CN115837854B - Hydraulic self-walking mobile power station - Google Patents
Hydraulic self-walking mobile power station Download PDFInfo
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- CN115837854B CN115837854B CN202310119429.1A CN202310119429A CN115837854B CN 115837854 B CN115837854 B CN 115837854B CN 202310119429 A CN202310119429 A CN 202310119429A CN 115837854 B CN115837854 B CN 115837854B
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Abstract
The invention relates to the technical field of mobile power stations, and provides a hydraulic self-walking mobile power station, which comprises a power station body, and further comprises a mobile frame, wherein a mobile seat is arranged at the bottom end of the power station body, the mobile seat is in sliding connection with the mobile frame, a plurality of damping components are correspondingly arranged between the mobile seat and the inner side wall of the mobile frame, the damping components are used for damping when the power station body and the mobile seat move to the two sides of the mobile frame, a hydraulic driving mechanism is arranged between the mobile frame and the mobile seat, the hydraulic self-walking mobile power station can stably move the heavier power station body so as to increase the charging range of the power station body, improve the practicability of the power station body, and protect the power station body in the moving process of the power station body, thereby preventing the power station body from being damaged due to the collision of external force of an automobile.
Description
Technical Field
The invention relates to the technical field of mobile power stations, in particular to a hydraulic self-walking mobile power station.
Background
The power station is one of the devices that are commonly used in real life and provide electric energy for electric vehicles and various electric bicycles, along with the continuous popularization of various electric vehicles in modern society, various power stations begin to appear their body and shadow at the roadside of the main road, and in some large-scale garages, because the controllability of electric power resources is higher than that of gasoline and the like, after purchasing electric vehicles, people can be provided with the power station that can charge for electric vehicles in the garage of their own home or the large-scale garages of public for more convenient use, thereby completing the charging operation of electric vehicles.
However, most of the existing devices for charging electric vehicles are fixed in a garage, cannot move by themselves, and suffer from the limitation of the length of the charging wire, so that a power station needs to be arranged at intervals of one end distance in the garage, which clearly generates waste of some resources, and because the charging wire is limited in length, a driver is required to stop the electric vehicle near the power station, so that the electric vehicle can be charged through the power station, and the practicability of the power station is greatly reduced.
To this problem, we propose a hydraulic pressure is from walking mobile power station, at first remove comparatively heavy power station through using hydraulic power to increase the charging range of power station, improve its practicality, and can also protect it when effectively fixing the in-process that removes the power station to thereby prevent the external force collision that receives the car and cause the problem that the power station damaged.
Disclosure of Invention
(one) solving the technical problems
Aiming at the defects of the prior art, the invention provides a hydraulic self-walking mobile power station, which uses hydraulic power to move a heavier power station so as to increase the charging range of the power station, improve the practicability of the power station, and can effectively fix the power station and protect the power station in the moving process, thereby preventing the power station from being damaged due to the collision of external force of an automobile.
(II) technical scheme
In order to achieve the above purpose, the present invention provides the following technical solutions: the hydraulic pressure is from walking type mobile power station, including the power station body, still include: the device comprises a movable frame, a hydraulic driving mechanism, a protection assembly and a stabilization assembly;
the movable frame is arranged at the bottom end of the power station body, the movable seat is connected with the movable frame in a sliding manner, a plurality of damping components are correspondingly arranged between the movable seat and the inner side wall of the movable frame, and the damping components are used for damping when the power station body and the movable seat move to the two sides of the movable frame;
the hydraulic driving mechanism is arranged between the movable frame and the movable seat and is used for driving the movable seat and the power station body to move left and right in the movable frame;
the protection assembly is arranged on the outer sides of the movable frame and the power station body and used for protecting the power station body, a plurality of control assemblies are arranged on the front portion of the protection assembly, a connecting assembly is arranged between the control assemblies and the power station body, and the control assemblies are used for performing rapid braking after the power station body moves to a designated position;
and the stabilizing component is arranged between the bottom of the power station body and the movable frame and is used for enabling the bottom of the power station body to be stable enough after moving.
