CN115036727B - Electric shock protection separation structure for electric shock safety whole sensing equipment - Google Patents

Abstract

The invention discloses an electric shock protection separation structure for electric shock safety whole sensing equipment, which relates to the technical field of electric shock protection separation and comprises a base, wherein a plurality of rows of first storage grooves and a plurality of rows of second storage grooves are formed in the upper end of the base, cavities which are communicated with the interiors of the first storage grooves and the second storage grooves and are used for circuit distribution are formed in the base, supporting plates are fixedly arranged on side walls of the side, away from each other, of each first storage groove and each second storage groove, each supporting plate is fixedly inserted with a second conductive column, each second conductive column is connected with a connecting port of a control module through a wire, the voltage connected with each second conductive column in the same row is increased in proportion, and the voltage connected with each second conductive column in the same row is increased in proportion. The invention is convenient for an experienter to simulate the step voltage value, and the circuit is immediately disconnected as long as one of the two feet leaves the second conductive column, so that the self-rescue process can be truly simulated through the disconnection of the circuit when a person actually gets an electric shock, and the potential safety hazard is reduced.

Description

Electric shock protection separation structure for electric shock safety whole sensing equipment

Technical Field

The invention relates to the technical field of electric shock protection separation, in particular to an electric shock protection separation structure for electric shock safety whole sensing equipment.

Background

The electric shock safety whole sensing device is characterized in that an electric shock feeling is experienced by students through an in-person electric shock experiencing mode, the electric shock degree of the human body under different wet conditions is compared, the students understand that the human body is more easily subjected to electric shock under the wet conditions, the correct method for separating from a power supply is mastered, the importance of wearing personal safety protection tools during electric operation is improved, electric shock accidents are prevented, the existing electric shock whole sensing device can meet the electric shock whole sensing requirements of different high and low voltages, but the electric shock safety whole sensing device does not always have an electric shock separation structure, so that the self-rescue process can not be really simulated through a circuit breaking process when the personnel actually get electric shock, the phenomena of electric injury or electric death still exist in the actual electric shock accidents, and the potential safety hazards of a power grid and trained personnel are large, so that the electric shock safety protection separation structure for the electric shock safety whole sensing device is designed.

Disclosure of Invention

The invention aims to provide an electric shock protection separation structure for electric shock safety whole sensing equipment, which aims to solve the problems in the background technology.

In order to achieve the above purpose, the present invention provides the following technical solutions: an electric shock protection separation structure for an electric shock safety somatosensory device comprises a base, wherein the base is used as a body of the somatosensory device and is used as an electric shock somatosensory place.

The upper end of the base is provided with a plurality of rows of first storage grooves and a plurality of rows of second storage grooves, the single row of first storage grooves and the single row of second storage grooves are positioned in the same vertical plane, and the single row of first storage grooves and the single row of second storage grooves are provided with a plurality of grooves and are uniformly distributed at intervals in a straight-line structure;

the inside of base has been seted up and has been accomodate groove and second and accomodate the inside intercommunication each other of groove, and is used for the cavity of circuit distribution, and all circuits of whole somatosensory equipment are embedded in the cavity to adopt the solid line fastener to take turns to the cable and fix the distribution in order in the cavity inside, both satisfied circuit signal's transmission demand, avoided appearing the cable again and distribute the complicated phenomenon of being inconvenient for later stage overhauls.

The side wall of one side that every first storage tank and every second storage tank inside kept away from each other is fixed and is equipped with the layer board, fixed grafting has the second conductive column on every layer board, every second conductive column all is connected with control module's connection port through the wire, the inside control module that is used for whole circuit control that is embedded of base, control module's signal output port is connected with voltage calculation module through the wire, voltage calculation module's signal output port is connected with liquid crystal display through the wire, the human body is as the conductor, can communicate the circuit of two second conductive columns that the both feet trampled, and the voltage calculation module that control module connects can calculate the high-voltage step voltage value etc. proportion that triggers fast, reduce to below the safe voltage, avoid triggering the high pressure in position and bring the injury for the experimenter, both ensure experimenter's experience security, can guarantee that the experimenter can simulate the experience in the actual electric shock accident again, improve experimenter's safety consciousness in the daily work, wear personal safety appliance's importance when making the experimenter electric operation, the emergence of preventing electric shock.

