arranged at the rear of the partition board.

Foretell container formula simulation electric shock and power consumption safety and helmet striking experience the pavilion, its characterized in that: the box is the container, the length of box is 4.5m, width is 2.4m, high is 2.5m, perpendicular distance L between baffle and the backplate is 0.5m.

Foretell container formula simulation electric shock and power consumption safety and helmet striking experience the pavilion, its characterized in that: the plurality of breakers are plastic shell breakers with working current ranges of 10A-1050A.

Compared with the prior art, the invention has the following advantages:

1. the invention synthesizes various experience devices, relates to three experience items of an electric shock simulation experience device, an electricity overload and leakage simulation construction experience device and a crash safety helmet simulation experience device, has rich and comprehensive safety experience content, can bring better safety experience feeling to an experimenter, solves the problem that more mechanical devices and labor force need to be mobilized in the process of installing and dismantling due to scattered original devices, and saves operation cost and time cost.

2. The container body adopts the standardized container, can meet the experience requirements of different regions, brings great convenience to transportation and improves the turnover rate.

3. The invention can directly use mechanical equipment to carry out loading and unloading through the integrated action of the container type, so that the installation, dismantling and arrangement work is saved, and the problem of delaying the user experience due to bad weather effect is solved because of the protection of the container body.

4. The container type experience hall disclosed by the invention also saves a large amount of occupied area, has the advantage of small occupied area, and particularly provides convenience for construction projects with narrow construction sites.

5. The safety experience device is safe and reliable, the safety of safety experience personnel can be practically guaranteed, the safety experience content is suitable for the actual working environment, the simulation effect is good, and the safety education effect is good.

The invention is described in further detail below with reference to the drawings and examples.

Drawings

Fig. 1 is a front view of the internal structure of the present invention.

Fig. 2 is a top view of the internal structure of the present invention.

Fig. 3 is a schematic block diagram of a device for simulating an electric shock experience according to the present invention.

Fig. 4 is a side view of the impact experience pod of the present invention.

Fig. 5 is a front view of the impact experience pod of the present invention.

Fig. 6 is a schematic block diagram of a device for simulating a crash experience of a helmet in accordance with the present invention.

Fig. 7 is a schematic structural diagram of the device for simulating the construction electricity overload and leakage experience.

Fig. 8 is a schematic block diagram of a device for simulating the overload and leakage experience of construction electricity.

Fig. 9 is a schematic structural view of the crash helmet crash experience device according to the present invention.

Reference numerals illustrate:

1-simulating an electric shock experience device; 2, simulating a construction electricity overload and leakage experience device;

3-simulating a crash experience device of the helmet; 4-1-right side plate;

4-2-left side plate; 4-3-separator; 4-backboard;

4-5-rolling shutter door; 4-6, a bottom plate; 4-7-top plate;

5-a discharge ball; 6, simulating an electric shock experience device box body;

7-electric shock touch display screen; 7-1, a direct-current voltage electric shock key;

7-2-alternating voltage electric shock keys; 7-3, pulse voltage electric shock key;

7-4, video buttons; 7-5, voice key; 8-a touch power supply;

9, an electric shock control module; 9-1, an electric shock main control module; 9-2-direct current module;

9-3-an alternating current module; 9-4, a pulse current module; 10-solid hemispheres;

11-an indicator light; 12-rope; 13, a remote controller;

14-a safety helmet; 15-an impact control module;

17-an impact experience box; 17-1, a guide wheel; 17-2-electromagnetic clutch;

17-3-motor; 17-11-a first guide wheel; 17-12, a second guide wheel;

17-13, a guide wheel shaft; 17-33-output shaft; 18-transformer pictures;

19-first-level distribution box pictures; 20-a second-level distribution box picture; 16-drawer;

20-1-a secondary leakage master switch; a 20-2-second level overload breaker;

20-3-second-level leakage breaker; 20-4-two-stage analog overload resistor;

21-three-level illumination distribution box pictures; 21-1-three-stage lighting overload breaker;

21-2-three-stage lighting leakage breaker; 21-3 three-stage lighting simulation overload resistor;

22-three-level electric welding distribution box pictures; 22-1-three-stage electric welding overload breaker;

22-2-three-stage electric welding leakage breaker; 22-3-three stages of electric welding simulation overload resistors;

23-electric welding tool pictures; 23-1, an electric welding indicator lamp;

24-lighting fixture pictures; 24-1, an illumination indicator lamp;

25-overload leakage touch display screen; 25-1-second level electricity distribution overload key;

25-2-three-level lighting overload keys; 25-3-three-stage lighting leakage keys;

25-4-three stages of electric welding overload keys; 25-5-three-stage electric welding leakage keys;

25-6, reset key; 26-an overload leakage control module;

26-1, an overload leakage main control module; 26-2—a first transformer;

26-3—a second transformer; 26-4-third transformer.

Detailed Description

As shown in fig. 1 and 2, the electric shock simulation device comprises a box body which can be carried by mechanical equipment, wherein an electric shock simulation experience device 1 which can be used for a person to experience electric shock feeling, an electric overload leakage simulation device 2 which can be used for a person to experience automatic tripping of a power distribution cabinet when electric leakage and overload occur on electric equipment, and an electric safety helmet collision experience device 3 which can be used for two human bodies to examine an object collision head are arranged in the box body, the box body comprises a right side plate 4-1, a bottom plate 4-6, a back plate 4-4, a left side plate 4-2 which is arranged opposite to the right side plate 4-1, a top plate 4-7 which is arranged opposite to the bottom plate 4-6, and a rolling shutter door 4-5 which is arranged opposite to the back plate 4-4, the right side plate 4-1, the left side plate 4-2, the bottom plate 4-6, the top plate 4-7, the back plate 4-5 and the rolling shutter door 4-5 are jointly enclose into a box body with a cuboid structure, the front side of the top plate 4-7 is fixedly connected with a cover shell of the rolling shutter door 4-5, a partition plate 4-3 is arranged on the rear side in the box body, the partition plate 4-3 is fixedly arranged on the front side of the box body, the partition plate 4-3 is fixed on the back plate 4-4, the partition plate 4-4 is fixed on the front side 4-4, and the electric safety helmet collision simulation device is fixed on the top 4-4, and the top 4-4 is fixed on the top of the back plate 4, and the electric safety device, and the electric shock simulation device is fixed on the top side.

