CN115649035B - Uninterrupted power supply's low pressure power generation car - Google Patents

Abstract

The invention discloses a low-voltage power generation vehicle with uninterrupted power supply, which comprises a power generation vehicle component, wherein the power generation vehicle component comprises a cab, a power generation box and a protective door, one end of the power generation box is connected with a traction end of the cab, a charging operation bin is arranged on the surface of the power generation box, and one end of the protective door is connected with the outer wall of the power generation box; and the cleaning module comprises a winding assembly, a buffer assembly, a cleaning assembly and a reciprocating driving assembly. According to the invention, the cleaning device is arranged, so that the surface of the wire is cleaned when the wire is recovered by the power generation vehicle, and the cleaning device is driven by the reciprocating driving device to clean the wire in an up-and-down motion manner, so that the cleaning effect on the wire is better, the surface of the wire is ensured to be clean, and the power generation vehicle is ensured to be clean in use.

Description

Uninterrupted power supply's low pressure power generation car

Technical Field

The invention relates to the technical field of low-voltage power generation vehicles, in particular to a low-voltage power generation vehicle with uninterrupted power supply.

Background

With the development of economy and the progress of society, the power supply protection work of important activities is more and more. The primary user adopts the power generation car to protect electricity, and is connected after the power failure of the 10kV distribution network line, and the 10kV distribution network line is disconnected after power restoration, namely, the primary power protection is required to cause the power failure of the user twice. In addition, the UPS is required to be used for guaranteeing the power supply in important power-supply-guaranteeing work, and most of the UPS adopts a storage battery for storing energy, so that the energy storage decay is quicker, the service life is shorter, the maintenance cost is high, and the UPS is required to be matched with a power generation vehicle.

When using the low pressure generator car to supply power the guarantee, have following problem, receive operational environment influence, the power supply wire of generator car stretches out longer, in wire recovery process, wire surface adhesion a large amount of dust influence the use cleanness of generator car, and the generator car in-process of supplying power, can't confirm that it is connected with what kind of link, the easy phenomenon that the difficulty of connection influences the power transmission safety that appears in the power supply connection.

Disclosure of Invention

This section is intended to outline some aspects of embodiments of the application and to briefly introduce some preferred embodiments. Some simplifications or omissions may be made in this section as well as in the description of the application and in the title of the application, which may not be used to limit the scope of the application.

The present invention has been made in view of the problems occurring in the prior art.

Therefore, the technical problem to be solved by the invention is that the power supply wire of the power generation car stretches out longer, a large amount of dust adheres to the surface of the wire in the wire recovery process, the use cleaning of the power generation car is affected, in the power supply process of the power generation car, the connection of the power generation car with the connection end cannot be determined, and the connection difficulty of the power supply connection is easy to occur.

In order to solve the technical problems, the invention provides the following technical scheme: the low-voltage power generation vehicle with uninterrupted power supply comprises a power generation vehicle component, wherein the power generation vehicle component comprises a cab, a power generation box and a protective door, one end of the power generation box is connected with a traction end of the cab, a charging operation bin is arranged on the surface of the power generation box, and one end of the protective door is connected with the outer wall of the power generation box; and the cleaning module comprises a winding component, a buffer component, a cleaning component and a reciprocating driving component, wherein the cleaning component is movably connected with the buffer component and the reciprocating driving component respectively, and the buffer component, the cleaning component and the reciprocating driving component are arranged in the winding component.

As a preferable scheme of the uninterruptible power supply low-voltage power generation vehicle, the invention comprises the following steps: the winding assembly comprises a winding bin, a first motor and a winding rod, wherein the winding bin is arranged in a charging operation bin, the first motor is arranged in the winding bin, the output end of the first motor is fixedly connected with the winding rod, one end of the winding rod is movably connected with the inner wall of the winding bin, the outer wall of the winding rod is connected with a receiving reel, and a connecting wire is arranged on the surface of the winding reel.

As a preferable scheme of the uninterruptible power supply low-voltage power generation vehicle, the invention comprises the following steps: the buffer assembly comprises a mounting bin, a buffer spring and a buffer bottom rod, one end of the buffer bottom rod is fixedly connected with the inner wall of the mounting bin, the buffer spring is arranged in the inner cavity of the buffer bottom rod, one end of the buffer spring is fixedly connected with the inner wall of the buffer bottom rod, one end of the buffer spring is connected with a buffer ejector rod, and one end of the buffer ejector rod penetrates through the outer side of the buffer bottom rod.

As a preferable scheme of the uninterruptible power supply low-voltage power generation vehicle, the invention comprises the following steps: the cleaning assembly comprises a cleaning bin, a second motor and a cleaning rod, wherein the outer wall of the cleaning bin is connected with a buffering ejector rod, the second motor is arranged on the inner wall of the cleaning bin, the output end of the second motor is fixedly connected with the cleaning rod, and one end of the cleaning rod is movably connected with the inner wall of the cleaning bin.

