CN115149622A - Mobile supply vehicle for airport energy storage power supply - Google Patents

Abstract

The invention relates to the technical field of energy storage power supply transport vehicles, and discloses a mobile supply vehicle for an airport energy storage power supply, which comprises a supply frame body, wherein four U-shaped blocks are arranged at the bottom of the supply frame body, first rotating holes are formed in the U-shaped blocks, rotating shafts are arranged in the first rotating holes through first bearings, rollers are fixedly sleeved on the rotating shafts, first fixing plates are arranged in the supply frame body, the energy storage power supply is placed on the first fixing plates, when the energy storage power supply on a luggage van is in a power failure and needs to be replaced, the supply frame body can move through the rollers on the U-shaped blocks due to the fact that the rollers can roll under the rotating action of the first bearings through the rotating shafts, and the energy storage power supply placed in the supply frame body can be driven to be stably transported after being fixed through the first fixing plates, so that the supply vehicle can supply the energy storage power supply to the luggage van conveniently.

Description

Mobile supply vehicle for airport energy storage power supply

Technical Field

The invention relates to the technical field of energy storage power supply transport vehicles, in particular to a mobile supply vehicle for an airport energy storage power supply.

Background

Along with the development of the times, the requirement of various industries on the intelligent degree is improved, more and more mobile machines are popularized, compared with the traditional following equipment, the logistics luggage van has better mobility, safety and practicability, nowadays, along with the increase of national economy of China, the civil aviation industry is rapidly developed, an airplane gradually becomes a common choice for people to travel outside due to the characteristics of high efficiency, comfort and the like, the modern airport has a large scale, people need to carry luggage for a long time and a long distance to handle various riding procedures when riding the airplane, and meanwhile, in order to prevent the luggage from being lost, time and energy are needed to be spent on watching the luggage, so that the fatigue of passengers is greatly increased, the traveling quality of the people is influenced, the logistics luggage van device of the airport is an important component of airport service, the luggage needs to be consigned, and the passengers need to carry the luggage in the traveling process for a long distance, so that the luggage carrier device of the passengers is a service device for conveniently carrying the luggage in the airport range, and the experience of the luggage is improved, and the luggage carrier needs to carry the energy storage vehicle for a long time during the use in the airport for replacing the airport.

The existing energy storage power supply device is mainly characterized in that a fixing frame is arranged in an airport, a plurality of energy storage power supplies are placed on the fixing frame, when the energy storage power supply of the luggage van is powered off, the energy storage power supply on the luggage van needs to be manually disassembled for replacement, and because the energy storage power supply device is mostly fixed, when the energy storage power supply is replaced, a worker is required to carry out remote carrying on the energy storage power supply, the transportation is inconvenient, and the labor intensity is high.

Disclosure of Invention

The invention aims to provide a mobile supply vehicle for an airport energy storage power supply, which solves the problems in the background technology.

In order to solve the technical problems, the invention provides the following technical scheme: the utility model provides a remove supply car for airport energy storage power, this remove supply car for airport energy storage power includes the supply framework, U type piece is installed to the bottom of supply framework, first commentaries on classics hole has been seted up on the U type piece, install the pivot through first bearing in the first commentaries on classics hole, fixed cover is equipped with the gyro wheel in the pivot, forms the supply car under the cooperation through gyro wheel and supply framework, it utilizes the subassembly to be provided with the one-level in the supply framework, the one-level utilizes the subassembly to cooperate with the pivot, through the rotation of pivot utilizes the subassembly to provide the operation drive power for the one-level, install first fixed plate in the supply framework, energy storage power has been placed on the first fixed plate, when energy storage power on the luggage van does not have the electricity and needs to change, because the gyro wheel can roll under the rotation effect of first bearing through the pivot, the supply framework can remove through the gyro wheel on the U type piece to after fixing energy storage power through first fixed plate, thereby can let the supply framework drive the energy storage power of inside and carry out steady transportation, be convenient for the supply car carries out the supply of energy storage power supply to luggage van.