As shown in fig. 1 and fig. 3, the electric shock simulation experience device 1 includes an electric shock control module 9, an electric shock simulation experience device box 6, a touch sensing power supply 8, an electric shock touch display screen 7 and two discharge balls 5, wherein the electric shock touch display screen 7 is arranged at the upper part of the front side of the electric shock simulation experience device box 6, a drawer 16 capable of being pulled is arranged in the middle of the front side of the electric shock simulation experience device box 6, two discharge balls 5 are fixed in the drawer 16, a distance is reserved between the two discharge balls 5, and the electric shock control module 9 and the touch sensing power supply 8 are arranged in the electric shock simulation experience device box 6; the electric shock control module 9 comprises an electric shock main control module 9-1, a direct current module 9-2, an alternating current module 9-3 and a pulse current module 9-4, wherein the output end of the electric shock main control module 9-1 is connected with the input end of the direct current module 9-2, the input end of the alternating current module 9-3 and the input end of the pulse current module 9-4 respectively and controls the direct current module 9-2, the alternating current module 9-3 and the pulse current module 9-4 to work, the touch keys of the electric shock touch display screen 7 comprise direct voltage electric shock keys 7-1, alternating voltage electric shock keys 7-2, the pulse voltage electric shock keys 7-3, video keys 7-4 and voice keys 7-5, the electric shock main control module 9-1 is connected with the electric shock touch display screen 7 in a two-way manner and can receive experience instructions, voice instructions and video instructions sent by the electric shock touch display screen 7 and send voice information and video information to the touch display screen 7 for display and playing, the output end of the main control module 9-1 is also connected with an electric shock power supply 8 and adjusts the intensity of the electric shock main control module 9-1 and the electric shock power supply module 9-4 through the direct current power supply module 9-2 and the pulse current module 9-4 respectively, the output end of the direct current module 9-2 is connected with the two discharge balls 5, the input current of the induction power supply 8 is converted into direct current and then is transmitted to the two discharge balls 5 respectively, the output end of the alternating current module 9-3 is connected with the two discharge balls 5, the input current of the induction power supply 8 is converted into alternating current and then is transmitted to the two discharge balls 5 respectively, and the output end of the pulse current module 9-4 is connected with the two discharge balls 5, and the input current of the induction power supply 8 is converted into pulse current and then is transmitted to the two discharge balls 5 respectively.

In this embodiment, the electric shock touch display screen 7 may further set a system setting key to set brightness and contrast of the electric shock touch display screen 7, the pulse current module 9-4 is a MOS tube module, the discharge ball 5 is a stainless steel ball, a diameter of the discharge ball 5 is less than 80mm, and the inductive power supply 8 is a 6V battery power supply.

As shown in fig. 4, 5 and 6, the crash helmet crash experience device 3 comprises a crash control module 15, two crash experience boxes, a remote controller 13 capable of remotely controlling the operation of the crash experience boxes, and two safety helmets 14 for protecting heads during crash experience, wherein the two crash experience boxes have the same structure, the crash experience boxes comprise a crash experience box body 17, a solid hemisphere 10, an indicator lamp 11, a rope 12, an electromagnetic clutch 17-2, a motor 17-3 and a guide wheel 17-1, the motor 17-3, the electromagnetic clutch 17-2 and the guide wheel 17-1 are all arranged in the crash experience box body 17, the motor 17-3 is fixedly connected with the inner wall of the crash experience box body 17, the input end of the electromagnetic clutch 17-2 is connected with the output shaft of the motor 17-3, the guide wheel 17-1 consists of a first guide wheel 17-11, a second guide wheel 17-12 and a guide wheel shaft 17-13, the first guide wheel 17-11 and the second guide wheel 17-12 are respectively arranged at the guide wheel shaft 17-13, the electromagnetic clutch 17-2 and the guide wheel shaft 17-12 are respectively arranged at the lower end of the guide wheel shaft 13, the electromagnetic clutch 17-12 is connected with the outer side of the guide wheel shaft 12 and the end of the power supply box 17, the electromagnetic clutch is connected with the end of the guide wheel shaft 17-13 at the end of the power supply box 17, and the end of the guide wheel is connected with the end of the guide wheel shaft 17-13 at the end of the power supply box 17-13; the remote controller 13 is in wireless connection with the impact control module 15 and transmits a remote control instruction to the impact control module 15, the output end of the impact control module 15 is connected with the electromagnetic clutch 17-2 and controls the electromagnetic clutch 17-2 to combine or separate the guide wheel shaft 17-13 from the output end of the motor 17-3 according to the remote control instruction, and the output end of the impact control module 15 is also connected with the motor 9-3 and controls the motor 17-3 to start or stop according to the remote control instruction.

In this embodiment, the impact control module 15 is a two-way control switch.