In order to enable the power station body to stably slide left and right on the movable frame, preferably, a sliding rod is fixedly connected between the left and right inner walls of the movable frame, a round opening is formed in the bottom end of the movable seat, the round opening is in sliding connection with the sliding rod, and the front side and the rear side of the bottom end of the movable seat are both in sliding connection with the two sides of the top end of the movable frame.
In order to carry out the shock attenuation when power station body and movable seat remove the both sides of moving the frame, further, damper includes the snubber block, the snubber block sets up on the inside wall of moving the frame, the fixed orifices has been seted up at the middle part of snubber block, the both ends of movable seat correspond snubber block fixedly connected with installing frame, sliding connection has the sliding plate on the inner wall of installing frame, fixedly connected with and the meshing piece of fixed orifices looks adaptation on the sliding plate, be provided with a plurality of cushioning members between the inside wall of sliding plate and installing frame.
In order to drive and remove seat and power station body and remove about in removing the frame, still further, hydraulic drive mechanism includes hydraulic motor, the rear end downside fixedly connected with connector of power station body, hydraulic motor installs the top at the connector, the rear end of connector rotates and is connected with the pivot, the cover is equipped with gear one on the rear portion of pivot, gear one's upside meshing has gear two, gear two cover is established on hydraulic motor's output, the rear end fixedly connected with fixed plate of removing the frame, be provided with the pinion rack on the top of fixed plate, intermeshing between gear one and the pinion rack.
In order to protect the power station body, prevent that it from receiving external force injury, as this scheme further scheme, the protection component includes a plurality of rail guards, a plurality of the rail guards set up respectively at the front and back both ends of moving the frame, are located the fixedly connected with fixed strip between the top of a plurality of rail guards of controlling same side, are located fixedly connected with a plurality of guard plates between two rail guards of controlling same side, are located the one end that the fixed strip of rear side is close to the power station body and have seted up the spout, sliding connection has the sliding block on the inner wall of the spout of complaining, the one end of sliding block passes through connecting rod and the rear end fixed connection of power station body.
In order to enable the power station body to move to the appointed position and then carry out quick braking, as a still further scheme of the scheme, the control assembly comprises a control frame, the control frame is arranged between the outsides of fixing strips located on the front side, the upper side and the lower side of the inner rear wall of the control frame are both connected with control boards in a sliding mode, the rear ends of the control boards are fixedly connected with operation boards, the control frame is provided with two sliding grooves corresponding to the two operation boards, the two operation boards extend out to the rear side of the control frame through the corresponding sliding grooves, a double-head electric cylinder is mounted at the rear end of the control frame, the two output ends of the double-head electric cylinder are respectively fixedly connected with the corresponding operation boards, the two control boards are respectively arranged on the upper side and the lower side of the fixing strips, the top ends of the control frame are both provided with buckles, and the buckles are used for fixing charging wires.
In order to make be connected between a plurality of control assembly and the power station body, on the basis of the aforesaid scheme, coupling assembling includes the fixed frame, control frame fixed connection is between the left and right sides inside wall of fixed frame, the front end fixedly connected with mounting panel of power station body, fixedly connected with connecting plate between fixed frame and the mounting panel.
In order to make the bottom of power station body enough stable after removing, further on the basis of the aforesaid scheme, stable subassembly includes first and the stable frame of electronic jar, first front end at the power station body is installed through the installation body to electronic jar, the front end fixedly connected with stabilizer plate of removing the frame, the stabilizer tank has been seted up on the stabilizer plate, the mounting groove has all been seted up to the front and back both sides of stabilizing the frame, two all slide in the mounting groove and be provided with the damping strip, be provided with a plurality of first springs between damping strip and the corresponding mounting groove, the output of first electronic jar and the top fixed connection of stable frame.
