CN112594117A - Equipment for realizing power generation through intermittent spring water pressure monitoring - Google Patents

Abstract

The invention discloses equipment for realizing power generation through intermittent spring water pressure monitoring, which comprises an equipment body, wherein the equipment body comprises a translation main space arranged in the equipment body, a power generation carrier is arranged in the translation main space, communication spaces are symmetrically arranged in the power generation carrier from left to right, a power generation fan is arranged in the communication space on the left side, a protection device arranged in the equipment body helps the power generation device not to be damaged by water pressure impact under the condition of overlarge water pressure, the power generation device arranged in the equipment body finally converts geothermal energy into electric energy to be stored, a buoyancy device and a fixing device are arranged in the equipment body, the equipment can be stably arranged on a rock wall between intermittent springs and can be finally recovered, the whole equipment monitors the water pressure of the intermittent springs and generates power through the water pressure, the geothermal energy is well utilized, and the pollution of the coal power generation to the air is reduced.

Description

Equipment for realizing power generation through intermittent spring water pressure monitoring

Technical Field

The invention relates to the field of water pressure monitoring, in particular to equipment for realizing power generation through intermittent spring water pressure monitoring.

Background

The intermittent spring is a hot spring which is intermittently sprayed, and is mostly generated in an area with active volcanic motion, in a volcanic active area, lava makes a stratum hydrated into water vapor, the water vapor rises along a crack, and is condensed into water with high temperature when the temperature drops below a vaporization point, and the water vapor is sprayed once at intervals to form the intermittent spring.

Disclosure of Invention

In order to solve the problems, the embodiment designs equipment for realizing power generation through intermittent spring water pressure monitoring, and the equipment for realizing power generation through intermittent spring water pressure monitoring comprises a machine body, wherein a translation main space is arranged in the machine body, a power generation carrier is arranged in the translation main space, communication spaces are symmetrically arranged in the power generation carrier in the left and right direction, a power generation fan is arranged in the communication space on the left side, a power generation shell is arranged on the rear side of the power generation fan, a reset space is arranged in the power generation shell, a water pressure monitoring space is arranged on the left side of the translation main space, a sixth transmission space is arranged on the upper side of the water pressure monitoring space, a seventh transmission space is arranged on the upper side of the sixth transmission space, a fifth transmission space is arranged on the right side of the seventh transmission space, translation auxiliary spaces are symmetrically arranged on the upper and lower sides of the translation main space, and four fixed spaces are symmetrically arranged in the, a first transmission space is arranged on the right side of the fixed space at the lower left, an impact space is arranged on the right side of the first transmission space, a buoyancy space is arranged on the rear side of the impact space, the upper side of the first transmission space is arranged, a third transmission space is arranged on the right side of the second transmission space, a fourth transmission space is arranged on the lower side of the third transmission space, a water pressure monitoring space, a sixth transmission space, a seventh transmission space, a fifth transmission space, each translation auxiliary space, the power generation shell, the translation main space, the power generation carrier and a protection device for protecting power generation equipment from being impacted by excessive water pressure are arranged in the reset space, the protection device comprises an energy storage motor fixedly arranged on the front wall of the reset space, a reset auxiliary shaft is rotationally connected with power on the rear side wall of the energy storage motor, and a reset sliding block is connected on the reset auxiliary shaft in a sliding manner, a spring is connected between the reset sliding block and the rear side wall of the energy storage motor, a reset fixed shaft is fixedly connected to the front wall of the reset space, an electromagnet is fixedly connected to the reset fixed shaft, a push rod is fixedly connected to the reset sliding block, the push rod extends downwards to penetrate through the bottom wall of the reset space to enter the communicating space, a sealing cow belt is connected between the push rod and the power generation shell, a reset rotating block is fixedly connected to the reset auxiliary shaft, auxiliary spaces are symmetrically arranged on the reset rotating block from top to bottom, a friction sliding block is slidably connected to each auxiliary space, a hinge rod is hinged between each friction sliding block and the reset sliding block, a reset main shaft is rotatably connected to the rear wall of the reset space, a reset disc and a sixth bevel gear are fixedly connected to the front and the rear of the reset main shaft, and each friction sliding block can be in friction, a protective transmission shaft is rotatably connected between the upper wall and the lower wall of the reset space, the protective transmission shaft extends upwards to penetrate through the top wall of the reset space and enter the communicated space, the protective transmission shaft extends upwards to penetrate through the bottom wall of the upper translation auxiliary space and enter the translation auxiliary space, the protective transmission shaft extends upwards to penetrate through the bottom wall of the fifth transmission space and enter the fifth transmission space and is rotatably connected with the top wall of the fifth transmission space, the protective transmission shaft extends downwards to penetrate through the bottom wall of the reset space and enter the communicated space, the protective transmission shaft extends downwards to penetrate through the top wall of the lower translation auxiliary space and enter the lower translation auxiliary space, the protective transmission shaft is vertically and symmetrically and fixedly connected with a movable gear, an elastic auxiliary pulley is fixedly connected on the protective transmission shaft, and a protective rack is fixedly connected on the rear wall of each translation auxiliary space, the left side of each protection rack is fixedly and vertically symmetrically connected with T-shaped auxiliary shafts, two T-shaped auxiliary shafts on the left side of each protection rack are respectively and slidably connected with an auxiliary single rack, each auxiliary single rack is respectively connected with a spring between the protection racks, each protection rack can be meshed with the movable gear, each auxiliary single rack can be meshed with the movable gear, a fifth transmission shaft is rotatably connected between the upper wall and the lower wall of the water pressure monitoring space, the fifth transmission shaft extends upwards to penetrate through the bottom wall of the sixth transmission space to enter the sixth transmission space, the fifth transmission shaft is fixedly connected with a rotating disc and a waterwheel up and down, a butting block is slidably connected in the rotating disc, a spring is connected between the butting block and the rotating disc, and the top wall of the sixth transmission space is rotatably connected with a sixth transmission shaft, the sixth transmission shaft extends upwards to penetrate through the bottom wall of the seventh transmission space to enter the seventh transmission space and is rotatably connected with the top wall of the seventh transmission space, an elastic main belt wheel and a groove disc are fixedly connected to the sixth transmission shaft from top to bottom, the groove disc can be abutted against the abutting block, and an elastic power belt is connected between the elastic main belt wheel and the elastic auxiliary belt wheel.