As a preferable scheme of the uninterruptible power supply low-voltage power generation vehicle, the invention comprises the following steps: one end of the connecting wire penetrates through the cleaning bin and the winding bin and extends to the outer side of the winding bin, the outer wall of the cleaning rod is connected with cleaning rollers, two groups of cleaning rollers are respectively arranged on two sides of the connecting wire, and the outer wall of the cleaning rollers is connected with bristles.

As a preferable scheme of the uninterruptible power supply low-voltage power generation vehicle, the invention comprises the following steps: the reciprocating driving assembly comprises a reciprocating driving bin, a third motor and a power transmission cross rod, wherein the reciprocating driving bin is arranged on the inner wall of the cleaning bin, the third motor is arranged on the inner wall of the reciprocating driving bin, one end of the power transmission cross rod is connected with the output end of the third motor, and the outer wall of the power transmission cross rod is sunken towards the direction of the inner wall of the reciprocating driving bin to form a curved rod.

As a preferable scheme of the uninterruptible power supply low-voltage power generation vehicle, the invention comprises the following steps: the reciprocating driving assembly further comprises a movable lantern ring, a reciprocating linkage rod and a movable mounting seat, the movable lantern ring is sleeved on the outer wall of the curved rod, one end of the reciprocating linkage rod is movably connected with the movable mounting seat, one end of the movable mounting seat is connected with the cleaning bin, and one end of the reciprocating linkage rod penetrates through the reciprocating driving bin and is fixedly connected with the movable lantern ring.

As a preferable scheme of the uninterruptible power supply low-voltage power generation vehicle, the invention comprises the following steps: and a heat dissipation opening is formed in the outer wall of the winding bin, and a dustproof gauze is arranged in the heat dissipation opening.

As a preferable scheme of the uninterruptible power supply low-voltage power generation vehicle, the invention comprises the following steps: the connecting module comprises a clamping assembly, a hydraulic assembly, a linkage assembly and a turnover fixing assembly, wherein the clamping assembly is communicated with the hydraulic assembly through hydraulic transmission, the hydraulic assembly is communicated with a limiting assembly through a containing assembly, the hydraulic assembly is movably connected with the linkage assembly, and the linkage assembly is movably connected with the turnover fixing assembly.

As a preferable scheme of the uninterruptible power supply low-voltage power generation vehicle, the invention comprises the following steps: the connecting module further comprises a driving assembly, and traction ends of the driving assembly are respectively connected with the two groups of clamping assemblies.

The invention has the beneficial effects that:

According to the invention, the cleaning device is arranged, so that the surface of the wire is cleaned when the wire is recovered by the power generation vehicle, and the cleaning device is driven by the reciprocating driving device to clean the wire in an up-and-down motion manner, so that the cleaning effect on the wire is better, the surface of the wire is ensured to be clean, and the power generation vehicle is ensured to be clean in use.

According to the invention, the connecting end capable of being automatically switched is arranged, so that when the power generation vehicle is connected with the end to be supplied with power for power transmission, the corresponding connecting end can be automatically switched according to the state of the end to be connected, and the electrical connection stability of the power generation vehicle and the end to be connected is ensured.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are needed in the description of the embodiments will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art. Wherein:

Fig. 1 is a block diagram of a power generating vehicle in an embodiment of the invention.

Fig. 2 is a schematic view of a cleaning module according to an embodiment of the invention.

Fig. 3 is a schematic view of a buffer assembly and a cleaning assembly according to an embodiment of the present invention.

Fig. 4 is a schematic structural diagram of a reciprocating driving assembly according to an embodiment of the present invention.

Fig. 5 is a schematic structural diagram of a connection module according to an embodiment of the invention.

Fig. 6 is a schematic structural diagram of a clamping assembly and a flip-over fixing assembly according to an embodiment of the present invention.

Fig. 7 is a schematic structural diagram of a linkage assembly according to an embodiment of the present invention.

Fig. 8 is a schematic view of a hydraulic assembly according to an embodiment of the present invention.

Fig. 9 is a diagram showing the connection structure of the hydraulic assembly and the linkage assembly in the embodiment of the present invention.

Fig. 10 is a schematic structural diagram of a receiving component in an embodiment of the invention.

Fig. 11 is a schematic diagram of power supply in an embodiment of the invention.

Detailed Description

In order that the above-recited objects, features and advantages of the present invention will become more readily apparent, a more particular description of the invention will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, but the present invention may be practiced in other ways other than those described herein, and persons skilled in the art will readily appreciate that the present invention is not limited to the specific embodiments disclosed below.