As shown in fig. 7 and 8, the electricity overload leakage experience device 2 for simulating construction comprises an overload leakage touch display screen 25, an overload leakage control module 26, a plurality of breakers, three electric welding indicator lamps 23-1 simulating an electric welding working state and illumination indicator lamps 24-1 simulating an illumination working state, wherein the overload leakage control module 26 comprises an overload leakage main control module 26-1, a first transformer 26-2, a second transformer 26-3 and a third transformer 26-4, the output end of the overload leakage main control module 26-1 is connected with the first transformer 26-2, the second transformer 26-3 and the third transformer 26-4 and respectively controls the first transformer 26-2, the second transformer 26-3 and the third transformer 26-4 to work, a second-level electricity distribution overload key 25-1, a third-level illumination overload key 25-2, a third-level illumination overload key 25-3, a third-level electric welding key 25-4, a third-level electricity leakage key 25-5 and a reset key 25-6 are arranged on the overload leakage touch display screen 25, the output end of the overload leakage main control module 26-1 is connected with the first transformer 26-2, the second transformer 26-3 and the third transformer 26-4 are respectively controlled to work, the overload leakage touch display screen 25 is capable of sending an instruction corresponding to the overload leakage touch display screen 25 and receiving the overload leakage touch display screen and sending the instruction to the overload touch display screen and receiving the instruction, the electric welding indicator lamp 23-1 and the illumination indicator lamp 24-1 are connected with the output end of the overload leakage main control module 26-1 and are controlled to work by the overload leakage main control module 26-1; the three simulated overload resistors comprise a second-stage simulated overload resistor 20-4, a third-stage lighting simulated overload resistor 21-3 and a third-stage electric welding simulated overload resistor 22-3, the plurality of circuit breakers comprise a second-stage total circuit breaker 20-1, a second-stage overload circuit breaker 20-2, a second-stage electric leakage circuit breaker 20-3, a third-stage lighting overload circuit breaker 21-1, a third-stage lighting electric leakage circuit breaker 21-2, a third-stage electric welding overload circuit breaker 22-1 and a third-stage electric welding electric leakage circuit breaker 22-2, one end of the second-stage simulated overload resistor 20-4 is connected with the positive electrode of the second-stage total circuit breaker 20-1, the negative electrode of the second-stage total circuit breaker 20-1 is connected with the positive electrode of the second-stage overload circuit breaker 20-2, the negative electrode of the second-stage overload circuit breaker 20-3 and the other end of the second-stage simulated resistor 20-4 are connected with a first transformer 26-2, and the first-stage electric leakage main control module 26-1 controls the first-2 and the second-stage electric leakage circuit breaker 20-2 to work through the second-stage simulated overload resistor 20-3 to enable the second-stage overload circuit breaker 20-2 to be connected with the positive electrode of the second-stage overload circuit breaker 20-2; one end of the three-level lighting simulation overload resistor 21-3 is connected with the positive electrode of the three-level lighting overload breaker 21-1, the negative electrode of the three-level lighting overload breaker 21-1 is connected with the positive electrode of the three-level lighting leakage breaker 21-2, the other end of the three-level lighting simulation overload resistor 21-3 and the negative electrode of the three-level lighting leakage breaker 21-2 are both connected with the second transformer 26-3, the overload leakage master control module 26-1 controls the second transformer 26-3 to work, and the input current of the three-level lighting simulation overload resistor 21-3 is increased to enable the three-level lighting overload breaker 21-1 and the three-level lighting leakage breaker 21-2 to perform power-off protection; one end of the three-stage electric welding simulation overload resistor 22-3 is connected with the positive electrode of the three-stage electric welding overload breaker 22-1, the negative electrode of the three-stage electric welding overload breaker 22-1 is connected with the positive electrode of the three-stage electric welding leakage breaker 22-2, the other end of the three-stage electric welding simulation overload resistor 22-3 and the negative electrode of the three-stage electric welding leakage breaker 22-2 are connected with the third transformer 26-4, the third transformer 26-4 is controlled to work by the overload leakage main control module 26-1, and the three-stage electric welding overload breaker 22-1 and the three-stage electric welding leakage breaker 22-2 are subjected to power-off protection by increasing the input current of the three-stage electric welding simulation overload resistor 22-3.

As shown in fig. 2, a distribution picture is stuck on the outer side of the partition board 4-3, the distribution picture comprises a transformer picture 18, a first-stage distribution box picture 19, a second-stage distribution box picture 20, a third-stage illumination distribution box picture 21, a third-stage electric welding distribution box picture 22, an electric welding tool picture 23 and an illumination lamp picture 24, and the second-stage analog overload resistor 20-4, the second-stage total breaker 20-1, the second-stage overload breaker 20-2 and the second-stage leakage breaker 20-3 are nested on the partition board 4-3 at the position of the second-stage distribution box picture 20; the three-level illumination simulated overload resistor 21-3, the three-level illumination overload breaker 21-1 and the three-level illumination leakage breaker 21-2 are all nested on the partition board 4-3 at the position of the three-level illumination distribution box picture 21; the three-stage electric welding simulation overload resistor 22-3, the three-stage electric welding overload breaker 22-1 and the three-stage electric welding leakage breaker 22-2 are all nested on the partition board 4-3 at the position of the three-stage electric welding distribution box picture 22, the illumination indicator lamp 24-1 is nested on the partition board 4-3 at the position above the illumination lamp picture 24, the electric welding indicator lamp 23-1 is nested on the partition board 4-3 at the position above the electric welding tool picture 23, the overload leakage touch display screen 25 is nested on the partition board 4-3 and is surrounded by the transformer picture 18, the primary distribution box picture 19, the secondary distribution box picture 20, the three-stage illumination distribution box picture 21, the three-stage electric welding distribution box picture 22, the electric welding tool picture 23 and the illumination lamp picture 24, the overload leakage control module 26 is arranged behind the partition board 4-3, the connecting line of the secondary total breaker 20-1 and the secondary simulation overload resistor 20-4 is arranged behind the partition board 4-3, the connecting line of the secondary total breaker 20-1 and the electric welding tool 20-2 is arranged behind the partition board 4, the connecting line of the secondary overload breaker 20-2 is arranged behind the three-stage electric welding tool 22-3, the three-stage electric leakage control module is arranged behind the partition board 22-3, the connecting wire of the three-level illumination leakage breaker 21-1 and the three-level illumination simulated overload resistor 21-3 is arranged behind the partition board 4-3, and the connecting wire of the three-level illumination leakage breaker 21-1 and the three-level illumination overload breaker 21-2 is arranged behind the partition board 4-3.