Preferably, each of the fixing space, the first transmission shaft, the second transmission space, the third transmission space and the fourth transmission space is provided with a fixing device for fixing power generation equipment, the power generation fan and the power generation shell are provided with a power generation device, and the impact space and the buoyancy space are provided with buoyancy devices for recovering the equipment.

Preferably, the fixing device comprises a power motor fixedly installed on the right wall of the first transmission space, a first transmission shaft is rotationally connected to the left side surface of the power motor, a first bevel gear is fixedly connected to the first transmission shaft, a second transmission shaft is rotationally connected to the top wall of the first transmission space, the second transmission shaft extends upwards to penetrate through the bottom wall of the second transmission space and enter the second transmission space, second bevel gears are fixedly connected to the second transmission shaft in an up-and-down symmetrical manner, the second bevel gears at the lower side are meshed with the first bevel gear, a third transmission shaft is rotationally connected to the right wall of the second transmission space, the third transmission shaft extends rightwards to penetrate through the left wall of the third transmission space and enter the third transmission space, a third bevel gear and a power main belt pulley are fixedly connected to the left and right of the third transmission shaft, and the third bevel gear is meshed with the second bevel gear at the upper side, fourth transmission space left side wall rotates and is connected with the fourth transmission shaft, fixedly connected with power auxiliary pulley on the fourth transmission shaft, power auxiliary pulley with be connected with the power belt between the power main pulley, every a fixed space left and right sides side threaded connection has the screw thread axle, every fixedly connected with fastening screw on the screw thread axle, every be equipped with the key on the screw thread axle, under a left side the screw thread axle with sliding connection between the first transmission shaft, upper left the screw thread axle with sliding connection between the third transmission shaft, upper right the screw thread axle with sliding connection between the third transmission shaft, lower right the screw thread axle with sliding connection between the fourth transmission shaft.