The first-level utilization assembly comprises a second fixing plate, a fixing rod, an extrusion plate, a sliding hole, a limiting block, an extrusion air bag, a linkage rod, a crankshaft and a transmission rod;

the utility model discloses a pneumatic air bag extrusion device, including supply framework, stopper, stripper plate, linkage rod, pivot, transmission rod, dead lever, second fixed plate, stopper, link, linkage rod, drive rod, link rod, linkage rod, drive rod, linkage rod, the second fixed plate is installed to the bottom of supply framework, the bilateral symmetry fixed mounting of second fixed plate has the dead lever, install the stripper plate on the dead lever, the last slide opening of having seted up of stripper plate, the dead lever runs through the slide opening, and is sliding fit, the dead lever is kept away from the tip of second fixed plate and is installed the stopper, the stripper plate is connected through the extrusion gasbag with the second fixed plate, one side fixed mounting that the extrusion gasbag was kept away from to the stripper plate has the linkage rod, two of homonymy the pivot is connected through the crankshaft, install the transmission rod on the crankshaft, the transmission rod is articulated with the tip that the stripper plate was kept away from to the linkage rod, and when the supply framework removes through the gyro wheel, the pivot can drive the crankshaft through the pivot in the rotation, and carry out-step reciprocating motion, the crankshaft can make the stripper plate stretch the extrusion gasbag inhale external gas, when the linkage rod resets, the cooperation of second fixed plate can compress the extrusion gasbag, and provide drive power for the second stage extrusion subassembly.

As a preferable technical scheme, a second rotating hole is formed in the transmission rod, a second bearing is installed in the second rotating hole, the crankshaft penetrates through the second bearing, the crankshaft is convenient to drive the transmission rod to transversely reciprocate in the rotating process, the crankshafts are 'n' -shaped shafts, the two crankshafts are parallel, the protruding portions of the two crankshafts are opposite, when the supply frame body moves, the rollers at the bottom rotate in the same direction, and at the moment, the two crankshafts are parallel and the protruding portions are opposite, so that the extrusion air bag can be driven by air flow provided by the secondary utilization assembly to be stable in the moving process, and the change of the flow speed of air flow output cannot occur.

According to a preferable technical scheme, a secondary utilization assembly and a tertiary utilization assembly are arranged on the supply frame body, the primary utilization assembly, the secondary utilization assembly and the tertiary utilization assembly are matched, and the primary utilization assembly provides operation driving force for the secondary utilization assembly and the tertiary utilization assembly.

As a preferred technical scheme, the secondary utilization assembly comprises a first pressurizing air bag, a perforation, a connecting pipe, a first chute, a first sliding block and a supporting rod;

the utility model discloses a support structure of energy storage power supply, including first fixed plate, supply framework, extrusion gasbag, first slider, bracing piece, connecting pipe, connecting rod, two first spouts, two first sliders are slidably mounted in the first spout, first slider is connected through the bracing piece with first fixed plate, the bracing piece is articulated with first slider and first fixed plate, two the contained angle that the bracing piece formed is the obtuse angle, and when first pressure boost gasbag takes place the volume inflation, two the contained angle of bracing piece reduces, and when the extrusion gasbag receives the compression, the inspiratory air current in the extrusion gasbag can enter into first pressure boost gasbag through the connecting pipe, and at this moment, along with in a large amount of air current gushes into first pressure boost gasbag, first pressure boost gasbag takes place the volume and upwards expands to can jack first fixed plate, utilize the subassembly to form the tight cooperation to the clamp of energy storage power supply with the tertiary, ensure the stability of energy storage power supply in the transportation, and when first fixed plate is jacked, can stimulate the first slider in the first pressure boost gasbag through the bracing piece, be the outer balanced form the buffering space of first pressure boost gasbag, make the first spout of the both sides of first pressure boost gasbag, the buffering form the effect when this moment, the buffering gasbag, make the both sides of first fixed plate, the buffering form the buffering effect of the buffering gasbag, the buffering of the buffering.

As a preferred technical scheme, the secondary utilization assembly further comprises a cavity, a through hole, an air pipe, a one-way pressure valve, a guide plate, a fixing hole, a one-way valve and an air outlet;