As long as the experimenter has one foot to leave the second conductive columns, the control module controlled by the whole circuit can not receive the circuit signals of the two second conductive columns stepped on by the two feet at the same time, the circuit is immediately disconnected, the experimenter at the moment is ensured to be a non-contact circuit, the self-rescue process can be truly simulated through the disconnected circuit when the person actually gets an electric shock, the probability of being electrically injured or electrocuted can be reduced in the actual electric shock accident, and the safety operation of the power grid and the personal safety hidden trouble of the trainee are reduced.

The voltage that every second conductive post of same row is connected is proportional to increase gradually, and experimenter's a foot is stepped on the second conductive post in a first storage tank on same row different positions, and another foot is stepped on the second conductive post in a second storage tank on same row different positions, and voltage calculation module calculates that the high-voltage step voltage value that triggers is different, and the experimenter of being convenient for feels the voltage signal value with electric shock leakage electrical equipment under the same distance in different positions.

The voltage that every second conductive post of same row is connected is scale-up, and experimenter's a foot is stepped on the second conductive post in a first storage tank on one of them row different positions, and another foot is stepped on the second conductive post in a second storage tank on another row different positions, and voltage calculation module calculates that the high-voltage step voltage value that triggers is different, and the experimenter of being convenient for feels the voltage signal value with electric shock leakage electrical equipment different distances down in different positions.

In further embodiments, the fixed embedded insulating ground pad that has that is located between a row of first storage tank and the second storage tank that are close to each other in base upper end, insulating ground pad is as insulating medium, and the person of being convenient for is walked along insulating ground pad's distribution position, is convenient for change the position between the first storage tank and the second storage tank of different ranks, avoids the person of being experienced to step on by mistake in arbitrary first storage tank and second storage tank, improves experience factor of safety.

In a further embodiment, each first storage groove and each second storage groove are provided with a treading mechanism, the treading mechanism of each first storage groove and the treading mechanism of each second storage groove form a group of treading mechanisms for bearing the two feet of the experimenter, that is to say, the treading mechanism of any first storage groove and the treading mechanism of any second storage groove can form a group of treading mechanisms for bearing the two feet of the experimenter, so that the electric shock body feeling requirements brought by different positions of the experimenter are met.

In further embodiments, the pedal mechanism includes the footboard that can match experimenter's sole, and the bottom mounting of footboard is equipped with the bracing piece that distributes around two, and every first storage tank and every second storage tank's inside both sides lateral wall all rotate be equipped with the round pin axle of corresponding bracing piece lateral wall bottom rotation grafting, and rotation department is equipped with the torsional spring, utilizes the torsion potential energy of torsional spring, under natural state for rotate the footboard of installing in first storage tank and to be close to the central point put one side below slope distribution of base, rotate the footboard of installing in second storage tank to be close to the central point put one side below slope distribution of base.

The bottom of two bracing pieces is fixed and is equipped with the crossbeam between, and the fixed extension piece that is equipped with of lateral wall of crossbeam, and the bottom mounting of extension piece be equipped with can with the first conductive post of the butt joint of the second conductive post top that corresponds, experience person's both feet stand behind the footboard in arbitrary one first storage tank and the footboard in arbitrary one second storage tank, can overturn the bracing piece of two footboard bottoms around round pin axle department by oneself hard, can drive the extension piece synchronous upset of crossbeam lateral wall, be convenient for dock the top at the conductive post of second with first conductive post.

In a further embodiment, the first conductive column, the second conductive column, the pedal, the support rod, the cross beam and the extension block are made of copper, and the first conductive column, the second conductive column, the pedal, the support rod, the cross beam and the extension block which are made of copper can be communicated with the circuits of the two second conductive columns which are stepped on, and the voltage calculation module connected with the control module can quickly calculate the triggered high-voltage step voltage value and display the triggered high-voltage step voltage value on the liquid crystal display screen.

In a further embodiment, the upper end of the base is provided with a hand mechanism which is helpful for an experimenter to stand stably, and the hand mechanism is utilized to facilitate the experimenter to hold in the electric shock body feeling process, so that the standing stability is enhanced.

In a further embodiment, the hand mechanism comprises four L-shaped supporting frames, the four L-shaped supporting frames are respectively fixedly arranged at the front side and the rear side of the side walls of the two sides of the base, a hand rod is fixedly arranged between the top ends of the two L-shaped supporting frames which are opposite front and rear, the four L-shaped supporting frames are utilized to form the supporting frames, the hand rod is emptied and is arranged above the two sides of the base, the experimenter can conveniently walk in the electric shock body feeling process, and the standing stability in the body feeling process is enhanced.