In order to provide buffering between the sliding plate and the inner side wall of the installation frame, the buffer part further comprises a damping rod, the damping rod is arranged between the sliding plate and the inner side wall of the installation frame, and a second spring is sleeved on the outer side of the damping rod.
In order to protect the hydraulic motor, the first gear, the second gear and the fixed plate, the scheme is more optimized, and a protective frame is arranged among a plurality of protective fences positioned at the rear side.
(III) beneficial effects
Compared with the prior art, the invention provides a hydraulic self-walking mobile power station, which has the following beneficial effects:
according to the invention, the movable seat is arranged between the movable frame and the power station body, and is stably connected to the upper side of the movable frame in a sliding way through the sliding rod, meanwhile, under the control of the hydraulic driving mechanism, the power station body and the movable seat can move left and right on the movable frame, and meanwhile, the impact force born by the power station body can be relieved by virtue of the plurality of damping components which are correspondingly arranged between the movable seat and the inner side wall of the movable frame, so that when electric automobiles at different positions are required to be charged by using the power station body, excessive movement of the electric automobiles is not required, and the charging operation is increased to be more convenient;
according to the invention, after the movable seat and the power station body move to the appointed position, the power station body can keep a certain stabilizing effect after moving to the appointed position by the control effect between the control component and the corresponding fixing strip and the fixing effect between the stabilizing component and the stabilizing plate fixedly connected with the front end of the movable frame, so that the offset problem is not easy to occur;
therefore, this hydraulic pressure is from walking mobile power station can be to comparatively heavy power station body stable removal to this increases the charging range of power station body, improves its practicality, and can also protect it when effectively fixing it to the in-process that the power station body removed, thereby prevent to receive the external force collision of car and cause the problem that the power station body damaged.
Drawings
In order to more clearly illustrate the embodiments of the present 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. It is evident that the drawings in the following description are only some embodiments of the present invention and that other drawings may be obtained from these drawings without inventive effort for a person of ordinary skill in the art.
FIG. 1 is a schematic view of a partially sectioned perspective structure of the present invention;
FIG. 2 is a schematic perspective view of the whole structure of the present invention;
FIG. 3 is a schematic view in perspective, partially in section, of another angle of the present invention;
FIG. 4 is a schematic perspective view of the hydraulic driving mechanism, the power station body, the moving frame, the moving seat and the sliding rod of the present invention;
FIG. 5 is a schematic perspective view of the control assembly and the connecting assembly of the present invention;
FIG. 6 is a schematic view in partial cross-section of a stabilization assembly in accordance with the present invention;
FIG. 7 is a schematic perspective view, partially in section, of a shock absorbing assembly and a cushioning member of the present invention.
Reference numerals in the drawings represent respectively: 100. a shock absorbing assembly; 200. a hydraulic drive mechanism; 300. a protective assembly; 400. a control assembly; 500. a connection assembly; 600. a stabilizing assembly; 700. a buffer member; 1. a power station body; 2. a moving frame; 3. a movable seat; 4. a slide bar; 5. a protective frame; 101. a damper block; 102. a mounting frame; 103. a sliding plate; 104. a meshing block; 201. a hydraulic motor; 202. a connecting body; 203. a rotating shaft; 204. a first gear; 205. a second gear; 206. a fixing plate; 301. a guard rail; 302. a fixing strip; 303. a protection plate; 304. a sliding block; 305. a connecting rod; 401. a control frame; 402. a control board; 403. an operation panel; 404. a double-ended electric cylinder; 501. a fixed frame; 502. a mounting plate; 503. a connecting plate; 601. an electric cylinder I; 602. a stabilizing frame; 603. a stabilizing plate; 604. damping strips; 605. a first spring; 701. a damping rod; 702. and a second spring.
Detailed Description
The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but 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.