In this embodiment, the box is a container, the length of the box is 4.5m, the width of the box is 2.4m, the height of the box is 2.5m, and the vertical distance L between the partition board 4-3 and the back board 4-4 is 0.5m.

In the embodiment, the plurality of breakers are plastic shell breakers with working current ranges of 10A-1050A.

The safety helmet collision simulation device comprises three experience items of a simulation electric shock experience device, a simulation construction electricity overload and leakage experience device and a simulation safety helmet collision experience device, wherein the simulation electric shock experience device aims at experiencing electric shock feeling, and the safety electricity consciousness is enhanced; the device for simulating the overload and electric leakage experience of the construction electricity consumption aims to truly experience the automatic tripping action process of each protection switch when the protection circuit is safe through the simulation of the electric leakage and overload phenomena of the secondary power distribution and the tertiary power distribution when the electric equipment works, understand the principle and further learn the fault processing method; the invention discloses a safety helmet collision experience simulation device, which aims to enable an experimenter to truly feel the force of object collision and the safety protection guarantee brought by the safety helmet to the experimenter by actually simulating the collision process of the safety helmet worn by the experimenter, and can simultaneously meet the safety education experience of four people by looking forward at the importance of the safety helmet.

The three experience procedures of the electric shock simulation experience device, the construction electricity overload leakage simulation experience device and the safety helmet collision simulation experience device are respectively described in detail below.

1. The experience process of the electric shock simulation experience device is as follows:

and selecting a voice key 7-5 in the infrared electric shock touch display screen 7, adjusting the volume of the voice prompt, returning to the main page, and opening the drawer 16.

The experience process of the simulation electric shock experience device is that the device experiences direct-current voltage electric shock, alternating-current voltage electric shock and pulse voltage electric shock, and the simulation electric shock experience device is specifically as follows:

1. and (3) experiencing direct-current voltage electric shock: according to the voice prompt content, a direct-current voltage electric shock key 7-1 is selected in the infrared electric shock touch display screen 7, and the electric shock main control module 9-1 of the electric shock control module 9 controls the direct-current module 9-2 to work after receiving a direct-current voltage experience instruction. After the direct-current voltage electric shock button 7-1 is turned on, two choices are provided, a manual mode is selected, first-level experience is selected, the electric shock main control module 9-1 adjusts the output voltage intensity of the induction power supply 8 to be first-level voltage, the output voltage of the induction power supply 8 is transmitted to the direct-current module 9-2 and then is converted into first-level direct current, and both hands are placed on the discharge ball 4 to experience first-level direct current electric shock; the secondary experience is selected, the electric shock main control module 9-1 adjusts the output voltage intensity of the induction power supply 8 to be secondary, the output voltage of the induction power supply 8 is transmitted to the direct current module 9-2 and then is converted into secondary direct current, and two hands are placed on the discharge ball 4 to experience secondary direct current electric shock; and the electric shock main control module 9-1 receives the three-level direct current voltage experience instruction to adjust the output voltage intensity of the inductive power supply 8 to be three-level current, the output voltage of the inductive power supply 8 is transmitted to the direct current module 9-2 and then is converted into three-level direct current, and two hands are placed on the discharge ball 4 to experience three-level direct current electric shock. The automatic mode is selected, the electric shock main control module 9-1 receives an automatic direct current voltage experience instruction and then controls the output voltage intensity of the induction power supply 8 to be automatically adjusted from weak to strong, the output voltage of the induction power supply 8 is transmitted to the direct current module 9-2 and then is converted into direct current which is automatically adjusted from weak to strong, hands are placed on the discharge ball 4, the direct current which is automatically updated can be experienced, and in the process, the voice prompt can broadcast the intensity level of the direct current voltage which is being experienced.

2. And (3) experiencing alternating voltage electric shock: according to the voice prompt content, an alternating voltage electric shock key 7-2 is selected in the infrared electric shock touch display screen 7, and after receiving an alternating voltage experience instruction, the electric shock main control module 9-1 of the electric shock control module 9 controls the alternating current module 9-3 to work, and two choices exist after the alternating voltage electric shock key 7-2 is opened. Firstly, selecting a manual mode, selecting first-level experience, wherein the electric shock main control module 9-1 adjusts the output voltage intensity of the induction power supply 8 to be first-level, the output voltage of the induction power supply 8 is transmitted to the alternating current module 9-3 and then is converted into first-level alternating current, and the first-level alternating current can be experienced by placing both hands on the discharge ball 5; the secondary experience is selected, the electric shock main control module 9-1 receives a secondary alternating voltage experience instruction and then adjusts the output voltage intensity of the induction power supply 8 to be secondary, the output voltage of the induction power supply 8 is transmitted to the alternating current module 9-3 and then is converted into secondary alternating current, and two hands are placed on the discharge ball 5 to experience secondary alternating current electric shock; and the electric shock main control module 9-1 receives the three-level alternating current voltage experience instruction, adjusts the output voltage intensity of the inductive power supply 8 to be three-level, transmits the output voltage of the inductive power supply 8 to the alternating current module 9-3, converts the output voltage into three-level alternating current, and places two hands on the discharge ball 5 to experience three-level alternating current electric shock. The automatic mode is selected, the electric shock main control module 9-1 receives an automatic alternating current voltage experience instruction and controls the intensity of the output voltage of the induction power supply 8 to be automatically adjusted from weak to strong, the output voltage of the induction power supply 8 is transmitted to the alternating current module 9-3 and then is converted into alternating current which is automatically adjusted from weak to strong, hands are placed on the discharge ball 5, the automatic-upgrading alternating current can be experienced, and in the process, the voice prompt can broadcast the intensity level of the alternating current voltage being experienced.