In a further embodiment, the hand mechanism includes two door type framves, two door type framves are fixed respectively in the front and back both sides of base, the fixed hanging beam that is equipped with of relative lateral wall of two door type framves, T type guide notch has been seted up to the bottom of hanging beam, the inside slip of T type guide notch is equipped with the I-roller, the I-roller rotates and cup joints the jib that extends to T type guide notch below, the outer wall bottom symmetry fixed of jib is equipped with two handles, according to the somatosensory demand in different positions, can freely roll the I-roller along the T type guide notch level of hanging beam through the jib, can adjust the hand position of handle, be convenient for according to the somatosensory demand in different positions of experimenter, freely adjust the handle position, be convenient for the experimenter in real time to reinforcing somatosensory in-process experimenter stability of standing.

Preferably, the separation method based on the electric shock protection separation structure for the electric shock safety somatosensory equipment comprises the following steps:

a1, the two feet of the experimenter can pedal on the second conductive columns in any one of the first storage groove and any one of the second storage groove by themselves, and the voltage calculation module can calculate the triggered high-voltage step voltage value so as to meet the somatosensory requirements of the experimenter;

a2, as long as the two feet of the experimenter leave the second conductive columns, the control module controlled by the whole circuit can not receive the circuit signals of the two second conductive columns stepped on by the two feet at the same time, the circuit is immediately disconnected, the experimenter at the moment is ensured to be a non-contact circuit, the self-rescue process can be truly simulated through the disconnected circuit when the person actually gets an electric shock, the probability of being electrically injured or electrocuted can be reduced in the actual electric shock accident, and the safety operation of a power grid and the personal safety hidden trouble of a trained person are reduced.

Compared with the prior art, the invention has the beneficial effects that:

the invention relates to an electric shock protection separation structure for electric shock safety whole sensing equipment, wherein two feet of an experimenter are respectively inserted into a first storage groove and a second storage groove which are arranged at different positions in the same row, and the voltage of the connection of each second conductive column in the same row is increased proportionally, so that after the two feet of the experimenter respectively step into the first storage groove at different positions and the second storage groove at different positions, the experimenter can respectively tread on the corresponding second conductive columns, a person serves as a conductor, the circuits of the two second conductive columns stepped by the two feet can be communicated, a voltage calculation module connected with a control module can rapidly calculate the ratio of the triggered high-voltage step voltage value and the like, the ratio is reduced to be lower than the safety voltage, the simulated step voltage value is obtained, and the voltage value is displayed on a liquid crystal display screen, so that the experimenter learns the voltage value of the position, as long as one foot leaves the second conductive column, the circuit is immediately disconnected, the experimenter is ensured not to be in contact with the circuit, the electric shock accident implementation process can be truly simulated when the person actually steps out, the electric shock accident is actually performed, and the potential safety hazard of the experimenter can be reduced in the practical electric shock safety accident or the electric shock accident and the electric power has potential failure probability.

Drawings

FIG. 1 is a schematic diagram of the main structure of the present invention;

FIG. 2 is a schematic view of a partial structure of the present invention;

FIG. 3 is an enlarged view of the structure of FIG. 1A according to the present invention;

FIG. 4 is an enlarged view of the structure of FIG. 2B in accordance with the present invention;

FIG. 5 is a cross-sectional view of a base structure of the present invention;

FIG. 6 is a schematic view of a part of the pedal mechanism according to the present invention;

FIG. 7 is a partial cross-sectional view of the tread mechanism of the present invention;

FIG. 8 is a block diagram of the functional principle of the present invention;

FIG. 9 is a schematic diagram of a third embodiment of the present invention;

FIG. 10 is a schematic diagram of a fourth embodiment of the present invention;

fig. 11 is a schematic diagram of a fourth partial structure of an embodiment of the present invention.

In the figure: 1. a base; 11. a first storage groove; 12. a second storage groove; 13. a supporting plate; 14. a second conductive post; 15. a cavity; 2. an insulating floor mat; 3. a pedal mechanism; 31. a pedal; 32. a support rod; 33. a cross beam; 34. an extension block; 35. a first conductive pillar; 4. a control module; 5. a voltage calculation module; 6. a liquid crystal display; 7. a hand-held mechanism; 71. an L-shaped supporting frame; 72. a walking bar; 73. a door-shaped frame; 74. a hanging beam; 75. a boom; 76. a handle; 77. a T-shaped guide notch; 78. i-shaped roller.