Referring to fig. 1, 2, 3, 4 and 7, the hydraulic self-walking mobile power station comprises a power station body 1 and a mobile frame 2, wherein a mobile seat 3 is installed at the bottom end of the power station body 1, the mobile seat 3 is slidably connected with the mobile frame 2, a sliding rod 4 is fixedly connected between the left and right inner walls of the mobile frame 2, a round opening is formed at the bottom end of the mobile seat 3, the round opening is slidably connected with the sliding rod 4, the front and rear sides of the bottom end of the mobile seat 3 are slidably connected at the two sides of the top end of the mobile frame 2, a plurality of damping assemblies 100 are correspondingly arranged between the mobile seat 3 and the inner side wall of the mobile frame 2, the damping assemblies 100 are used for damping when the power station body 1 and the mobile seat 3 move to the two sides of the mobile frame 2, the damping assemblies 100 comprise damping blocks 101, the damping blocks 101 are arranged on the inner side walls of the mobile frame 2, a fixed opening is formed in the middle of the shock absorption block 101, the two ends of the movable seat 3 are fixedly connected with the mounting frame 102 corresponding to the shock absorption block 101, the inner wall of the mounting frame 102 is slidably connected with the sliding plate 103, the sliding plate 103 is fixedly connected with the meshing block 104 matched with the fixed opening, a plurality of buffer pieces 700 are arranged between the sliding plate 103 and the inner side wall of the mounting frame 102, the buffer pieces 700 comprise damping rods 701, the damping rods 701 are arranged between the sliding plate 103 and the inner side wall of the mounting frame 102, the outer sides of the damping rods 701 are sleeved with springs II 702, when the electric automobile needs to be charged by using the power station body 1, when the power station body 1 is moved to two sides, the meshing block 104 matched with the fixed opening fixedly connected with the sliding plate 103 enters the fixed opening formed in the corresponding shock absorption block 101, the interaction force between the shock absorbing block 101 and the mounting frame 102 is reduced under the action of the elastic force of the second spring 702 sleeved on the outer side of the damping rod 701 arranged between the sliding plate 103 and the inner side wall of the mounting frame 102, and then the shock absorbing block 101 and the mounting frame 102 are quickly kept stable under the action of the damping rod 701.
Referring to fig. 1, fig. 2, fig. 3 and fig. 4, the hydraulic driving mechanism 200 is disposed between the moving frame 2 and the moving seat 3, the hydraulic driving mechanism 200 is used for driving the moving seat 3 and the power station body 1 to move left and right in the moving frame 2, the hydraulic driving mechanism 200 includes a hydraulic motor 201, a connecting body 202 is fixedly connected to a bottom side of a rear end of the power station body 1, the hydraulic motor 201 is mounted at a top end of the connecting body 202, a rotating shaft 203 is rotatably connected to a rear end of the connecting body 202, a first gear 204 is sleeved on a rear portion of the rotating shaft 203, a second gear 205 is engaged with an upper side of the first gear 204, the second gear 205 is sleeved on an output end of the hydraulic motor 201, a fixed plate 206 is fixedly connected to a rear end of the moving frame 2, a toothed plate 206 is disposed on a top end of the fixed plate 206, the toothed plate 204 and the toothed plate are engaged with each other, a protection frame 5 is disposed between the plurality of protection rails 301 on the rear side, and the power station body 1 is required to be adjusted because the position of the electric automobile is different, the hydraulic motor 201 is started to drive the second gear 205 to rotate, and then the second gear 205 is driven to rotate, and the first gear 204 is simultaneously driven to rotate and the toothed plate 206 is meshed with the fixed plate 202 on the toothed plate 202 to move the rotating shaft 2, thereby slide the power station body 1, and the sliding seat 2 is stably, and the sliding seat 2 is moved.