3. And (3) experiencing pulse voltage electric shock: according to the voice prompt content, a pulse voltage electric shock key 7-3 is selected in the infrared electric shock touch display screen 7, and after receiving a pulse voltage experience instruction, the electric shock main control module 9-1 of the electric shock control module 9 controls the pulse current module 9-3 to work, and two choices are available after the pulse voltage electric shock key 7-3 is opened. Firstly, selecting a manual mode, selecting first-level experience, wherein the electric shock main control module 9-1 adjusts the output voltage intensity of the induction power supply 8 to be first-level, the output voltage of the induction power supply 8 is transmitted to the pulse current module 9-4 and then is converted into first-level pulse current, and the first-level pulse voltage electric shock can be experienced by placing both hands on the discharge ball 5; the secondary experience is selected, the electric shock main control module 9-1 adjusts the output voltage intensity of the inductive power supply 8 to be secondary, the output voltage of the inductive power supply 8 is transmitted to the pulse current module 9-4 and then is converted into secondary pulse current, and two hands are placed on the discharge ball 5 to experience electric shock of the secondary pulse voltage; the three-level experience is selected, the electric shock main control module 9-1 adjusts the output voltage intensity of the inductive power supply 8 to be three-level, the output voltage of the inductive power supply 8 is transmitted to the pulse current module 9-4 and then is converted into three-level pulse current, and two hands are placed on the discharge ball 5 to experience three-level pulse voltage electric shock. The automatic mode is selected, the electric shock main control module 9-1 receives an automatic pulse voltage experience instruction and controls the output voltage intensity of the induction power supply 8 to be automatically adjusted from weak to strong, the output voltage of the induction power supply 8 is transmitted to the pulse current module 9-3 and then is converted into pulse current which is automatically adjusted from weak to strong, two hands are placed on the discharge ball 5, the pulse current which is automatically upgraded can be experienced, in the process, the voice prompt can broadcast the intensity level of the experienced pulse voltage, the pulse fundamental wave of the pulse voltage output by the induction power supply is square wave, the pulse width is 80 mu s, and the pulse frequency range is 20Hz-300Hz.

The experimenter clicks the video button 7-4, so that the video of the safe electricity utilization can be watched, the main content is common potential safety hazards of electricity utilization in the electricity utilization of the construction site, the specification corresponding to the electricity utilization of the construction site is popularized, and the experience of the simulated electric shock experience device is finished.

2. The experience process of the simulation construction electricity overload and leakage experience device is as follows:

in the experience process, the whole process is provided with voice prompts for simulating the operation of the overload and leakage experience of the construction electricity, a plurality of breakers are in an on state before the experience, and the luminous colors of the electric welding indicator lamp 23-1 and the illumination indicator lamp 24-1 are green, namely, are in a normal working state.

The experience process of the device is experienced in the overload electric leakage of simulation construction electricity utilization has the power-off protection of experiencing the overload of the secondary distribution electricity, the power-off protection of experiencing the overload of the tertiary illumination, the power-off protection of experiencing the electric leakage of tertiary illumination, the power-off protection of experiencing the overload of tertiary electric welding, the power-off protection of experiencing the electric leakage of tertiary electric welding, and is specifically as follows:

1. experience power-off protection of a secondary power distribution overload: the overload leakage main control module 26-1 of the overload leakage control module 26 receives the experience instruction of the secondary power distribution overload key 25-1, then controls the first transformer 26-2 to work and increases the current of the secondary analog overload resistor 20-4, at this time, the secondary overload voltage is displayed in the overload leakage touch display screen 25 to be gradually increased, and after the current passing through the secondary analog overload resistor 20-4 is increased to the maximum value, the switch gates of the secondary total breaker 20-1, the secondary overload breaker 20-2 and the secondary leakage breaker 20-3 fall to simulate that the secondary power distribution device is protected by the overload breaker to cut off when the secondary power distribution is overloaded, at this time, the electric welding indicator lamp 23-1 and the lighting indicator lamp 24-1 are closed, and the overload leakage main control module 26-1 controls the overload leakage touch display screen 25 to send an alarm sound to remind that the secondary power distribution is abnormal.

2. Experience three-level lighting overload power-off protection: after clicking a reset key 25-6 in the overload leakage touch display screen 25, an experimenter selects a three-level lighting overload key 25-2, an overload leakage main control module 26-1 receives an instruction of the three-level lighting overload key 25-2 to control a second transformer 26-3 to work and increase current of a three-level lighting simulation overload resistor 21-3, at this time, overload voltage of three-level lighting is gradually increased in the overload leakage touch display screen 25, after the current of the overload resistor 21-3 is increased to the maximum value through the three-level lighting simulation overload, a three-level lighting overload breaker 21-1 and a switch gate of the three-level lighting leakage breaker 21-2 are fallen to simulate protection power failure of the three-level power distribution device by the overload breaker when the three-level lighting power utilization is overloaded, at this time, the lighting indicator 24-1 is closed, and the overload leakage main control module 26-1 controls the overload leakage touch display screen 25 to send alarm sounds to remind of abnormal three-level lighting power distribution.

3. Experience tertiary illumination electric leakage power-off protection: after clicking a reset key 25-6 in the overload leakage touch display screen 25, an experimenter selects a three-level illumination leakage key 25-3, an overload leakage main control module 26-1 receives an instruction of the three-level illumination leakage key 25-3 to control a second transformer 26-2 to work and increase current of a three-level illumination simulation overload resistor 21-3, at this time, the leakage voltage of the three-level illumination displayed in the overload leakage touch display screen 25 is gradually increased, after the current of the overload resistor 21-3 is increased to the maximum value through the three-level illumination simulation overload, a switch gate of a three-level illumination overload breaker 21-1 and a switch gate of the three-level illumination leakage breaker 21-2 are fallen to simulate protection outage of the three-level illumination power distribution device by the leakage protector, at this time, the illumination indicator 24-1 is closed, and the overload leakage main control module 26-1 controls the overload leakage touch display screen 25 to send alarm sounds to remind of abnormal three-level illumination power distribution.