the first fixing plate is internally provided with a cavity, the bottom of the cavity is provided with a through hole, the through hole is positioned at the middle position of the bottom of the cavity, the output end of the first pressurizing air bag is connected with an air pipe, the air pipe is connected with the through hole, the through hole is provided with a one-way pressure valve, when the maximum air pressure in the first pressurizing air bag can be reached through the one-way pressure valve, the maximum air pressure of the first pressurizing air bag is maintained, meanwhile, the redundant internal air flow is conveyed, the top of the cavity is provided with a guide plate, the guide plate is a triangular plate and can cut the air flow jetted by the one-way pressure valve and shunt towards two sides, the guide plate is positioned right above the through hole, the top of the cavity is provided with a fixing hole, and the lower port of the fixing hole is provided with the one-way valve, the energy storage power supply contacts with the port on the fixed orifices, the venthole has been seted up to the both sides that the guide plate was kept away from to the cavity, when atmospheric pressure in first pressure boost gasbag reached the maximum value and continuously gushed the air current, unnecessary air current can enter into the check pressure valve through the trachea, be sprayed in the cavity, after the cutting reposition of redundant personnel of guide plate, can be in the cavity towards both sides venthole fast flow, make the air current provide the operation drive power for tertiary utilization subassembly, and, when the air current flows fast in the cavity, according to the venturi principle, restriction through the check valve, make the fixed orifices can form suction, from adsorbing the energy storage power supply on can the first fixed plate, reach fixed effect, make first fixed plate and energy storage power supply form wholly, improve the shock attenuation effect to energy storage power supply.

As a preferred technical scheme, the three-level utilization assembly comprises a second sliding groove, a second sliding block, a connecting spring, a linkage plate, a second pressurizing air bag and an air conveying pipe;

the energy storage power supply comprises a supply frame body, a first sliding groove and a second sliding groove, wherein the upper portion of the inner side of the supply frame body is provided with a first sliding groove, the upper portion of the inner side of the supply frame body is provided with a first sliding block, the upper portion of the inner side of the supply frame body is provided with a second sliding block, the front sliding groove and the rear sliding groove are symmetrically provided with a second sliding groove, the back surfaces of the two second sliding blocks are connected with the groove wall of the second sliding groove through a connecting spring, the front sliding block and the rear sliding block are positioned at the same side and are connected through a linkage plate, the linkage plate is connected with the upper portion of the inner side of the supply frame body in a sliding mode, the input end of the second pressurizing air bag is connected with an air outlet, when air in a cavity flows out through the air outlet, the flowing air can enter the second pressurizing air bag through the air pipe, so that the second pressurizing air bag generates volume transverse expansion, the second sliding block can push the linkage plate to move transversely in the volume expansion process, so that the connecting spring stretches to move transversely in the second sliding groove, and when the two linkage plates are contacted, the second pressurizing air bag and the first fixing plate can clamp the energy storage power supply tightly to achieve the secondary fixing effect, and improve the stability of the energy storage power supply in the transportation process.

As a preferred technical scheme, a pressure release valve is arranged at the output end of the second pressurizing air bag, and the air flow entering continuously can be discharged when the second pressurizing air bag reaches the maximum air pressure through the pressure release valve, so that the service life of the second pressurizing air bag is guaranteed.

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

when the energy storage power supply on the luggage van does not have the electricity and needs to be changed, because the gyro wheel can roll under the rotation effect of first bearing through the pivot, the supply framework can remove through the gyro wheel on the U type piece to fix the back to the energy storage power supply through first fixed plate, thereby can let the supply framework drive the inside energy storage power supply of placing and carry out steady transportation, be convenient for supply the supply of car to luggage van and carry out the supply of energy storage power supply.

When the supply framework moves through the roller, the roller can drive the crankshaft to synchronously rotate through the rotating shaft in the rotating process, the crankshaft can drive the linkage rod to transversely reciprocate through the transmission rod in the rotation process, the sliding hole in the extrusion plate is in sliding fit with the fixed rod, so that the linkage rod can drive the extrusion plate to transversely reciprocate in the moving process, when the linkage rod moves outwards, the extrusion plate can stretch to extrude the air bag to suck external gas, when the linkage rod resets, the extrusion plate can compress the extrusion air bag under the matching of the second fixed plate, and the extrusion air bag is repeatedly compressed to provide operation driving force for the secondary utilization assembly.

When the extrusion gasbag received the compression, inspiratory air current can enter into first pressure boost gasbag through the connecting pipe in the extrusion gasbag, at this moment, along with in a large amount of air currents gush into first pressure boost gasbag, the volume upwards inflation takes place for first pressure boost gasbag, thereby can the first fixed plate of jacking, utilize the subassembly to form the tight cooperation of clamp to energy storage power with the tertiary, ensure energy storage power source's stability in the transportation, and, when first fixed plate is by the jacking, can stimulate the first slider in the first spout through the bracing piece, the bracing piece that makes both sides is outer "eight" form, at this moment, under the cooperation of first pressure boost gasbag, when making the balance of bracing piece and first pressure boost gasbag guarantee first fixed plate, can form the buffer space, play absorbing effect.