Referring to fig. 1, 2, 3 and 5, a protection assembly 300 is disposed on the outer sides of a moving frame 2 and a power station body 1, the protection assembly 300 is used for protecting the power station body 1, the protection assembly 300 includes a plurality of protection fences 301, the protection assemblies 301 are respectively disposed at front and rear ends of the moving frame 2, a fixing strip 302 is fixedly connected between top ends of the protection fences 301 disposed on the same side, a plurality of protection plates 303 are fixedly connected between two protection fences 301 disposed on the same side, a chute is disposed at one end of the fixing strip 302 disposed on the rear side near the power station body 1, a sliding block 304 is slidingly connected on an inner wall of the chute, one end of the sliding block 304 is fixedly connected with a rear end of the power station body 1 through a connecting rod 305, a plurality of control assemblies 400 are disposed on the front portion of the protection assembly 300, a connecting assembly 500 is disposed between the control assemblies 400 and the power station body 1, the control assembly 400 is used for quick braking after the power station body 1 moves to a designated position, the control assembly 400 comprises a control frame 401, the control frame 401 is arranged between the outer sides of the fixing strips 302 positioned at the front side, the heights of a plurality of guard rails 301 positioned in the middle of the front side are slightly lower than those of other guard rails 301, control boards 402 are slidably connected to the upper side and the lower side of the inner rear wall of the control frame 401, an operation board 403 is fixedly connected to the rear end of the control board 402, two sliding grooves are formed in the control frame 401 corresponding to the two operation boards 403, the two operation boards 403 extend to the rear side of the control frame 401 through the corresponding sliding grooves, a double-head electric cylinder 404 is arranged at the rear end of the control frame 401, two output ends of the double-head electric cylinder 404 are fixedly connected with the corresponding operation boards 403 respectively, the two control boards 402 are arranged on the upper side and the lower side of the fixing strips 302 respectively, buckles are arranged at the top end of the control frame 401, the buckle is used for fixed charging wire, coupling assembling 500 includes fixed frame 501, control frame 401 fixed connection is between the left and right sides inside wall of fixed frame 501, the front end fixedly connected with mounting panel 502 of power station body 1, fixedly connected with connecting plate 503 between fixed frame 501 and the mounting panel 502, after removing seat 3 and power station body 1 and removing the assigned position, after power station body 1 removes the assigned position through fixed frame 501, connecting plate 503 and mounting panel 502 fixed connection's control frame 401, start double-end electric cylinder 404 makes two control panels 403 drive two control panels 402 start the centre gripping in the upper and lower both sides of fixed strip 302 assigned position, thereby remain stable to power station body 1.
Referring to fig. 1, fig. 2, fig. 3 and fig. 6, the stabilizing assembly 600 is disposed between the bottom of the power station body 1 and the moving frame 2, and is used for stabilizing the bottom of the power station body 1 after moving, the stabilizing assembly 600 includes a first electric cylinder 601 and a stabilizing frame 602, the first electric cylinder 601 is mounted at the front end of the power station body 1 through a mounting body, the front end of the moving frame 2 is fixedly connected with a stabilizing plate 603, stabilizing grooves are formed in the stabilizing plate 603, mounting grooves are formed in the front side and the rear side of the stabilizing frame 602, damping strips 604 are slidably disposed in the two mounting grooves, a plurality of first springs 605 are disposed between the damping strips 604 and the corresponding mounting grooves, the output end of the first electric cylinder 601 is fixedly connected with the top end of the stabilizing frame 602, after the power station body 1 moves to a designated position, the first electric cylinder 601 is started to push the stabilizing frame 602 into the stabilizing grooves formed in the stabilizing plate 603, and then a large friction force is generated between the two damping strips 604 and the inner side walls of the stabilizing grooves under the thrust of the plurality of first springs 605 disposed between the damping strips 604 and the corresponding mounting grooves, so that the bottom of the power station body 1 is kept stable.