Detailed Description

The following description will clearly and fully describe the technical solutions of the embodiments of the present invention, and it is apparent that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Example 1

Referring to fig. 1, 2, 4 and 8, the present embodiment provides an electric shock protection separation structure for an electric shock safety somatosensory device, which comprises a base 1, wherein the base 1 is used as a body of the somatosensory device and is used as an electric shock somatosensory place.

The base 1 is made of insulating materials, so that the phenomenon of short circuit caused by parallel wires among various circuits is avoided, and the normal use of equipment is influenced.

The upper end of the base 1 is provided with a plurality of rows of first storage grooves 11 and a plurality of rows of second storage grooves 12, and the first storage grooves 11 and the second storage grooves 12 serve as places for experienters to experience different voltage values.

The first groove 11 of accomodating of single row and the second groove 12 of accomodating of single row are located same vertical plane, and the first groove 11 of accomodating of single row and the second groove 12 of accomodating of single row all are equipped with a plurality of and are a word type structure even interval distribution, and the experimenter can be according to the demand is felt to the body, and the first groove 11 of accomodating and the second groove 12 of accomodating of same row different positions are stepped on respectively to both feet, and the voltage signal numerical value that finally triggers is different, satisfies experimenter's electric shock body and feels the demand.

The inside of base 1 is offered and is accomodate groove 11 and second and accomodate the inside intercommunication of groove 12 each other, and is used for the cavity 15 of circuit distribution, and all circuits of whole somatosensory equipment are embedded in cavity 15 to adopt the solid line fastener to be fixed distribution in order with the cable inside cavity 15, both satisfied circuit signal's transmission demand, avoid appearing the cable again and distribute complicated and be inconvenient for the phenomenon of later stage maintenance.

The side wall of one side of each first storage groove 11 and one side of each second storage groove 12, which are mutually far away, is fixedly provided with a supporting plate 13, each supporting plate 13 is fixedly inserted with a second conductive column 14, and the experimenters respectively tread on the second conductive columns 14 in the first storage grooves 11 and the second storage grooves 12 in the same row and at different positions.

The control module 4 for whole circuit control is embedded in the base 1, the signal output port of the control module 4 is connected with the voltage calculation module 5 through a wire, the signal output port of the voltage calculation module 5 is connected with the liquid crystal display 6 through a wire, each second conductive column 14 is connected with the connection port of the control module 4 through a wire, a human body serves as a conductor, the circuits of the two second conductive columns 14 trampled by two feet can be communicated, the voltage calculation module 5 connected with the control module 4 can rapidly calculate the ratio of the triggered high-voltage step voltage value and the like, the ratio is reduced to be lower than the safe voltage, the damage to an experimenter caused by the high voltage at the position where the trigger is located is avoided, the experience safety of the experimenter is ensured, the experimenter can be ensured to simulate the experience in the actual electric shock accident, the safety awareness of the experimenter in the daily work is improved, the experimenter is enabled to realize the importance of wearing personal safety protection tools during the electric operation, and the occurrence of the electric shock accident is prevented.

The analog step voltage value is obtained and displayed on the liquid crystal display 6 so that the experienter can learn the voltage value of the position.

The existing electric shock body sensing equipment can meet the electric shock body sensing requirements of different high and low voltages, but often does not have an electric shock separation structure, so that the self-rescue process of a person in real electric shock can not be truly simulated through a circuit breaking process, in an actual electric shock accident, the phenomenon that the person is electrically injured or killed still exists, the power grid is safe to operate and the personal safety hidden danger of a trained person is large, so that in order to enable an experimenter to quickly break away from an electric shock scene when electric shock occurs, as long as the experimenter has one foot to leave the second conductive column 14, the control module 4 controlled by the whole circuit can not receive circuit signals of the two second conductive columns 14 while trampling on the two feet, the circuit is instantly broken, the experimenter at the moment is ensured to be not in contact with the circuit, the self-rescue process of the person in real electric shock can be truly simulated through the circuit breaking process, the probability of being electrically injured or killed can be helped in the actual electric shock accident, and the power grid safe operation and the personal safety hidden danger of the trained person are reduced.