Further, reference herein to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic can be included in at least one implementation of the invention. The appearances of the phrase "in one embodiment" in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments.

Example 1

Referring to fig. 1 and 2, in a first embodiment of the present invention, a low-voltage electric power generating vehicle with uninterrupted power supply is provided, which includes an electric power generating vehicle assembly 100, the electric power generating vehicle assembly 100 includes a cab 101, an electric power generating box 102 and a protective door 104, one end of the electric power generating box 102 is connected with a traction end of the cab 101, a charging operation cabin 103 is provided on a surface of the electric power generating box 102, and one end of the protective door 104 is connected with an outer wall of the electric power generating box 102.

A charging operation cabin 103 is provided on the surface of the power generation box 102, and is used for installing the cleaning module 200 for charging wires, when power supply operation is required, a user opens the protection door 104, pulls out the wires, and then charging operation can be performed.

The cleaning module 200, the cleaning module 200 includes a winding component 201, a buffer component 202, a cleaning component 203 and a reciprocating driving component 204, the cleaning component 203 is movably connected with the buffer component 202 and the reciprocating driving component 204, and the buffer component 202, the cleaning component 203 and the reciprocating driving component 204 are all arranged in the winding component 201.

After charging is completed, the winding assembly 201 is used for winding the wire, manual winding of a worker is avoided, time and labor are wasted, the cleaning assembly 203 is driven to continuously reciprocate through the starting of the reciprocating driving assembly 204 in the winding process, the cleaning assembly 203 is prevented from being oscillated in the reciprocating process to affect the stable use through the buffering of the buffering assembly 202, the surface of the wire is continuously cleaned through the starting of the cleaning assembly 203, dust on the surface of the wire is effectively removed, and the use cleanliness of the wire is ensured.

Example 2

Referring to fig. 2 to 4, a second embodiment of the present invention is based on the previous embodiment.

The winding assembly 201 comprises a winding bin 201a, a first motor 201b and a winding rod 201c, wherein the winding bin 201a is arranged in the charging operation bin 103, the first motor 201b is arranged in the winding bin 201a, the output end of the first motor 201b is fixedly connected with the winding rod 201c, one end of the winding rod 201c is movably connected with the inner wall of the winding bin 201a, the outer wall of the winding rod 201c is connected with a winding disc 201d, and a connecting wire 201e is arranged on the surface of the winding disc 201 d.

When the power generation vehicle transmits power, the winding rod 201c is driven to rotate by starting the first motor 201b, the winding disc 201d is driven to rotate by rotating the winding rod 201c, the connecting wire 201e is subjected to rope releasing operation by rotating the winding disc 201d, a user can hold the connecting wire 201e and pull the connecting wire out of the inner cavity of the winding bin 201a, and accordingly the connecting wire is connected with equipment to be powered, and power transmission operation is performed.

When the power transmission is completed and rope winding is required, the first motor 201b is used for reversing, the winding rod 201c is driven to rotate, the winding disc 201d is driven to rotate to wind the connecting wire 201e, and winding operation of the connecting wire 201e is completed.

The buffer assembly 202 comprises a mounting bin 202a, a buffer spring 202b and a buffer bottom rod 202c, wherein one end of the buffer bottom rod 202c is fixedly connected with the inner wall of the mounting bin 202a, the buffer spring 202b is arranged in the inner cavity of the buffer bottom rod 202c, one end of the buffer spring 202b is fixedly connected with the inner wall of the buffer bottom rod 202c, one end of the buffer spring 202b is connected with a buffer ejector rod 202d, and one end of the buffer ejector rod 202d penetrates through the outer side of the buffer bottom rod 202 c.

When the cleaning assembly 203 reciprocates, the cleaning bin 203a reciprocates to pull the buffer ejector rod 202d, so that the buffer ejector rod 202d is driven to move up and down, the buffer spring 202b is pulled or compressed through the movement of the buffer ejector rod 202d, and the buffer ejector rod 202d effectively limits the cleaning bin 203a through the arrangement of the buffer spring 202b, so that the cleaning bin 203a is prevented from vibrating in the moving process.

The cleaning assembly 203 comprises a cleaning bin 203a, a second motor 203b and a cleaning rod 203c, wherein the outer wall of the cleaning bin 203a is connected with a buffer ejector rod 202d, the second motor 203b is arranged on the inner wall of the cleaning bin 203a, the output end of the second motor 203b is fixedly connected with the cleaning rod 203c, and one end of the cleaning rod 203c is movably connected with the inner wall of the cleaning bin 203 a.