When atmospheric pressure in the first pressure boost gasbag reaches the maximum value and lasts to gush into the air current, unnecessary air current can enter into the one-way pressure valve through the trachea, be sprayed in the cavity, after the cutting reposition of redundant personnel of guide plate, can be in the cavity to both sides venthole fast flow, make the air current provide the operation drive power for tertiary utilization subassembly, and, when the air current is fast flow in the cavity, according to the venturi principle, restriction through the one-way valve, make the fixed orifices can form suction, adsorb from the energy storage power supply that can be to on the first fixed plate, reach fixed effect, make first fixed plate and energy storage power supply form wholly, improve the shock attenuation effect to energy storage power supply.

When the air current in the cavity flows out through the venthole, the air current that flows out can enter into in the second pressure boost gasbag through the gas-supply pipe, make the second pressure boost gasbag take place the volume lateral expansion, because the second slider can carry out lateral sliding in the second spout, the second pressure boost gasbag can promote the linkage board at the volume inflation in-process and carry out lateral shifting, make second slider tensile coupling spring sideslip in the second spout, when two linkage boards contact, at this moment, the second pressure boost gasbag of inflation can form to press from both sides tightly fixedly with first fixed plate to the energy storage power, reach the fixed effect of secondary to the energy storage power, improve the stability of energy storage power in the transportation.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

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

FIG. 2 is a first cutaway schematic view of the present invention;

FIG. 3 is a second cutaway configuration of the present invention;

FIG. 4 is a third cutaway schematic view of the present invention;

FIG. 5 is an enlarged schematic view of FIG. 4 at a;

FIG. 6 is an enlarged schematic view of FIG. 4 at b;

fig. 7 is an enlarged schematic view of the structure at c of fig. 2.

In the figure: 1. a supply frame; 2. a U-shaped block; 3. a first rotary hole; 4. a first bearing; 5. a rotating shaft; 6. a roller; 7. a first fixing plate; 8. an energy storage power supply;

9. a primary utilization assembly; 901. a second fixing plate; 902. a fixing rod; 903. a pressing plate; 904. a slide hole; 905. a limiting block; 906. extruding the air bag; 907. a linkage rod; 908. a crankshaft; 909. a transmission rod; 910. a second rotary hole; 911. a second bearing;

10. a secondary utilization component; 1001. a first pressurizing airbag; 1002. perforating; 1003. a connecting pipe; 1004. a first chute; 1005. a first slider; 1006. a support bar; 1007. a chamber; 1008. a through hole; 1009. an air tube; 1010. a one-way pressure valve; 1011. a baffle; 1012. a fixing hole; 1013. a one-way valve; 1014. an air outlet;

11. a tertiary utilization assembly; 1101. a second chute; 1102. a second slider; 1103. a connecting spring; 1104. a linkage plate; 1105. a second pressurized air bag; 1106. a gas delivery pipe; 1107. and (4) releasing the valve.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be obtained by a person skilled in the art without making any creative effort based on the embodiments in the present invention, belong to the protection scope of the present invention.

The embodiment is as follows: as shown in fig. 1 to 7, the present invention provides the following technical solutions: the utility model provides a remove supply vehicle for airport energy storage power, this remove supply vehicle for airport energy storage power includes supply framework 1, four U type pieces 2 are installed to the bottom of supply framework 1, first trompil 3 has been seted up on U type piece 2, install pivot 5 through first bearing 4 in the first trompil 3, fixed cover is equipped with gyro wheel 6 on the pivot 5, form the supply vehicle under the cooperation through gyro wheel 6 and supply framework 1, it utilizes subassembly 9 to be provided with the one-level on the supply framework 1, the one-level utilizes subassembly 9 and pivot 5 to cooperate, through the rotation of pivot 5 utilizes subassembly 9 to provide the running drive power for the one-level, install first fixed plate 7 in the supply framework 1, energy storage power 8 has been placed on the first fixed plate 7, when energy storage power 8 on the luggage van does not have the electricity and needs to change, because gyro wheel 6 can roll under the rotation effect of first bearing 4 through pivot 5, supply framework 1 can move through gyro wheel 6 on U type piece 2 to after energy storage power 8 fixes through first fixed plate 7, thereby can let supply framework 1 inside place the energy storage power and drive the supply vehicle supply 8 of transportation, the energy storage vehicle is convenient to supply.