Preferably, the power generation device comprises an energy storage motor fixedly mounted on the front wall of the reset space, a power generation shaft is rotationally connected to the front side face of the energy storage motor, the power generation shaft extends forwards to penetrate through the front wall of the reset space to enter the communication space, and a power generation fan is fixedly connected to the power generation shaft.

Preferably, the buoyancy device comprises a power motor fixedly installed on the left wall of the impact space, the right side face of the power motor is connected with an impact main shaft in a rotating mode, the impact main shaft is fixedly connected with a fourth bevel gear, an impact auxiliary shaft is connected between the upper wall and the lower wall of the impact space in a rotating mode, the impact auxiliary shaft is fixedly connected with a fifth bevel gear and an impact cam from top to bottom, the fourth bevel gear is meshed with the fifth bevel gear, the right wall of the impact space is fixedly provided with an inflation mechanism, the inflation mechanism extends rightwards to enter the buoyancy space, the impact cam can be abutted against the inflation mechanism, and an air bag is arranged on the inflation mechanism.

The invention has the beneficial effects that: the invention relates to equipment for realizing power generation by monitoring water pressure of intermittent springs, wherein a protection device is arranged in a machine body to help a power generation device not to be damaged by water pressure impact under the condition of overlarge water pressure, the power generation device arranged in the machine body finally converts geothermal energy into electric energy to be stored, a buoyancy device and a fixing device are arranged in the machine body, so that the equipment can be stably arranged on a rock wall between the intermittent springs and can be finally recycled, the whole equipment generates power by monitoring the water pressure of the intermittent springs and the water pressure, the geothermal energy is well utilized, and the pollution of coal power generation to air is reduced.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the structure A-A of FIG. 1;

FIG. 3 is a schematic diagram of B-B of FIG. 1;

FIG. 4 is a schematic diagram of the structure of C-C in FIG. 1;

FIG. 5 is a schematic diagram of D-D of FIG. 1;

fig. 6 is a schematic diagram of the structure of E-E in fig. 5.