The voltage of each second conductive column 14 in the same row is increased proportionally, one foot of an experimenter is stepped on the second conductive column 14 in one first storage groove 11 in the same row at different positions, the other foot is stepped on the second conductive column 14 in one second storage groove 12 in the same row at different positions, and the voltage calculation module 5 calculates the triggered high-voltage step voltage values to be different, so that the experimenter can feel voltage signal values at different positions at the same distance from electric shock leakage electrical equipment.

The voltage of each second conductive column 14 in the same row is increased proportionally, an experimenter treads on the second conductive column 14 in one first storage groove 11 in one row at different positions, the other foot treads on the second conductive column 14 in one second storage groove 12 in the other row at different positions, and the voltage calculation module 5 calculates different triggered high-voltage step voltage values, so that the experimenter can feel voltage signal values at different positions at different distances from electric shock and leakage electrical equipment.

The experimenter can tread one foot on the second conductive column 14 in one second storage groove 12 in one row of different positions, and tread the other foot on the second conductive column 14 in one first storage groove 11 in the other row of different positions, and the voltage calculation module 5 calculates that the triggered high-voltage step voltage values are different, so that the experimenter can feel the voltage signal values in different positions under different distances with the electric shock and leakage electrical equipment.

The experienter can pedal by oneself on the second conductive column 14 in arbitrary first storage tank 11 and arbitrary second storage tank 12, and voltage calculation module 5 can both calculate the high-voltage step voltage value that triggers, satisfies experienter's somatosensory demand.

The experimenter can not tread the second conductive posts 14 in any two of the first accommodating grooves 11 or in any two of the second accommodating grooves 12 at the same time, otherwise, the control module 4 breaks the whole circuit, and the experimenter can not experience the simulated electric shock feeling.

Through fixedly embedded insulating ground mat 2 that is located between a row of first storage tank 11 and the second storage tank 12 that are close to each other in base 1 upper end, insulating ground mat 2 is as insulating medium, and the person of being convenient for walks along insulating ground mat 2's distributing position, is convenient for change the position between the first storage tank 11 and the second storage tank 12 of different ranks, avoids the person of being experienced to step on by mistake in arbitrary first storage tank 11 and second storage tank 12, improves experience factor of safety.

The experimenter steps on the second conductive column 14 that corresponds, self is used for the electric current to flow as the conductor, thereby produce the inductance that touches, above-mentioned process is on safe basis, simulate the actual production in electric shock situation, because the inductance that touches of different positions is different, bring various different tactiless for the experimenter, consequently the initial experience of easy appearance experimenter leads to the shake of limbs and emptys, in order to improve the stability that experimenter body feel in-process stood, be equipped with the hand mechanism 7 that helps experimenter to stably stand in the upper end of base 1, utilize hand mechanism 7, the experimenter of being convenient for is in electric shock body feel in-process hand, the stability of reinforcing stood.

In addition, the experimenter holds the hand mechanism 7 with both hands, is convenient for lift both feet simultaneously, breaks away from the second conductive column 14 to be convenient for implementing self rescue when the circuit needs to be disconnected.

Example two

Referring to fig. 1-7, further modifications were made based on example 1:

through all being equipped with one at every first groove 11 of accomodating and every second groove 12 notch position of accomodating and trample mechanism 3, trample mechanism 3 is used for supporting experimenter's both feet, avoids the foot directly to trample and is produced uncomfortable to feel by the jack-up of second conductive column 14 on second conductive column 14.

The trample mechanism 3 of every first groove 11 notch position of accomodating and the trample mechanism 3 of every second groove 12 notch position of accomodating form a set of trample mechanism 3 that is used for bearing experimenter both feet, that is to say that trample mechanism 3 of groove 11 notch position is accomodate to arbitrary first and trample mechanism 3 of groove 12 notch position all can form a set of trample mechanism 3 that is used for bearing experimenter both feet with arbitrary second, satisfies the electric shock body feel demand that brings on experimenter different positions.

The pedal mechanism 3 comprises a pedal 31 which can be matched with the soles of experimenters, support rods 32 which are distributed around are fixed at the bottom end of the pedal 31, pin shafts which are inserted with the corresponding bottom ends of the side walls of the support rods 32 are rotationally arranged on the front side and the rear side of the inside of each first storage groove 11 and each second storage groove 12, torsion springs are arranged at the rotation positions, and the torsion potential energy of the torsion springs is utilized, so that the pedal 31 which is rotationally arranged in the first storage groove 11 is obliquely distributed below one side of the central position close to the base 1 in a natural state, and the pedal 31 which is rotationally arranged in the second storage groove 12 is obliquely distributed below one side of the central position close to the base 1.