4. Experience three-level electric welding overload power-off protection: after the experimenter clicks a reset key 25-6 in the overload electric leakage touch display screen 25, a three-level electric welding overload key 25-4 is selected, an overload electric leakage main control module 26-1 receives an instruction of the three-level electric welding overload key 25-4 to control a third transformer 26-4 to work and increase current of a three-level electric welding simulation overload resistor 22-3, at the moment, overload voltage of the three-level electric welding displayed in the overload electric leakage touch display screen 25 is gradually increased, after the current of the three-level electric welding simulation overload resistor 22-3 is increased to the maximum value, switch gates of a three-level electric welding overload breaker 22-1 and a three-level electric welding electric leakage breaker 22-2 are all dropped to simulate protection outage of the three-level electric welding distribution device by the overload breaker, at the moment, an electric welding working lamp 23-1 is turned off, and the overload electric leakage main control module 26-1 controls the overload electric leakage touch display screen 25 to send out alarm sounds to prompt three-level electric welding distribution abnormality.

5. Experience tertiary electric welding electric leakage power-off protection: after clicking a reset key 25-6 in the overload leakage touch display screen 25, an experimenter selects a three-stage electric welding leakage key 25-5, an overload leakage main control module 26-1 receives an instruction of the three-stage electric welding leakage key 25-5 to control a third transformer 26-4 to work and increase current passing through a three-stage electric welding simulation overload resistor 22-3, at this moment, the electric welding leakage voltage of the three-stage electric welding displayed in the overload leakage touch display screen 25 is gradually increased, after the current passing through the three-stage electric welding simulation overload resistor 22-3 is increased to the maximum value, switch gates of a three-stage electric welding overload breaker 22-1 and a three-stage electric welding leakage breaker 22-2 are all dropped to simulate the protection outage of a three-stage electric welding distribution device under the protection of a leakage protector, at this moment, the electric welding working lamp 23-1 is closed, and the overload leakage main control module 26-1 controls the overload leakage touch display screen 25 to send an alarm sound to wake up, and the three-stage electric welding distribution is abnormal.

And the experience of the device for simulating the overload and leakage of the construction electricity is finished.

3. The experience process of the crash experience device of the simulation safety helmet is as follows:

the simulation safety helmet impact experience device can accommodate two people to experience simultaneously, two impact experience boxes are respectively an A experience box and a B experience box, the buttons on the remote controller 13 comprise an A release button capable of enabling the solid hemisphere 10 of the A experience box to fall down, an A lifting button capable of enabling the solid hemisphere 10 of the A experience box to rise up, a B release button capable of enabling the solid hemisphere 10 of the B experience box to fall down and a B lifting button capable of enabling the solid hemisphere 10 of the B experience box to rise up, the impact experience flows of the A experience box and the B experience box are the same, and the experience process of the A experience box is as follows.

As shown in fig. 9, the device is confirmed to be powered on and the indicator lamp 11 is on, the experimenter wears the safety helmet 14, walks under the impact a experience box 17, places the feet at the identification mark under the a experience box 17, holds the remote controller 13 by the manager, presses the button placed by a, and the impact control module 15 controls the electromagnetic clutch 17-2 to separate the guide wheel shaft 17-13 from the output shaft of the motor 17-3. At this time, the gravity of the solid hemisphere 10 pulls the guide wheel 17-1 to rotate, the solid hemisphere 10 makes free falling motion downwards, the solid hemisphere 10 impacts on the helmet 14, and the experimenter experiences the feeling of head impact. The manager presses a button for lifting A, which can enable the solid hemisphere 10 of the A experience box to be lifted, in the remote controller 13, the impact control module 15 controls the electromagnetic clutch 17-2 to combine the guide wheel shaft 17-13 with the output shaft of the motor 17-3, the impact control module 15 controls the motor 17-3 to start, the output shaft of the motor 17-3 rotates and drives the guide wheel 17-3 to rotate in the opposite direction, the rope 12 is wound on the guide wheel shaft 17-13, the length of the rope is gradually shortened, and the solid hemisphere 10 is lifted. When the specified position on the upper part is reached, the impact control module 15 controls the motor 17-3 to stop working (the motor 17-3 is a servo motor, and when the impact control module 15 controls the motor 17-3 to stop working, the output shaft of the motor 17-3 stops rotating), the output shaft of the motor 17-3 and the guide wheel shaft 17-13 stop rotating, the experienter at the end of impact experience leaves the marked position and returns to the safety helmet 14, and the simulated safety helmet impact experience device is ready to work and waits for the next experienter to carry out the safety helmet impact experience.

The foregoing description is only a preferred embodiment of the present invention, and is not intended to limit the present invention, and any simple modification, variation and equivalent structural transformation of the above embodiment according to the technical substance of the present invention still fall within the scope of the technical solution of the present invention.

Claims (6)

1. The utility model provides a house is experienced with crash of helmet to container formula simulation electric shock and power consumption safety, its characterized in that: the electric shock simulation device comprises a box body capable of being carried by mechanical equipment, wherein an electric shock simulation experience device (1) capable of being used for experiencing electric shock feeling by one person, an electric overload electricity consumption and leakage experience device (2) capable of being used for simulating construction of automatic tripping of a power distribution cabinet when electric equipment is in electric leakage and overload are arranged in the box body, and a safety helmet collision experience device (3) capable of being used for two human bodies to examine a head part are arranged in the box body, the box body comprises a right side plate (4-1), a bottom plate (4-6), a back plate (4-4), a left side plate (4-2) arranged opposite to the right side plate (4-1), a top plate (4-7) arranged opposite to the bottom plate (4-6) and a rolling door (4-5), the right side plate (4-1), the left side plate (4-2), the bottom plate (4-6), the top plate (4-7) and the rolling door jointly encircle a box body in a cuboid structure, the front side of the top plate (4-7) is fixedly connected with the rolling door (4-5), the front side of the top plate (4-7) is fixedly connected with the back plate (4-4) and the back plate (4-4) is arranged in parallel to the box body, the electric shock simulation device is characterized in that a distance is reserved between the partition board (4-3) and the back board (4-4), the electric shock simulation device (1) is fixed at the top of the left side of the bottom board (4-6), the electric overload and electric leakage simulation device (2) for simulation construction is nested on the right side of the partition board (4-3), and the electric shock simulation device (3) for simulation safety helmet impact is fixed on the inner wall of the right side board (4-1);