As shown in fig. 1 to fig. 5, the primary utilization assembly 9 includes a second fixing plate 901, a fixing rod 902, a pressing plate 903, a sliding hole 904, a limiting block 905, a pressing air bag 906, a linkage rod 907, a crankshaft 908 and a transmission rod 909;

the bottom of the supply frame body 1 is provided with a second fixing plate 901, fixing rods 902 are symmetrically and fixedly installed on two sides of the second fixing plate 901, a squeezing plate 903 is installed on the fixing rods 902, a sliding hole 904 is formed in the squeezing plate 903, the fixing rods 902 penetrate through the sliding hole 904 and are in sliding fit, a limiting block 905 is installed at the end, far away from the second fixing plate 901, of each fixing rod 902, the squeezing plate 903 is connected with the second fixing plate 901 through a squeezing air bag 906, one side, far away from the squeezing air bag 906, of the squeezing plate 903 is fixedly provided with a linkage rod 907, the two rotating shafts 5 on the same side are connected through a crankshaft 908, a transmission rod 909 is installed on the crankshaft 908, the transmission rod 909 is hinged to the end, far away from the squeezing plate 903, of the linkage rod 907, when the supply frame body 1 moves through a roller 6, the roller 6 can drive the crankshaft 908 to synchronously rotate through the rotating shaft 5, the crankshaft 908 can drive the linkage rod 907 to transversely reciprocate in the rotation through the linkage rod 909, and the sliding fit is achieved through the sliding hole 904 and the fixing rods 902 on the squeezing plate 903, so that the linkage rod 903 can drive the squeezing plate 903 to transversely move transversely through the linkage rod 903 in a reciprocating motion, when the air bag 903, the air bag 906, the linkage rod 903 is compressed, the squeezing plate 906, and the air bag is compressed by the air bag 906, the air bag 903, and the linkage rod 903 is compressed by the second fixing rod 903, and the air bag 906, when the squeezing plate 903 is compressed by the air bag 906, the pressing plate 903 is compressed by the air bag 906, the air bag 903 is compressed by the air bag 906, and the air bag is compressed by the air bag.

The driving rod 909 is provided with a second rotating hole 910, a second bearing 911 is installed in the second rotating hole 910, the crankshaft 908 penetrates through the second bearing 911, the crankshaft 908 is a 'n' -shaped shaft, the two crankshafts 908 are parallel, the protruding parts of the two crankshafts 908 are opposite, when the supply frame 1 moves, the rollers 6 at the bottom rotate in the same direction, at the moment, the extrusion airbag 906 can be driven by the airflow provided by the secondary utilization assembly 10 to keep stable in the moving process through the parallel arrangement of the two crankshafts 908 and the opposite protruding parts, and the change of the flow rate of the airflow output cannot occur.

The supply frame body 1 is provided with a secondary utilization assembly 10 and a tertiary utilization assembly 11, the primary utilization assembly 9, the secondary utilization assembly 10 and the tertiary utilization assembly 11 are matched, and the primary utilization assembly 9 provides operation driving force for the secondary utilization assembly 10 and the tertiary utilization assembly 11.

The secondary utilization assembly 10 as shown includes a first pressurizing bladder 1001, a perforation 1002, a connecting tube 1003, a first chute 1004, a first slider 1005, and a support rod 1006;

3-4, the first fixing plate 7 is connected to the bottom of the inner side of the supply frame 1 through a first pressurizing airbag 1001, a through hole 1002 is formed in the bottom of the supply frame 1, the extruding airbag 906 is connected to the first pressurizing airbag 1001 through a connecting pipe 1003, the connecting pipe 1003 penetrates through the through hole 1002, two first sliding grooves 1004 are symmetrically formed in the front and back of the bottom of the inner side of the supply frame 1, two first sliding blocks 1005 are slidably mounted in the first sliding grooves 1004, the first sliding blocks 1005 are connected to the first fixing plate 7 through supporting rods 1006, the supporting rods 1006 are hinged to the first sliding blocks 1005 and the first fixing plate 7, an included angle formed by the two supporting rods 1006 is an obtuse angle, when the first pressurizing airbag 1001 expands in volume, the included angle of the two supporting rods 1006 is reduced, when the extruding airbag 906 is compressed, airflow sucked into the first pressurizing airbag 1001 through the connecting pipe 1003 can flow into the first pressurizing airbag 1001, at this time, the airflow rushes into the first pressurizing airbag 1001, the first pressurizing airbag 1001 expands in volume, so that the first fixing plate 7 can be lifted to form a power supply module 11 to clamp the power supply 8, and the energy storage airbag 1001, when the first fixing plate 1006 is lifted, the first pressurizing airbag is lifted, the supporting rods 1006 and the energy storage airbag is lifted up, the first fixing plate 1001, the first pressurizing airbag 1001 can be stably transported, and the supporting rods 1006 can be stably lifted up to the first pressurizing airbag 1001, and the energy storage airbag 1001, and the supporting rods 1006, and the energy storage airbag 1001, when the first fixing plate 1006 can be stably transported, and the energy storage airbag 1001, the first fixing plate 1006 can be stably lifted energy storage airbag 1001, and the supporting rods are stably transported, and the energy storage airbag 1001 can be stably transported, and the supporting rods 1006 can be stably transported in the energy storage airbag 1001.