Detailed Description

The invention will now be described in detail with reference to fig. 1-6, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The invention relates to equipment for realizing power generation by monitoring intermittent spring water pressure, which comprises a machine body 21, wherein a translation main space 47 is arranged in the machine body 21, a power generation carrier 48 is arranged in the translation main space 47, communicating spaces 50 are symmetrically arranged in the power generation carrier 48 from left to right, a power generation fan 71 is arranged in the communicating space 50 on the left side, a power generation shell 73 is arranged on the rear side of the power generation fan 71, a reset space 86 is arranged in the power generation shell 73, a water pressure monitoring space 60 is arranged on the left side of the translation main space 47, a sixth transmission space 63 is arranged on the upper side of the water pressure monitoring space 60, a seventh transmission space 69 is arranged on the upper side of the sixth transmission space 63, a fifth transmission space 45 is arranged on the right side of the seventh transmission space 69, translation auxiliary spaces 42 are symmetrically arranged up and down in the translation main space 47, four fixed spaces 29 are symmetrically arranged in the machine body 21 from front to, a first transmission space 22 is arranged on the right side of the left lower fixing space 29, an impact space 59 is arranged on the right side of the first transmission space 22, a buoyancy space 51 is arranged on the rear side of the impact space 59, the upper side of the first transmission space 22 is provided with a third transmission space 33 on the right side of the second transmission space 32, a fourth transmission space 36 is arranged on the lower side of the third transmission space 33, a protection device for protecting power generation equipment from being impacted by excessive water pressure is arranged in the water pressure monitoring space 60, the sixth transmission space 63, the seventh transmission space 69, the fifth transmission space 45, each translation auxiliary space 42, the power generation shell 73, the translation main space 47, the power generation carrier 48 and the reset space 86, the protection device comprises an energy storage motor 74 fixedly arranged on the front wall of the reset space 86, and a reset auxiliary shaft 75 is connected to the rear side wall of the energy storage motor 74 in a power rotation manner, the energy storage device is characterized in that a reset sliding block 76 is connected to the reset auxiliary shaft 75 in a sliding manner, a spring is connected between the reset sliding block 76 and the rear side wall of the energy storage motor 74, a reset fixing shaft 87 is fixedly connected to the front wall of the reset space 86, an electromagnet 88 is fixedly connected to the reset fixing shaft 87, a push rod 89 is fixedly connected to the reset sliding block 76, the push rod 89 extends downwards to penetrate through the bottom wall of the reset space 86 to enter the communicating space 50, a sealing cow belt 90 is connected between the push rod 89 and the power generation shell 73, a reset rotating block 80 is fixedly connected to the reset auxiliary shaft 75, auxiliary spaces 81 are symmetrically arranged up and down on the reset rotating block 80, a friction sliding block 79 is connected to each auxiliary space 81 in a sliding manner, a hinged rod 78 is hinged between each friction sliding block 79 and the reset sliding block 76, and a reset main shaft 83 is rotatably, a reset disc 82 and a sixth bevel gear 84 are fixedly connected to the reset main shaft 83 in a front-rear direction, each friction slider 79 can be in friction fit with the reset disc 82, a protective transmission shaft 70 is rotatably connected between the upper wall and the lower wall of the reset space 86, the protective transmission shaft 70 extends upward to penetrate through the top wall of the reset space 86 and enter the communicating space 50, the protective transmission shaft 70 continues to extend upward to penetrate through the bottom wall of the upper translational auxiliary space 42 and enter the translational auxiliary space 42, the protective transmission shaft 70 continues to extend upward to penetrate through the bottom wall of the fifth transmission space 45 and enter the fifth transmission space 45 and are rotatably connected with the top wall of the fifth transmission space 45, the protective transmission shaft 70 extends downward to penetrate through the bottom wall of the reset space 86 and enter the communicating space 50, and the protective transmission shaft 70 continues to extend downward to penetrate through the lower translational auxiliary space 42 and enter the lower translational auxiliary space 42, the protective transmission shaft 70 is vertically and symmetrically and fixedly connected with movable gears 43, the protective transmission shaft 70 is fixedly connected with an elastic secondary pulley 44, the rear wall of each translational auxiliary space 42 is fixedly connected with a protective rack 41, the left side of each protective rack 41 is vertically and symmetrically and fixedly connected with a T-shaped auxiliary shaft 39, two T-shaped auxiliary shafts 39 on the left side of each protective rack 41 are respectively and slidably connected with an auxiliary single rack 40, each auxiliary single rack 40 is respectively connected with a spring between the protective rack 41, each protective rack 41 can be meshed with the movable gear 43, each auxiliary single rack 40 can be meshed with the movable gear 43, a fifth transmission shaft 61 is rotatably connected between the upper wall and the lower wall of the water pressure monitoring space 60, and the fifth transmission shaft 61 extends upwards to penetrate through the bottom wall of the sixth transmission space 63 to enter the sixth transmission space 63, fixedly connected with rolling disc 66 about fifth transmission shaft 61, waterwheel 62, sliding connection has butt joint piece 65 in the rolling disc 66, butt joint piece 65 with be connected with the spring between the rolling disc 66, sixth transmission space 63 roof rotates and is connected with sixth transmission shaft 67, sixth transmission shaft 67 upwards extends and runs through seventh transmission space 69 diapire gets into in the seventh transmission space 69 with rotate between the seventh transmission space 69 roof and connect, fixedly connected with elasticity driving pulley 68, recess dish 64 about sixth transmission shaft 67, recess dish 64 can with butt between the butt joint piece 65, elasticity driving pulley 68 with be connected with the elasticity driving pulley between the elasticity secondary pulley 44.

Advantageously, each of said fixing space 29, said first transmission shaft 23, said second transmission space 32, said third transmission space 33 and said fourth transmission space 36 is provided with fixing means for fixing power generating equipment, said power generating fan 71, said power generating housing 73 are provided with power generating means, and said impingement space 59, said buoyancy space 51 are provided with buoyancy means for recovering equipment.