One end of the connecting wire 201e penetrates through the cleaning bin 203a and the winding bin 201a and extends to the outer side of the winding bin 201a, the outer wall of the cleaning rod 203c is connected with cleaning rollers 203d, two groups of cleaning rollers 203d are respectively arranged on two sides of the connecting wire 201e, and the outer wall of the cleaning rollers 203d is connected with bristles 203e.

The cleaning lever 203c is driven to rotate by the activation of the second motor 203b, the cleaning roller 203d is driven to rotate by the rotation of the cleaning lever 203c, the brush 203e is driven to rotate by the rotation of the cleaning roller 203d, and the connection wire 201e is cleaned by the rotation of the cleaning roller 203d and the brush 203 e.

The reciprocating driving assembly 204 comprises a reciprocating driving bin 204a, a third motor 204b and a power transmission cross rod 204c, wherein the reciprocating driving bin 204a is arranged on the inner wall of the cleaning bin 203a, the third motor 204b is arranged on the inner wall of the reciprocating driving bin 204a, one end of the power transmission cross rod 204c is connected with the output end of the third motor 204b, and the outer wall of the power transmission cross rod 204c is recessed towards the inner wall of the reciprocating driving bin 204a to form a curved rod 204d.

The reciprocating driving assembly 204 further comprises a movable sleeve ring 204e, a reciprocating linkage rod 204f and a movable mounting seat 204g, wherein the movable sleeve ring 204e is sleeved on the outer wall of the curved rod 204d, one end of the reciprocating linkage rod 204f is movably connected with the movable mounting seat 204g, one end of the movable mounting seat 204g is connected with the cleaning bin 203a, and one end of the reciprocating linkage rod 204f penetrates through the reciprocating driving bin 204a and is fixedly connected with the movable sleeve ring 204 e.

The third motor 204b is started to drive the power transmission cross rod 204c to rotate, the crank rod 204d is driven to rotate through the rotation of the power transmission cross rod 204c, the movable sleeve ring 204e is driven to rotate through the rotation of the crank rod 204d, the reciprocating linkage rod 204f is driven to reciprocate through the rotation of the movable sleeve ring 204e, the movable mounting seat 204g is driven to reciprocate through the reciprocating motion of the reciprocating linkage rod 204f, and therefore the cleaning bin 203a is driven to reciprocate.

The outer wall of the winding bin 201a is provided with a heat dissipation port 201f, and a dustproof gauze is arranged in the heat dissipation port 201 f. Through the seting up of thermovent 201f, can effectively realize the heat dissipation in the rolling storehouse 201a, avoid its in the use, pile up more heat unable discharge, ensure the security when equipment uses, through the setting of dustproof gauze, can effectively avoid external dust to get into equipment and influence the use cleanness of equipment.

Example 3

Referring to fig. 5 to 10, a third embodiment of the present invention is based on the above two embodiments.

The embodiment provides a connection module 300, and the connection module 300 includes a clamping assembly 301, a hydraulic assembly 302, a linkage assembly 305 and a turnover fixing assembly 306, wherein the clamping assembly 301 is communicated with the hydraulic assembly 302 through hydraulic transmission, the hydraulic assembly 302 is communicated with a limiting assembly 304 through a containing assembly 303, the hydraulic assembly 302 is movably connected with the linkage assembly 305, and the linkage assembly 305 is movably connected with the turnover fixing assembly 306.

When the power generation car carries out emergent power supply, need adopt the binding clip to be connected with the wiring end of waiting to supply the power transformer, in the connection process, because the wiring end is probably the copper bar, also probably is the copper line, current binding clip can't take into account both, accomplishes the adaptation and connects.

When the device is connected, the two groups of connecting modules 300 move relatively, and the copper bars or copper wires are clamped between the two groups of connecting modules 300.

If the clamped wiring terminal is a copper bar, the clamping assembly 301 will contact the copper bar first, and the mechanical transmission force is output by extruding the copper bar and the clamping assembly 301, so that the hydraulic oil in the clamping assembly 301 is extruded and output, and after the hydraulic oil enters the hydraulic assembly 302, the hydraulic oil is linked with the linkage assembly 305 by the hydraulic transmission force, and finally the power transmission connection end in the overturning fixing assembly 306 is driven to overturn, so that the power transmission connection end of the planar end is contacted with the wiring terminal of the transformer to be supplied.

After the residual hydraulic oil enters the accommodating component 303, the limiting component 304 is extruded by hydraulic pressure, and the output end of the limiting component is embedded with the linkage component 305, so that the state of the clamping component 301 is maintained, and the power transmission connecting end of the plane end of the clamping component is contacted with the wiring end of the transformer to be supplied.

If the clamped terminal is a copper wire, the power transmission connection end of the cambered surface of the clamping assembly 301 is in contact with the terminal of the transformer to be supplied, so that the electrical connection is directly completed, and the contact power transmission is completed.