The electric shock simulation experience device (1) comprises an electric shock control module (9), an electric shock simulation experience device box (6), a touch sensing power supply (8), an electric shock touch display screen (7) and two discharge balls (5), wherein the electric shock touch display screen (7) is arranged on the upper portion of the front side of the electric shock simulation experience device box (6), a drawer (16) capable of being pulled is arranged in the middle of the front side of the electric shock simulation experience device box (6), the two discharge balls (5) are fixed in the drawer (16), a distance is reserved between the two discharge balls (5), and the electric shock control module (9) and the touch sensing power supply (8) are arranged in the electric shock simulation experience device box (6); the electric shock control module (9) comprises an electric shock main control module (9-1), a direct current module (9-2), an alternating current module (9-3) and a pulse current module (9-4), wherein the output end of the electric shock main control module (9-1) is connected with the input end of the direct current module (9-2), the input end of the alternating current module (9-3) and the input end of the pulse current module (9-4) respectively to control the direct current module (9-2), the alternating current module (9-3) and the pulse current module (9-4) to work, the touch keys of the electric shock touch display screen (7) comprise a direct current voltage electric shock key (7-1), an alternating current voltage electric shock key (7-2), a pulse voltage electric shock key (7-3), a video key (7-4) and a voice key (7-5), the electric shock main control module (9-1) is connected with the electric shock touch display screen (7) in a bidirectional manner and can receive experience instructions, voice instructions and video instructions sent by the electric shock touch display screen (7) and send the video information to the electric shock display screen to play, the output end of the electric shock main control module (9-1) is also connected with the induction power supply (8) and adjusts the voltage intensity of the induction power supply (8) according to the instruction received by the electric shock main control module (9-1), the induction power supply (8) is also connected with the input end of the direct current module (9-2), the input end of the alternating current module (9-3) and the input end of the pulse current module (9-4) and respectively transmits the regulated voltage intensity to the direct current module (9-2), the alternating current module (9-3) and the pulse current module (9-4), the output end of the direct current module (9-2) is connected with the two discharge balls (5) and respectively transmits the input current of the induction power supply (8) to the two discharge balls (5) after the input end of the alternating current module (9-3) is connected with the two discharge balls (5) and respectively transmits the input current of the input induction power supply (8) to the two discharge balls (5) after the voltage intensity is adjusted by the electric shock main control module (9-1);

The crash helmet crash experience device (3) comprises a crash control module (15), two crash experience boxes, a remote controller (13) capable of remotely controlling the crash experience boxes to work and two crash helmets (14) used for protecting heads during crash experience, the two crash experience boxes are identical in structure, the crash experience boxes comprise a crash experience box body (17), a solid hemisphere (10), an indicator lamp (11), a rope (12), an electromagnetic clutch (17-2), a motor (17-3) and a guide wheel (17-1), the motor (17-3), the electromagnetic clutch (17-2) and the guide wheel (17-1) are all arranged in the crash experience box body (17), the motor (17-3) is fixedly connected with the inner wall of the crash experience box body (17), the input end of the electromagnetic clutch (17-2) is connected with the output shaft of the motor (17-3), the guide wheel (17-1) comprises a first guide wheel (17-11), a second guide wheel (17-12) and a guide wheel shaft (17-13), the first guide wheel (17-12) and the second guide wheel (17-13) are respectively arranged at two ends of the first guide wheel (17-13), the output end of the electromagnetic clutch (17-2) is connected with one end of a guide wheel shaft (17-13) close to the electromagnetic clutch (17-2), the guide wheel shaft (17-13) is connected with one end of a rope (12), the other end of the rope (12) vertically penetrates through the lower part of the impact experience box body (17) and then is connected with the center of the round surface of the solid hemisphere (10), and the indicator lamp (11) is arranged on the outer side of the impact experience box body (17) and is turned on after a working power supply is turned on; the remote controller (13) is in wireless connection with the impact control module (15) and transmits a remote control instruction to the impact control module (15), the output end of the impact control module (15) is connected with the electromagnetic clutch (17-2) and controls the electromagnetic clutch (17-2) to combine or separate the guide wheel shaft (17-13) and the output end of the motor (17-3) according to the remote control instruction, and the output end of the impact control module (15) is also connected with the motor (17-3) and controls the motor (17-3) to start or stop according to the remote control instruction;