Advantageously, the fixing device comprises a power motor 91 fixedly installed on the right wall of the first transmission space 22, a first transmission shaft 23 is rotationally connected to the left side surface of the power motor 91, a first bevel gear 26 is fixedly connected to the first transmission shaft 23, a second transmission shaft 27 is rotationally connected to the top wall of the first transmission space 22, the second transmission shaft 27 extends upwards to penetrate through the bottom wall of the second transmission space 32 to enter the second transmission space 32, second bevel gears 28 are fixedly connected to the second transmission shaft 27 in an up-and-down symmetrical manner, the second bevel gear 28 is meshed with the first bevel gear 26 at the lower side, a third transmission shaft 31 is rotationally connected to the right wall of the second transmission space 32, the third transmission shaft 31 extends rightwards to penetrate through the left wall of the third transmission space 33 to enter the third transmission space 33, and a third bevel gear 30 is fixedly connected to the left and right of the third transmission shaft 31, Power primary pulley 34, third bevel gear 30 and upside meshing between the second bevel gear 28, fourth transmission space 36 left side wall rotates and is connected with fourth transmission shaft 38, fixedly connected with power secondary pulley 37 on the fourth transmission shaft 38, power secondary pulley 37 with be connected with the power band between the power primary pulley 34, every a side threaded connection has threaded shaft 24 about the dead space 29, every fixedly connected with fastening screw 25 on the threaded shaft 24, every be equipped with the key on the threaded shaft 24, down on a left side threaded shaft 24 with sliding connection between the first transmission shaft 23, on a left side threaded shaft 24 with sliding connection between the third transmission shaft 31, on a right side threaded shaft 24 with sliding connection between the third transmission shaft 31, down on a right side threaded shaft 24 with sliding connection between the fourth transmission shaft 38.

Advantageously, the power generating device comprises the energy storage motor 74 fixedly mounted on the front wall of the reset space 86, a power generating shaft 72 is rotationally connected to the front side of the energy storage motor 74, the power generating shaft 72 extends forwards through the front wall of the reset space 86 into the communicating space 50, and a power generating fan 71 is fixedly connected to the power generating shaft 72.

Advantageously, the buoyancy device comprises the power motor 91 fixedly installed on the left wall of the impact space 59, the right side surface of the power motor 91 is in power rotation connection with an impact main shaft 56, the impact main shaft 56 is fixedly connected with a fourth bevel gear 57, an impact auxiliary shaft 55 is rotatably connected between the upper wall and the lower wall of the impact space 59, the impact auxiliary shaft 55 is vertically and fixedly connected with a fifth bevel gear 58 and an impact cam 54, the fourth bevel gear 57 is meshed with the fifth bevel gear 58, the right wall of the impact space 59 is fixedly provided with an inflation mechanism 53, the inflation mechanism 53 extends rightwards to enter the buoyancy space 51, the impact cam 54 can abut against the inflation mechanism 53, and the inflation mechanism 53 is provided with an air bag 52.

The use steps herein are described in detail below with reference to fig. 1-6:

place the equipment in the geyser, power motor 91 is started in the forward direction, thereby drive first transmission shaft 23 to rotate, thereby drive first bevel gear 26 to rotate, thereby drive downside second bevel gear 28 to rotate, thereby drive second transmission shaft 27 to rotate, thereby drive upside second bevel gear 28 to rotate, thereby drive third bevel gear 30 to rotate, thereby drive third transmission shaft 31 to rotate, thereby drive power primary pulley 34 to rotate, pivoted power primary pulley 34 transmits power to power secondary pulley 37 through the power belt, thereby drive fourth transmission shaft 38 to rotate, first transmission shaft 23 of pivoted, third transmission shaft 31, fourth transmission shaft 38 drives four threaded shafts 24 to move and rotate to the left and right sides, thereby drive four fastening screws 25 to move and rotate to the left and right sides, thereby fix the equipment between the geyser rock walls.