The clamping assembly 301 comprises a clamping frame 301a, a hydraulic cavity 301e and a mounting cavity 301f, wherein the hydraulic cavity 301e and the mounting cavity 301f are arranged in the clamping frame 301a, an inner cavity of the hydraulic cavity 301e is slidably connected with a first sealing plate 301c, one end of the first sealing plate 301c is connected with a moving rod 301d, one end of the moving rod 301d penetrates through the outer side of the clamping frame 301a, one end of the first sealing plate 301c is connected with a first spring 301b, and one end of the first spring 301b is connected with the inner wall of the clamping frame 301 a.

The diameters of the moving rods 301d in the two groups of clamping assemblies 301 are different, the inner wall of one group of moving rods 301d is provided with a cavity, and the diameter of the cavity is larger than the outer diameter of the other group of moving rods 301 d.

When clamping power transmission is performed on the copper wires, the two groups of clamping assemblies 301 relatively move, the moving rods 301d cannot contact the copper wires, one group of moving rods 301d can move to the inner cavity of the other group of moving rods 301d, and the extrusion power transmission movement of the two groups of clamping assemblies 301 cannot be affected.

When clamping power transmission is conducted on the copper bar, the copper bar is wider, the movable rod 301d contacts the outer wall of the copper bar and is moved by copper bar extrusion, the first sealing plate 301c is driven to move through movement of the movable rod 301d, the first spring 301b is extruded through movement of the first sealing plate 301c to deform, elastic energy storage is conducted through deformation of the first spring 301b, and reset of subsequent equipment is facilitated.

The hydraulic assembly 302 comprises a compression bin 302a, a first connecting pipe 302b, a second sealing plate 302c and a traction rod 302f, one end of the compression bin 302a is arranged on the outer wall of the clamping frame 301a, the outer wall of the second sealing plate 302c is in sliding connection with the inner wall of the clamping frame 301a, one end of the traction rod 302f is fixedly connected with the second sealing plate 302c, one end of the traction rod 302f penetrates through the compression bin 302a and is connected with the transmission rod 302g, and two ends of the first connecting pipe 302b are respectively communicated with the compression bin 302a and the hydraulic cavity 301 e.

The hydraulic oil in the hydraulic cavity 301e is extruded through the movement of the first sealing plate 301c, the hydraulic oil is extruded under pressure, the hydraulic oil enters the compression bin 302a through the first connecting pipe 302b, the pressure in the hydraulic cavity 301e is increased along with the continuous entering of the hydraulic oil, the second sealing plate 302c is extruded to move, the traction rod 302f is driven to move through the movement of the second sealing plate 302c, the transmission rod 302g is driven to move through the movement of the traction rod 302f, the meshing toothed plate 305a is driven to move through the movement of the transmission rod 302g, and meshing transmission operation is performed.

The hydraulic assembly 302 further comprises a second spring 302d and a stop block 302e, the second spring 302d is sleeved on the outer wall of the traction rod 302f, one end of the stop block 302e is fixedly connected with the inner wall of the clamping frame 301a, and a movable through groove M is formed in the outer wall of the clamping frame 301 a.

The second spring 302d is extruded through the movement of the second sealing plate 302c, so that the second spring 302d deforms, the subsequent resetting operation of the equipment is facilitated through deformation energy storage of the second spring 302d, the displacement of the transmission rod 302g can be more conveniently realized through the arrangement of the movable through groove M, and the phenomenon that the normal use of the equipment is influenced by interference is avoided.

When the second seal plate 302c moves to contact the stopper 302e, its displacement reaches a predetermined stroke, and in this state, the engaging tooth plate 305a also moves to reach a predetermined stroke.

The linkage assembly 305 comprises a meshing toothed plate 305a, a movable rod 305b and a driving gear 305c, wherein the outer wall of the meshing toothed plate 305a is fixedly connected with a transmission rod 302g, one end of the movable rod 305b is fixedly connected with the clamping frame 301a, and one end of the movable rod 305b is movably connected with the driving gear 305 c.

The driving gear 305c is driven to rotate by the movement of the meshing toothed plate 305a, and the transmission power is transmitted to the driven gear 306b to rotate by the rotation of the driving gear 305 c.

The overturning fixing assembly 306 comprises a torsion spring 306a, a driven gear 306b, a rotating rod 306c and an arc clamping plate 306d, wherein the torsion spring 306a and the driven gear 306b are arranged on the outer wall of the rotating rod 306c, two ends of the rotating rod 306c are movably connected with the clamping frame 301a, two ends of the torsion spring 306a are respectively connected with the driven gear 306b and the clamping frame 301a, the outer wall of the rotating rod 306c is sequentially connected with a first supporting rod 306e and a second supporting rod 306f, one end of the first supporting rod 306e is connected with the arc clamping plate 306d, and one end of the second supporting rod 306f is connected with a transverse plate 306g.