In summary, the use principle of the hydraulic self-walking type mobile power station is as follows: when the electric automobile needs to be charged by using the power station body 1, when the power station body 1 is moved to two sides, firstly the meshing block 104 which is fixedly connected with the sliding plate 103 and is matched with the fixed opening enters the fixed opening formed on the corresponding damping block 101, then under the action of the elastic force of the spring II 702 which is sleeved outside the damping rod 701 and is arranged between the sliding plate 103 and the inner side wall of the mounting frame 102, the interaction force between the damping block 101 and the mounting frame 102 is reduced, then under the action of the damping rod 701, the damping block 101 and the mounting frame 102 are quickly kept stable, when the position of the power station body 1 needs to be adjusted because the stop position of the electric automobile is different, the hydraulic motor 201 is started to drive the gear II 205 to rotate, then the gear II 205 drives the gear I204 to rotate and simultaneously enables the gear II to be meshed with the toothed plate arranged on the fixed plate 206, so that the gear I204 drives the rotating shaft 203, the connecting body 202, the movable seat 3 and the power station body 1 to move, so that the gear I moves between the top end of the movable frame 2 and the sliding rod 4 to adjust the position of the power station body 1, after the movable seat 3 and the power station body 1 move to the designated position, the control frame 401 fixedly connected through the fixed frame 501, the connecting plate 503 and the mounting plate 502 starts the double-headed electric cylinder 404 after the power station body 1 moves to the designated position, so that the two control plates 402 are driven by the two operation plates 403 to start to be clamped on the upper side and the lower side of the designated position of the fixed bar 302, the power station body 1 is kept stable, after the power station body 1 moves to the designated position, the electric cylinder I601 is started to push the stabilizing frame 602 to enter the stabilizing groove formed on the stabilizing plate 603, then, under the thrust action of the springs 605 arranged between the damping strips 604 and the corresponding mounting grooves, a huge friction force is generated between the two damping strips 604 and the inner side walls of the stabilizing grooves, so that the bottom of the power station body 1 is kept stable.
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 a hydraulic pressure is from walking mobile power station, includes power station body (1), its characterized in that still includes:
the mobile power station comprises a mobile frame (2), wherein a mobile seat (3) is arranged at the bottom end of a power station body (1), the mobile seat (3) is in sliding connection with the mobile frame (2), a plurality of damping components (100) are correspondingly arranged between the mobile seat (3) and the inner side wall of the mobile frame (2), and the damping components (100) are used for damping when the power station body (1) and the mobile seat (3) move to two sides of the mobile frame (2);
the hydraulic driving mechanism (200) is arranged between the movable frame (2) and the movable seat (3), and the hydraulic driving mechanism (200) is used for driving the movable seat (3) and the power station body (1) to move left and right in the movable frame (2);
the protection assembly (300) is arranged on the outer side of the movable frame (2) and the power station body (1), the protection assembly (300) is used for protecting the power station body (1), a plurality of control assemblies (400) are arranged on the front part of the protection assembly (300), a connecting assembly (500) is arranged between the control assemblies (400) and the power station body (1), and the control assemblies (400) are used for performing quick braking after the power station body (1) moves to a designated position;
stable subassembly (600), stable subassembly (600) set up between the bottom of power station body (1) and remove frame (2) for make the bottom of power station body (1) enough stable after removing, stable subassembly (600) are including electronic jar one (601) and stable frame (602), electronic jar one (601) is installed at the front end of power station body (1) through the installation body, the front end fixedly connected with stabilizer plate (603) of removing frame (2), the stabilizer tank has been seted up on stabilizer plate (603), the mounting groove has all been seted up to the front and back both sides of stable frame (602), two all slide in the mounting groove and be provided with damping strip (604), be provided with a plurality of first (605) of springs between damping strip (604) and the corresponding mounting groove, the output of electronic jar one (601) and the top fixed connection of stabilizer frame (602).
2. The hydraulic self-walking mobile power station according to claim 1, wherein a sliding rod (4) is fixedly connected between the left and right inner walls of the mobile frame (2), a round opening is formed in the bottom end of the mobile seat (3), the round opening is slidably connected with the sliding rod (4), and the front side and the rear side of the bottom end of the mobile seat (3) are slidably connected with the two sides of the top end of the mobile frame (2).