Under the big normal condition of water pressure, spun spring gets into water pressure monitoring space 60 with higher speed, thereby it rotates to drive waterwheel 62, thereby it rotates to drive fifth transmission shaft 61, thereby it rotates to drive rolling disc 66, because water pressure is big inadequately, thereby it is not fast enough to make waterwheel 62 rotational speed, thereby can't throw away butt piece 65 and make butt piece 65 and recess dish 64 butt, normal electricity generation, spring water gets into left side intercommunication space 50 blowout again through translation main space 47, thereby it rotates to drive generating fan 71, thereby it rotates to drive generating shaft 72, thereby it stores to generate electricity at energy storage motor 74, the electricity generation is changed geothermal energy into kinetic energy, change kinetic energy into electric energy and store again.

When the water pressure is too high, in order to protect the power generation equipment from being damaged, the power generation equipment needs to be collected, the electromagnet 88 is electrified, the water flow pushes the push rod 89 to move forwards, so that the electromagnet 88 attracts the push rod 89, the friction slide block 79 is not in contact with the reset disc 82, the rotating speed of the waterwheel 62 is fast enough, the abutting block 65 is abutted against the groove disc 64, the rotating rotary disc 66 drives the groove disc 64 to rotate, the sixth transmission shaft 67 is driven to rotate, the elastic main belt wheel 68 is driven to rotate, the rotating elastic main belt wheel 68 drives the elastic auxiliary belt wheel 44 to rotate through the elastic power belt, the protective transmission shaft 70 is driven to rotate, the seventh bevel gear 85 and the two movable gears 43 are driven to rotate, the rotating movable gear 43 drives the protective rack 41 to rotate, the protective rack 41 is fixed, and the power generation carrier 48 is driven to move leftwards integrally, thereby, the right communication space 50 is communicated with the translation main space 47, so that the power generation fan 71 cannot rotate, the power generation is stopped, and the power generation device is protected from being damaged by strong water pressure.

When the water pressure is reduced, the rotation speed of the waterwheel 62 is insufficient, so that the abutting block 65 is separated from the abutting connection with the groove disc 64, the electricity in the electromagnet 88 is cut off, the electromagnet 88 is made to move downwards, the two friction sliding blocks 79 are made to contact with the reset disc 82, the energy storage motor 74 is started, the reset auxiliary shaft 75 is driven to rotate, the reset rotating block 80 is driven to rotate, the reset disc 82 is driven to rotate through the friction sliding blocks 79, the reset main shaft 83 is driven to rotate, the sixth bevel gear 84 is driven to rotate, the seventh bevel gear 85 is driven, the protection transmission shaft 70 is driven to rotate, the two movable gears 43 are driven to rotate, the power generation carrier 48 is driven to move rightwards integrally and reset, the left communicating space 50 is made to communicate with the translation main space 47, the energy storage motor 74 is closed.

When the equipment needs to be recovered, the power motor 91 is started reversely, so that the impact main shaft 56 is driven to rotate, the fourth bevel gear 57 is driven to rotate, the fifth bevel gear 58 is driven to rotate, the impact auxiliary shaft 55 is driven to rotate, the impact cam 54 is abutted against the inflation mechanism 53, the air bag 52 is rapidly expanded, the power motor 91 is closed, the power motor 91 is started forwardly, the four fastening screws 25 are screwed out of the rock wall to reset, the power motor 91 is closed, so that the whole equipment is taken out by the sprayed spring water, and the recovery of the equipment is realized.