The crossbeam 33 is fixedly arranged between the bottom ends of the two support rods 32, the extension block 34 is fixedly arranged on the side wall of the crossbeam 33, the first conductive column 35 which can be in butt joint with the top end of the corresponding second conductive column 14 is fixedly arranged at the bottom end of the extension block 34, after the experimenter stands on the pedal 31 in any one of the first storage grooves 11 and the pedal 31 in any one of the second storage grooves 12, the support rods 32 at the bottom ends of the two pedals 31 can be overturned around the pin shaft by self-force, the extension block 34 on the side wall of the crossbeam 33 can be driven to synchronously overturned, and the first conductive column 35 can be conveniently in butt joint with the top end of the second conductive column 14.

Through adopting the copper material with first conductive post 35, second conductive post 14, footboard 31, bracing piece 32, crossbeam 33 and extension piece 34, after first conductive post 35 dock at the top of second conductive post 14, can communicate the circuit of two second conductive posts 14 of being stepped on through the first conductive post 35 of copper material, second conductive post 14, footboard 31, bracing piece 32, crossbeam 33 and extension piece 34 equally, the voltage calculation module 5 that control module 4 connects can calculate the high-voltage step voltage value that triggers fast to show on liquid crystal display 6.

Example III

Please refer to fig. 1 and 9, which are further modified from embodiment 1:

the hand mechanism 7 comprises four L-shaped supporting frames 71, the four L-shaped supporting frames 71 are respectively fixedly arranged at the front side and the rear side of the side walls of the base 1, a hand rod 72 is fixedly arranged between the top ends of the two L-shaped supporting frames 71 which are opposite front and rear, the four L-shaped supporting frames 71 are utilized to form a supporting frame, the hand rod 72 is emptied and is arranged above the two sides of the base 1, an experimenter is convenient to hold in the electric shock body feeling process, and the standing stability in the body feeling process is enhanced.

Example IV

Referring to fig. 1, 10 and 11, the difference from embodiment 3 is that:

the hand mechanism 7 comprises two door-shaped frames 73, the two door-shaped frames 73 are respectively fixed on the front side and the rear side of the base 1, hanging beams 74 are fixedly arranged on opposite side walls of the two door-shaped frames 73, the hanging beams 74 are emptied and erected by the two door-shaped frames 73, T-shaped guide notches 77 are formed in the bottom ends of the hanging beams 74, I-shaped rollers 78 are slidably arranged in the T-shaped guide notches 77, hanging rods 75 extending to the lower portions of the T-shaped guide notches 77 are rotatably sleeved on the I-shaped rollers 78, two handles 76 are symmetrically and fixedly arranged at the bottom ends of the outer walls of the hanging rods 75, the two handles 76 are grasped by hands, the I-shaped rollers 78 can freely roll horizontally along the T-shaped guide notches 77 of the hanging beams 74 according to body feeling requirements of different positions, the hand positions of the handles 76 can be adjusted, the positions of the experimenters can be freely adjusted, the experimenters can conveniently hold the handles 76 in real time, and accordingly, the standing stability of the experimenters in the body feeling process is enhanced.

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

Claims (9)

1. The utility model provides an electric shock protection separation structure for electric shock safety somatosensory equipment, includes base (1), the inside control module (4) that are used for whole circuit control that is embedded of base (1), the signal output port of control module (4) is connected with voltage calculation module (5) through the wire, the signal output port of voltage calculation module (5) is connected with liquid crystal display (6) through the wire, its characterized in that: the upper end of the base (1) is provided with a plurality of rows of first storage grooves (11) and a plurality of rows of second storage grooves (12), the single row of first storage grooves (11) and the single row of second storage grooves (12) are positioned in the same vertical plane, and the single row of first storage grooves (11) and the single row of second storage grooves (12) are provided with a plurality of and uniformly distributed at intervals in a straight structure;

the inside of the base (1) is provided with a cavity (15) which is communicated with the inside of the first containing groove (11) and the inside of the second containing groove (12) and is used for distributing circuits,

a supporting plate (13) is fixedly arranged on the side wall of one side, which is far away from each other, inside each first storage groove (11) and each second storage groove (12), a second conductive column (14) is fixedly inserted on each supporting plate (13), and each second conductive column (14) is connected with a connecting port of the control module (4) through a wire;

the voltage of each second conductive column (14) in the same row is increased proportionally;

the voltage to which each second conductive pillar (14) of the same column is connected increases proportionally.