In the initial state, the arc clamping plate 306d is positioned at one side far away from the clamping frame 301a, and the outer walls of the arc clamping plate 306d and the transverse plate 306g are connected with conductive equipment, so that contact power transmission with the wiring terminal of the transformer to be supplied is realized.

The rotation of the driven gear 306b drives the rotating rod 306c to rotate, and the rotation of the rotating rod 306c enables the arc-shaped clamping plate 306d and the transverse plate 306g to rotate, so that the transverse plate 306g rotates to the side far away from the clamping frame 301a, and contact power transmission with the copper bars is achieved.

By setting the position of the stopper 302e, when the second sealing plate 302c moves to contact the stopper 302e, the displacement reaches a predetermined stroke, and in this state, the movement of the engaging toothed plate 305a also reaches a predetermined stroke, that is, the driven gear 306b rotates one hundred eighty degrees, so that the positions of the arc-shaped clamping plate 306d and the cross plate 306g are exchanged.

The accommodating component 303 is disposed in the mounting cavity 301f, the accommodating component 303 includes an accommodating bin 303a, a second connecting pipe 303b and a pressure release valve 303c, one end of the accommodating bin 303a is fixedly connected with the clamping frame 301a, the pressure release valve 303c is disposed on the outer wall of the second connecting pipe 303b, and two ends of the second connecting pipe 303b are respectively communicated with the accommodating bin 303a and the compression bin 302 a.

In this state, the pressing state of the copper bar against the moving rod 301d is continued, and the second sealing plate 302c is not moved, the oil pressure in the compression chamber 302a is continuously increased, the oil pressure exceeds the predetermined value of the relief valve 303c, and the hydraulic oil enters the housing chamber 303a through the second connection pipe 303 b.

The limiting assembly 304 comprises a circulation bin 304a, a third spring 304b, a third sealing plate 304c and an extension rod 304d, one end of the circulation bin 304a is fixedly connected with the inner wall of the accommodating bin 303a, the outer wall of the third sealing plate 304c is slidably connected with the inner wall of the circulation bin 304a, two ends of the third spring 304b are respectively connected with the third sealing plate 304c and the circulation bin 304a, one end of the extension rod 304d is connected with the third sealing plate 304c, one end of the extension rod 304d penetrates through the accommodating bin 303a and is connected with the positioning toothed plate 304f, and a circulation hole 304e is formed in the outer wall of the circulation bin 304 a.

The circulation bin 304a is communicated with the containing bin 303a through the circulation hole 304e, after the oil pressure is increased, the third sealing plate 304c is moved through the driving of the oil pressure, the third spring 304b is stretched to deform through the movement of the third sealing plate 304c, the subsequent resetting of the equipment is facilitated through the deformation of the third spring 304b, the extension rod 304d is driven to move through the movement of the third sealing plate 304c, the positioning toothed plate 304f is driven to move through the movement of the extension rod 304d, the positioning toothed plate 304f is contacted with the meshing toothed plate 305a, teeth on the surfaces of the positioning toothed plate 304f are mutually locked, the equipment is kept in a stable state, the shaking and skewing phenomenon is avoided when the copper bar is subjected to clamping power transmission, and the stability of electric connection is ensured.

The driving assembly 307 comprises a driving bin 307a and a counter-pulling screw 307b, one end of the counter-pulling screw 307b is movably connected with the inner wall of the driving bin 307a, one end of the counter-pulling screw 307b penetrates through the driving bin 307a and is connected with a driving disc, the outer wall of the counter-pulling screw 307b is in threaded connection with a screw block 307d, one end of the screw block 307d is connected with a guide rod 307e, one end of the guide rod 307e is connected with the clamping frame 301a, one end of a connecting wire 201e is in contact with the outer wall of the driving bin 307a, a connecting terminal is arranged on the back of the driving bin 307a and is electrically connected with the connecting wire 201e, and a connecting terminal branching line is connected with an arc clamping plate 306d and a transverse plate 306g so as to facilitate power transmission after connection of the two terminals with terminals to be powered.

When the connection module 300 is driven to clamp and transmit power, the user rotates the driving disc, the rotation of the driving disc drives the opposite-pulling screw 307b to rotate, the rotation of the opposite-pulling screw 307b drives the two screw blocks 307d on the surface of the opposite-pulling screw 307b to move relatively, the movement of the screw blocks 307d drives the guide rod 307e to move, and the movement of the guide rod 307e drives the two groups of connection modules 300 to move relatively.