The invention has the beneficial effects that: the invention relates to equipment for realizing power generation by monitoring water pressure of intermittent springs, wherein a protection device is arranged in a machine body to help a power generation device not to be damaged by water pressure impact under the condition of overlarge water pressure, the power generation device arranged in the machine body finally converts geothermal energy into electric energy to be stored, a buoyancy device and a fixing device are arranged in the machine body, so that the equipment can be stably arranged on a rock wall between the intermittent springs and can be finally recycled, the whole equipment generates power by monitoring the water pressure of the intermittent springs and the water pressure, the geothermal energy is well utilized, and the pollution of coal power generation to air is reduced.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (5)

1. An equipment for realizing power generation through intermittent spring water pressure monitoring comprises a machine body, and is characterized in that: the device comprises a machine body, wherein a translation main space is arranged in the machine body, a power generation carrier is arranged in the translation main space, communication spaces are symmetrically arranged in the power generation carrier in the left and right direction, a power generation fan is arranged in the communication space on the left side, a power generation shell is arranged on the rear side of the power generation fan, a reset space is arranged in the power generation shell, a water pressure monitoring space is arranged on the left side of the translation main space, a sixth transmission space is arranged on the upper side of the water pressure monitoring space, a seventh transmission space is arranged on the upper side of the sixth transmission space, a fifth transmission space is arranged on the right side of the seventh transmission space, translation auxiliary spaces are symmetrically arranged in the translation main space in the up-down direction, four fixed spaces are symmetrically arranged in the machine body in the front-back and left direction, a first transmission space is arranged on the right side of the fixed space, the upper side of the first transmission space is provided with a third transmission space, the right side of the second transmission space is provided with a third transmission space, the lower side of the third transmission space is provided with a fourth transmission space, the water pressure monitoring space, the sixth transmission space, the seventh transmission space, the fifth transmission space, each translation auxiliary space, the power generation shell, the translation main space, the power generation carrier and the reset space are internally provided with a protection device for protecting power generation equipment from being impacted by excessive water pressure, the protection device comprises an energy storage motor fixedly installed on the front wall of the reset space, a reset auxiliary shaft is rotationally connected with the rear side wall of the energy storage motor in a power rotating way, a reset sliding block is connected on the reset auxiliary shaft in a sliding way, a spring is connected between the reset sliding block and the rear side wall of the energy storage motor, a reset fixed shaft is fixedly connected on the front wall of the reset space, and an electromagnet, the reset slide block is fixedly connected with a push rod, the push rod extends downwards to penetrate through the bottom wall of the reset space to enter the communicating space, a sealing cattle belt is connected between the push rod and the power generation shell, the reset auxiliary shaft is fixedly connected with a reset rotary block, the reset rotary block is symmetrically provided with auxiliary spaces up and down, each auxiliary space is connected with a friction slide block in a sliding manner, each friction slide block is hinged with a hinge rod between the reset slide block and the reset slide block, the rear wall of the reset space is rotatably connected with a reset main shaft, the front part and the rear part of the reset main shaft are fixedly connected with a reset disc and a sixth bevel gear, each friction slide block can be in friction fit with the reset disc, a protective transmission shaft is rotatably connected between the upper wall and the lower wall of the reset space and extends upwards to penetrate through the top wall of the reset, the protection transmission shaft continuously extends upwards to penetrate through the bottom wall of the upper translation auxiliary space to enter the translation auxiliary space, the protection transmission shaft continuously extends upwards to penetrate through the bottom wall of the fifth transmission space to enter the fifth transmission space and is rotatably connected with the top wall of the fifth transmission space, the protection transmission shaft downwardly extends to penetrate through the bottom wall of the reset space to enter the communication space, the protection transmission shaft continuously extends downwards to penetrate through the top wall of the lower translation auxiliary space to enter the lower translation auxiliary space, the protection transmission shaft is vertically and symmetrically and fixedly connected with moving gears, the protection transmission shaft is fixedly connected with elastic auxiliary pulleys, a rear wall in each translation auxiliary space is fixedly connected with protection racks, the left side of each protection rack is vertically and symmetrically and fixedly connected with T-shaped auxiliary shafts, and two T-shaped auxiliary shafts on the left side of each protection rack are respectively and slidably connected with auxiliary single racks, each auxiliary single rack is respectively connected with a spring between the protection racks, each protection rack can be meshed with the movable gear, each auxiliary single rack can be meshed with the movable gear, a fifth transmission shaft is rotatably connected between the upper wall and the lower wall of the water pressure monitoring space, the fifth transmission shaft extends upwards to penetrate through the bottom wall of the sixth transmission space to enter the sixth transmission space, the fifth transmission shaft is fixedly connected with a rotating disc and a waterwheel from top to bottom, a butting block is slidably connected in the rotating disc, a spring is connected between the butting block and the rotating disc, the top wall of the sixth transmission space is rotatably connected with a sixth transmission shaft, the sixth transmission shaft extends upwards to penetrate through the bottom wall of the seventh transmission space to enter the seventh transmission space to be rotatably connected with the top wall of the seventh transmission space, the sixth transmission shaft is fixedly connected with an elastic main belt wheel and a groove disc up and down, the groove disc can be abutted against the abutting blocks, and an elastic power belt is connected between the elastic main belt wheel and the elastic auxiliary belt wheel.