The electric overload leakage experience device (2) for the simulation construction comprises an overload leakage touch display screen (25), an overload leakage control module (26), a plurality of breakers, three simulation overload resistors, an electric welding indicator lamp (23-1) for simulating an electric welding working state and an illumination indicator lamp (24-1) for simulating an illumination lamp working state, wherein the overload leakage control module (26) comprises an overload leakage main control module (26-1), a first transformer (26-2), a second transformer (26-3) and a third transformer (26-4), the output end of the overload leakage main control module (26-1) is connected with the first transformer (26-2), the second transformer (26-3) and the third transformer (26-4) and respectively controls the first transformer (26-2), the second transformer (26-3) and the third transformer (26-4) to work, a second power distribution button (25-1), a third-level illumination button (25-2), a third-level illumination button (25-3), an overload leakage button (25-5-to reset button (25-6-to reset the overload leakage touch display screen (25), the overload leakage main control module (26-1) is connected with the overload leakage touch display screen (25) in a two-way manner, can receive experience instructions and reset instructions sent by the overload leakage touch display screen (25) and send data information of corresponding instructions to the overload leakage touch display screen (25) to be displayed by the overload leakage touch display screen (25), and the electric welding indicator lamp (23-1) and the illumination indicator lamp (24-1) are connected with the output end of the overload leakage main control module (26-1) and are controlled to work by the overload leakage main control module (26-1); the three analog overload resistors comprise a second-stage analog overload resistor (20-4), a third-stage illumination analog overload resistor (21-3) and a third-stage electric welding analog overload resistor (22-3), the plurality of circuit breakers comprise a second-stage total circuit breaker (20-1), a second-stage overload circuit breaker (20-2), a second-stage electric leakage circuit breaker (20-3), the third-stage illumination overload circuit breaker (21-1), the third-stage illumination electric leakage circuit breaker (21-2), the third-stage electric welding overload circuit breaker (22-1) and the third-stage electric welding electric leakage circuit breaker (22-2), one end of the second-stage analog overload resistor (20-4) is connected with the positive electrode of the second-stage total circuit breaker (20-1), so that the negative electrode of the second-stage overload circuit breaker (20-2) is connected with the positive electrode of the second-stage overload circuit breaker (20-3), the negative electrode of the second-stage electric leakage circuit breaker (20-3) and the other end of the second-stage analog resistor (20-4) are connected with the positive electrode of the second-stage overload circuit breaker (20-2) through a first-26-2 and a second-26-2 mutual inductance current transformer to enable the second-stage overload circuit breaker to be connected with the first-2 and the second-stage overload circuit breaker (20-2) through a mutual inductance module to be controlled to work by the second-stage overload circuit breaker (26-1) The secondary overload breaker (20-2) and the secondary leakage breaker (20-3) are subjected to power-off protection; one end of the three-level lighting simulation overload resistor (21-3) is connected with the positive electrode of the three-level lighting overload breaker (21-1), the negative electrode of the three-level lighting overload breaker (21-1) is connected with the positive electrode of the three-level lighting leakage breaker (21-2), the other end of the three-level lighting simulation overload resistor (21-3) and the negative electrode of the three-level lighting leakage breaker (21-2) are connected with the second transformer (26-3), the overload leakage main control module (26-1) controls the second transformer (26-3) to work, and the input current of the three-level lighting simulation overload resistor (21-3) is increased to enable the three-level lighting overload breaker (21-1) and the three-level lighting leakage breaker (21-2) to perform power-off protection; one end of the three-stage electric welding simulation overload resistor (22-3) is connected with the positive electrode of the three-stage electric welding overload breaker (22-1), the negative electrode of the three-stage electric welding overload breaker (22-1) is connected with the positive electrode of the three-stage electric welding leakage breaker (22-2), the other end of the three-stage electric welding simulation overload resistor (22-3) and the negative electrode of the three-stage electric welding leakage breaker (22-2) are connected with the third transformer (26-4) and the third transformer (26-4) is controlled by the overload leakage main control module (26-1) to work, and the three-stage electric welding overload breaker (22-1) and the three-stage electric welding leakage breaker (22-2) are subjected to power-off protection by increasing the input current of the three-stage electric welding simulation overload resistor (22-3).

2. The container-type simulated electric shock and electricity safety and helmet crash experience library according to claim 1, wherein: the pulse current module (9-4) is a MOS tube module, the discharge ball (5) is a stainless steel ball, the diameter of the discharge ball (5) is smaller than 80mm, and the sensing power supply (8) is a 6V battery power supply.

3. The container-type simulated electric shock and electricity safety and helmet crash experience library according to claim 1, wherein: the impact control module (15) is a two-way single-way control switch.

4. The container-type simulated electric shock and electricity safety and helmet crash experience library according to claim 1, wherein: the power distribution picture is adhered to the outer side of the partition board (4-3), and comprises a transformer picture (18), a first-stage power distribution box picture (19), a second-stage power distribution box picture (20), a third-stage illumination power distribution box picture (21), a third-stage electric welding power distribution box picture (22), an electric welding tool picture (23) and an illumination lamp picture (24), wherein the second-stage simulated overload resistor (20-4), the second-stage total breaker (20-1), the second-stage overload breaker (20-2) and the second-stage leakage breaker (20-3) are all nested on the partition board (4-3) at the position of the second-stage power distribution box picture (20); the three-level lighting simulation overload resistor (21-3), the three-level lighting overload breaker (21-1) and the three-level lighting leakage breaker (21-2) are all nested on a partition board (4-3) at the position of the three-level lighting distribution box picture (21); the electric welding device is characterized in that the three-level electric welding simulation overload resistor (22-3), the three-level electric welding overload breaker (22-1) and the three-level electric welding leakage breaker (22-2) are nested on the partition board (4-3) at the position of the three-level electric welding distribution box picture (22), the illumination indicator lamp (24-1) is nested on the partition board (4-3) at the position above the illumination lamp picture (24), the electric welding indicator lamp (23-1) is nested on the partition board (4-3) at the position above the electric welding tool picture (23), and the overload electric leakage touch display screen (25) is nested on the partition board (4-3) and is surrounded by the transformer picture (18), the first-level distribution box picture (19), the second-level distribution box picture (20), the three-level illumination distribution box picture (21), the three-level electric welding distribution box picture (22), the electric welding tool picture (23) and the illumination lamp (24), and the overload electric leakage control module (26) is arranged behind the partition board (4-3).

5. The container-type simulated electric shock and electricity safety and helmet crash experience library according to claim 1, wherein: the container is characterized in that the container body is a container, the length of the container body is 4.5m, the width of the container body is 2.4m, the height of the container body is 2.5m, and the vertical distance L between the partition plate (4-3) and the back plate (4-4) is 0.5m.

6. The container-type simulated electric shock and electricity safety and helmet crash experience library according to claim 1, wherein: the plurality of breakers are plastic shell breakers with working current ranges of 10A-1050A.