The driving assembly 307 further comprises a limiting slide rod 307f and a limiting slide way 307c, wherein the limiting slide way 307c is arranged on the inner wall of the driving bin 307a, one end of the limiting slide rod 307f is in sliding connection with the limiting slide way 307c, and one end of the limiting slide rod 307f is fixedly connected with the screw block 307 d;

The limiting slide rod 307d is driven to slide in the limiting slide way 307c through movement of the screw block 307d, and the phenomenon of offset clamping stagnation of the screw block 307d in the moving process can be effectively avoided through limiting of the limiting slide rod 307d, so that stability of equipment during clamping operation is ensured.

After the driving component 307 drives the clamping component 301 to clamp the copper bars or copper wires, the power transmission operation is performed through the power generation vehicle.

Example 4

Referring to fig. 11, in order to provide a fourth embodiment of the present invention, the embodiment is based on the above three embodiments, and this embodiment provides a method for uninterrupted power supply of a power generating vehicle.

The grid-connected device is connected to the low-voltage side of the user, and the front and rear buses of the main circuit breaker of the low-voltage power distribution cabinet are connected. The connection adopts a confluence clamp, so that the rapid access with points can be realized;

Forward grid connection:

the QF1 user high-voltage load switch and the QF2 user low-voltage main breaker are in a closing state, and the commercial power supplies power to the user load;

QF3 commercial power is input into the breaker to be switched on, and the commercial power forms a bypass. The IG-NT control screen detects the voltage and phase sequence of the mains supply;

And starting the generator car G and closing the QF4 unit circuit breaker (delay closing). The IG-NT control screen detects parameters such as unit voltage, phase sequence, phase angle and the like, and the IG-AVRI module adjusts the unit voltage and frequency (synchronous with the mains supply) and synchronizes the phase angle and then closes the power supply, so that the power supply vehicle and the mains supply are connected in a forward direction;

And after the power supply vehicle is connected with the grid, flexibly loading the load value of the screen base number to a fixed value according to the IG-NT control screen base number. Breaking QF2 user low-voltage main breaker;

Breaking QF3 mains supply input breaker, mains supply power supply stops. The power supply vehicle is automatically converted into an island mode from a grid-connected mode to fully bear the load of a user.

Reverse grid connection:

The mains supply resumes the power supply, and QF3 mains supply input circuit breaker is closed (time-lapse closing). The IG-NT control screen detects parameters such as mains voltage, phase sequence, phase angle and the like, and the IG-AVRI module adjusts the voltage and frequency (synchronous with the mains) of the unit and the synchronous phase angle and then closes the power supply, so that the reverse grid connection of the power supply vehicle and the mains is completed;

The breaker of the split QF4 unit has the advantage of power failure during unit cooling. The user load is supplied with power through a QF3 mains supply input breaker bypass;

and a bypass is released by electrification of a low-voltage main breaker of a switching QF2 user.

It is important to note that the construction and arrangement of the application as shown in the various exemplary embodiments is illustrative only. Although only a few embodiments have been described in detail in this disclosure, those skilled in the art who review this disclosure will readily appreciate that many modifications are possible (e.g., variations in sizes, dimensions, structures, shapes and proportions of the various elements, values of parameters (e.g., temperature, pressure, etc.), mounting arrangements, use of materials, colors, orientations, etc.) without materially departing from the novel teachings and advantages of the subject matter described in this application. For example, elements shown as integrally formed may be constructed of multiple parts or elements, the position of elements may be reversed or otherwise varied, and the nature or number of discrete elements or positions may be altered or varied. Accordingly, all such modifications are intended to be included within the scope of present application. The order or sequence of any process or method steps may be varied or re-sequenced according to alternative embodiments. In the claims, any means-plus-function clause is intended to cover the structures described herein as performing the recited function and not only structural equivalents but also equivalent structures. Other substitutions, modifications, changes and omissions may be made in the design, operating conditions and arrangement of the exemplary embodiments without departing from the scope of the present applications. Therefore, the application is not limited to the specific embodiments, but extends to various modifications that nevertheless fall within the scope of the appended claims.

Furthermore, in an effort to provide a concise description of the exemplary embodiments, all features of an actual implementation may not be described (i.e., those not associated with the best mode presently contemplated for carrying out the invention, or those not associated with practicing the invention).

It should be appreciated that in the development of any such actual implementation, as in any engineering or design project, numerous implementation-specific decisions may be made. Such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking of design, fabrication, and manufacture for those of ordinary skill having the benefit of this disclosure.

It should be noted that the above embodiments are only for illustrating the technical solution of the present invention and not for limiting the same, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the technical solution of the present invention may be modified or substituted without departing from the spirit and scope of the technical solution of the present invention, which is intended to be covered in the scope of the claims of the present invention.