2. The apparatus for generating electricity through intermittent spring water pressure monitoring as claimed in claim 1, wherein: fixing devices for fixing power generation equipment are arranged in each fixing space, the first transmission shaft, the second transmission space, the third transmission space and the fourth transmission space, a power generation fan and a power generation shell are internally provided with power generation devices, and an impact space and a buoyancy space are internally provided with buoyancy devices for recycling equipment.

3. The apparatus for generating electricity through intermittent spring water pressure monitoring as claimed in claim 2, wherein: the fixing device comprises a power motor fixedly arranged on the right wall of the first transmission space, a first transmission shaft is rotationally connected to the left side surface of the power motor, a first bevel gear is fixedly connected to the first transmission shaft, a second transmission shaft is rotationally connected to the top wall of the first transmission space, the second transmission shaft extends upwards to penetrate through the bottom wall of the second transmission space to enter the second transmission space, second bevel gears are fixedly connected to the second transmission shaft in an up-and-down symmetrical mode, the second bevel gears on the lower side are meshed with the first bevel gears, a third transmission shaft is rotationally connected to the right wall of the second transmission space, the third transmission shaft extends rightwards to penetrate through the left wall of the third transmission space to enter the third transmission space, a third bevel gear and a power main belt wheel are fixedly connected to the left side and the right side of the third transmission shaft, and the third bevel gear is meshed with the second bevel gear on, fourth transmission space left side wall rotates and is connected with the fourth transmission shaft, fixedly connected with power auxiliary pulley on the fourth transmission shaft, power auxiliary pulley with be connected with the power belt between the power main pulley, every a fixed space left and right sides side threaded connection has the screw thread axle, every fixedly connected with fastening screw on the screw thread axle, every be equipped with the key on the screw thread axle, under a left side the screw thread axle with sliding connection between the first transmission shaft, upper left the screw thread axle with sliding connection between the third transmission shaft, upper right the screw thread axle with sliding connection between the third transmission shaft, lower right the screw thread axle with sliding connection between the fourth transmission shaft.

4. The apparatus for generating electricity through intermittent spring water pressure monitoring as claimed in claim 2, wherein: the power generation device comprises an energy storage motor fixedly installed on the front wall of the reset space, a power generation shaft is rotationally connected to the front side face of the energy storage motor, the power generation shaft extends forwards to penetrate through the front wall of the reset space to enter the communication space, and a power generation fan is fixedly connected to the power generation shaft.

5. The apparatus for generating electricity through intermittent spring water pressure monitoring as claimed in claim 2, wherein: the buoyancy device comprises a power motor fixedly installed on the left wall of the impact space, the right side face of the power motor is connected with an impact main shaft in a rotating mode, the impact main shaft is fixedly connected with a fourth bevel gear, an impact auxiliary shaft is connected between the upper wall and the lower wall of the impact space in a rotating mode, a fifth bevel gear and an impact cam are fixedly connected to the upper portion and the lower portion of the impact auxiliary shaft in a rotating mode, the fourth bevel gear is meshed with the fifth bevel gear, the right wall of the impact space is fixedly provided with an inflation mechanism, the inflation mechanism extends rightwards to enter the buoyancy space, the impact cam can be abutted to the inflation mechanism, and an air bag is arranged on the inflation mechanism.

Images