2. The shock protection separation structure for a shock safety somatosensory device according to claim 1, wherein: an insulating ground mat (2) positioned between a row of first containing grooves (11) and second containing grooves (12) which are close to each other is fixedly embedded at the upper end of the base (1).

3. The shock protection separation structure for a shock safety somatosensory device according to claim 1, wherein: the position of the notch of each first storage groove (11) and each second storage groove (12) is provided with a treading mechanism (3);

the treading mechanism (3) at the notch position of each first storage groove (11) and the treading mechanism (3) at the notch position of each second storage groove (12) form a group of treading mechanisms (3) for bearing the two feet of the experimenter.

4. The shock protection separation structure for a shock safety somatosensory device according to claim 3, wherein: the pedal mechanism (3) comprises a pedal (31) which can be matched with the sole of an experimenter, two support rods (32) which are distributed front and back are fixedly arranged at the bottom end of the pedal (31), pin shafts which are rotationally inserted with the bottom ends of the corresponding support rods (32) are rotationally arranged on the front side wall and the rear side wall of the inside of each first storage groove (11) and each second storage groove (12), and torsion springs are arranged at the rotation positions;

a cross beam (33) is fixedly arranged between the bottom ends of the two support rods (32), an extension block (34) is fixedly arranged on the side wall of the cross beam (33), and a first conductive column (35) which can be in butt joint with the top end of the corresponding second conductive column (14) is fixedly arranged at the bottom end of the extension block (34).

5. The shock protection separation structure for a shock safety somatosensory device according to claim 4, wherein: the first conductive column (35), the second conductive column (14), the pedal (31), the support rod (32), the cross beam (33) and the extension block (34) are all made of copper.

6. The shock protection separation structure for a shock safety somatosensory device according to claim 1, wherein: the upper end of the base (1) is provided with a hand mechanism (7) which is helpful for an experienter to stand stably.

7. The shock protection separation structure for a shock safety somatosensory device according to claim 6, wherein: the hand mechanism (7) comprises four L-shaped supporting frames (71), the four L-shaped supporting frames (71) are respectively fixedly arranged at the front side and the rear side of the side walls at the two sides of the base (1), and a hand rod (72) is fixedly arranged between the tops of the two L-shaped supporting frames (71) which are opposite in front and rear.

8. The shock protection separation structure for a shock safety somatosensory device according to claim 6, wherein: the hand mechanism (7) comprises two door-shaped frames (73), the two door-shaped frames (73) are respectively fixed on the front side and the rear side of the base (1), hanging beams (74) are fixedly arranged on the opposite side walls of the two door-shaped frames (73), T-shaped guide notches (77) are formed in the bottom ends of the hanging beams (74), I-shaped rollers (78) are slidably arranged in the T-shaped guide notches (77), hanging rods (75) extending to the lower portions of the T-shaped guide notches (77) are rotatably sleeved on the I-shaped rollers (78), and two handles (76) are symmetrically and fixedly arranged at the bottom ends of the outer walls of the hanging rods (75).

9. A method for separating an electric shock protection separation structure for an electric shock safety somatosensory device, adopting the electric shock protection separation structure for an electric shock safety somatosensory device according to claim 1, characterized by comprising the steps of:

a1, the two feet of the experimenter can pedal on the second conductive column (14) in any one of the first storage groove (11) and any one of the second storage groove (12) by themselves, and the voltage calculation module (5) can calculate the triggered high-voltage step voltage value so as to meet the body feeling requirement of the experimenter;

a2, as long as the experimenter has one foot to leave the second conductive columns (14), the control module (4) controlled by the whole circuit can not accept the circuit signals of the two second conductive columns (14) stepped on by the two feet at the same time, the circuit is immediately disconnected, the experimenter at the moment is ensured to be a non-contact circuit, the self-rescue process can be implemented through the disconnected circuit when the actual electric shock of personnel can be truly simulated, in the actual electric shock accident, the probability of being electrically injured or dead can be reduced, and the safety operation of a power grid and the personal safety hidden trouble of a trained person are reduced.

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