Claims (1)

1. The utility model provides a low pressure power generation car of uninterrupted power supply which characterized in that: comprising the steps of (a) a step of,

The power generation car assembly (100), the power generation car assembly (100) comprises a cab (101), a power generation box (102) and a protective door (104), one end of the power generation box (102) is connected with the traction end of the cab (101), a charging operation bin (103) is arranged on the surface of the power generation box (102), and one end of the protective door (104) is connected with the outer wall of the power generation box (102); and

The cleaning module (200), the cleaning module (200) comprises a winding component (201), a buffer component (202), a cleaning component (203) and a reciprocating driving component (204), the cleaning component (203) is movably connected with the buffer component (202) and the reciprocating driving component (204) respectively, and the buffer component (202), the cleaning component (203) and the reciprocating driving component (204) are arranged in the winding component (201);

The winding assembly (201) comprises a winding bin (201 a), a first motor (201 b) and a winding rod (201 c), wherein the winding bin (201 a) is arranged in a charging operation bin (103), the first motor (201 b) is arranged in the winding bin (201 a), the output end of the first motor (201 b) is fixedly connected with the winding rod (201 c), one end of the winding rod (201 c) is movably connected with the inner wall of the winding bin (201 a), the outer wall of the winding rod (201 c) is connected with a receiving reel (201 d), and a connecting wire (201 e) is arranged on the surface of the winding reel (201 d);

The buffer assembly (202) comprises a mounting bin (202 a), a buffer spring (202 b) and a buffer bottom rod (202 c), one end of the buffer bottom rod (202 c) is fixedly connected with the inner wall of the mounting bin (202 a), the buffer spring (202 b) is arranged in the inner cavity of the buffer bottom rod (202 c), one end of the buffer spring (202 b) is fixedly connected with the inner wall of the buffer bottom rod (202 c), one end of the buffer spring (202 b) is connected with a buffer ejector rod (202 d), and one end of the buffer ejector rod (202 d) penetrates through the outer side of the buffer bottom rod (202 c);

The cleaning assembly (203) comprises a cleaning bin (203 a), a second motor (203 b) and a cleaning rod (203 c), wherein the outer wall of the cleaning bin (203 a) is connected with a buffer ejector rod (202 d), the second motor (203 b) is arranged on the inner wall of the cleaning bin (203 a), the output end of the second motor (203 b) is fixedly connected with the cleaning rod (203 c), and one end of the cleaning rod (203 c) is movably connected with the inner wall of the cleaning bin (203 a);

One end of the connecting wire (201 e) penetrates through the cleaning bin (203 a) and the winding bin (201 a) and extends to the outer side of the winding bin (201 a), the outer wall of the cleaning rod (203 c) is connected with cleaning rollers (203 d), two groups of cleaning rollers (203 d) are respectively arranged on two sides of the connecting wire (201 e), and the outer wall of the cleaning rollers (203 d) is connected with bristles (203 e);

the reciprocating drive assembly (204) comprises a reciprocating drive bin (204 a), a third motor (204 b) and a power transmission cross rod (204 c), wherein the reciprocating drive bin (204 a) is arranged on the inner wall of the cleaning bin (203 a), the third motor (204 b) is arranged on the inner wall of the reciprocating drive bin (204 a), one end of the power transmission cross rod (204 c) is connected with the output end of the third motor (204 b), and the outer wall of the power transmission cross rod (204 c) is recessed towards the inner wall of the reciprocating drive bin (204 a) to form a curved rod (204 d);

The reciprocating driving assembly (204) further comprises a movable sleeve ring (204 e), a reciprocating linkage rod (204 f) and a movable mounting seat (204 g), wherein the movable sleeve ring (204 e) is sleeved on the outer wall of the curved rod (204 d), one end of the reciprocating linkage rod (204 f) is movably connected with the movable mounting seat (204 g), one end of the movable mounting seat (204 g) is connected with the cleaning bin (203 a), and one end of the reciprocating linkage rod (204 f) penetrates through the reciprocating driving bin (204 a) and is fixedly connected with the movable sleeve ring (204 e);

a heat dissipation opening (201 f) is formed in the outer wall of the winding bin (201 a), and a dustproof gauze is arranged in the heat dissipation opening (201 f);

The connecting module (300) comprises a clamping assembly (301), a hydraulic assembly (302), a linkage assembly (305) and a turnover fixing assembly (306), wherein the clamping assembly (301) is communicated with the hydraulic assembly (302) through hydraulic transmission, the hydraulic assembly (302) is communicated with a limiting assembly (304) through a containing assembly (303), the hydraulic assembly (302) is movably connected with the linkage assembly (305), and the linkage assembly (305) is movably connected with the turnover fixing assembly (306);

the connecting module (300) further comprises a driving assembly (307), and traction ends of the driving assembly (307) are respectively connected with the two groups of clamping assemblies (301).