3. The hydraulic self-walking mobile power station according to claim 1, wherein the damping component (100) comprises a damping block (101), the damping block (101) is arranged on the inner side wall of the mobile frame (2), a fixing opening is formed in the middle of the damping block (101), two ends of the mobile seat (3) are fixedly connected with a mounting frame (102) corresponding to the damping block (101), sliding plates (103) are slidably connected onto the inner wall of the mounting frame (102), meshing blocks (104) matched with the fixing opening are fixedly connected onto the sliding plates (103), and a plurality of buffering pieces (700) are arranged between the sliding plates (103) and the inner side wall of the mounting frame (102).
4. The hydraulic self-walking mobile power station according to claim 1, wherein the hydraulic driving mechanism (200) comprises a hydraulic motor (201), a connecting body (202) is fixedly connected to the bottom side of the rear end of the power station body (1), the hydraulic motor (201) is installed at the top end of the connecting body (202), a rotating shaft (203) is rotatably connected to the rear end of the connecting body (202), a gear I (204) is sleeved on the rear portion of the rotating shaft (203), a gear II (205) is meshed with the upper side of the gear I (204), the gear II (205) is sleeved on the output end of the hydraulic motor (201), a fixed plate (206) is fixedly connected to the rear end of the mobile frame (2), a toothed plate is arranged on the top end of the fixed plate (206), and the gear I (204) and the toothed plate are meshed with each other.
5. The hydraulic self-walking mobile power station according to claim 1, wherein the protection assembly (300) comprises a plurality of guard rails (301), the guard rails (301) are respectively arranged at the front end and the rear end of the mobile frame (2), a fixing strip (302) is fixedly connected between the top ends of the guard rails (301) on the same side in the left-right direction, a plurality of protection plates (303) are fixedly connected between the guard rails (301) on the same side in the front-rear direction, a chute is formed at one end, close to the power station body (1), of the fixing strip (302) on the rear side, a sliding block (304) is slidably connected to the inner wall of the chute, and one end of the sliding block (304) is fixedly connected with the rear end of the power station body (1) through a connecting rod (305).
6. The hydraulic self-walking mobile power station according to claim 5, wherein the control assembly (400) comprises a control frame (401), the control frame (401) is arranged between the outer sides of the fixing strips (302) at the front side, control boards (402) are slidably connected to the upper and lower sides of the inner rear wall of the control frame (401), operation boards (403) are fixedly connected to the rear ends of the control boards (402), two sliding grooves are formed in the control frame (401) corresponding to the two operation boards (403), the two operation boards (403) extend out to the rear side of the control frame (401) through the corresponding sliding grooves, a double-head electric cylinder (404) is mounted at the rear end of the control frame (401), two output ends of the double-head electric cylinder (404) are fixedly connected with the corresponding operation boards (403), the two control boards (402) are respectively arranged at the upper and lower sides of the fixing strips (302), and buckles are arranged on the top ends of the control frame (401) and are used for fixing charging wires.
7. The hydraulic self-walking mobile power station according to claim 6, wherein the connecting assembly (500) comprises a fixed frame (501), the control frame (401) is fixedly connected between the left and right inner side walls of the fixed frame (501), the front end of the power station body (1) is fixedly connected with a mounting plate (502), and a connecting plate (503) is fixedly connected between the fixed frame (501) and the mounting plate (502).
8. A hydraulic self-walking mobile power station according to claim 3, characterized in that the buffer (700) comprises a damping rod (701), the damping rod (701) is arranged between the sliding plate (103) and the inner side wall of the mounting frame (102), and the outer side of the damping rod (701) is sleeved with a second spring (702).
9. The hydraulic self-walking mobile power station according to claim 5, characterized in that a protective frame (5) is arranged between the guard rails (301) at the rear side, and the protective frame (5) is used for protecting the hydraulic motor (201), the first gear (204) and the second gear (205) fixing plates (206).
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