As shown in fig. 4 and 6, the secondary utilization assembly 10 further comprises a chamber 1007, a through hole 1008, an air pipe 1009, a one-way pressure valve 1010, a guide plate 1011, a fixing hole 1012, a one-way valve 1013, and an air outlet 1014;

a cavity 1007 is arranged in the first fixing plate 7, a through hole 1008 is arranged at the bottom of the cavity 1007, the through hole 1008 is located at the middle position of the bottom of the chamber 1007, the output end of the first pressurizing air bag 1001 is connected with an air pipe 1009, the air pipe 1009 is connected with the through hole 1008, a one-way pressure valve 1010 is arranged on the through hole 1008, when the maximum air pressure can be reached within the first pressurized air bladder 1001 by means of the one-way pressure valve 1010, the excess internal airflow is delivered while maintaining the maximum pressure of the first pressurizing airbag 1001, a guide plate 1011 is installed on the top of the chamber 1007, the guide plate 1011 is a triangular plate and can cut the air flow ejected by the one-way pressure valve 1010, and the flow is divided towards two sides, the guide plate 1011 is positioned right above the through hole 1008, the top of the chamber 1007 is provided with a fixed hole 1012, a one-way valve 1013 is installed on the lower port of the fixing hole 1012, the stored energy power supply 8 is in contact with the upper port of the fixing hole 1012, the two sides of the chamber 1007 far away from the guide plate 1011 are provided with air outlet holes 1014, when the air pressure in the first pressurized bladder 1001 reaches a maximum and continues to rush into the air flow, the excess air flow can pass through the air tube 1009 into the one-way pressure valve 1010, is sprayed into the chamber 1007, and after being cut and divided by the guide plate 1011, can rapidly flow towards the air outlet 1014 at two sides in the chamber 1007, such that the airflow provides the operational driving force for the tertiary utilization assembly 11 and, when the airflow rapidly flows within the chamber 1007, according to the venturi principle, through the restriction of check valve 1013 for fixed orifices 1012 can form suction, adsorbs energy storage power supply 8 from can being to on the first fixed plate 7, reaches fixed effect, makes first fixed plate 7 and energy storage power supply 8 form wholly, improves the shock attenuation effect to energy storage power supply 8.

As shown in fig. 1-4 and 7, the tertiary utilization assembly 11 includes a second chute 1101, a second slider 1102, a connecting spring 1103, a linkage plate 1104, a second pressurizing air bag 1105 and an air pipe 1106;

the energy storage fixing plate comprises a supply frame body 1, a first sliding groove 1101 is symmetrically formed in the front and back of the upper portion of the inner side of the supply frame body 1, two first sliding blocks 1102 are arranged in the first sliding groove 1101 in a front-back mode, the back faces of the two first sliding blocks 1102 are connected with the groove wall of the first sliding groove 1101 through a connecting spring 1103, the front sliding block 1102 and the back sliding block 1102 which are located on the same side are connected through a linkage plate 1104, the linkage plate 1104 is connected with the upper portion of the inner side of the supply frame body 1 through a second pressurizing air bag 1105, an air pipe 1106 is connected to the input end of the second pressurizing air bag 1105, the air pipe 1106 is connected with an air outlet 1014, when air flow in a cavity 1007 flows out through the air outlet 1014, the flowing air flow can enter the second pressurizing air bag 1105 through the air pipe 1106 to transversely expand the second pressurizing air bag 1105, the second pressurizing air bag 1105 expands in the volume direction, when the two second sliding blocks 1102 are in the second sliding groove 1101, the second pressurizing air bag 1104 can push the linkage plate 1104 to transversely move, the second pressurizing air bag 1104 can clamp the energy storage fixing plate 8 and can improve the energy storage fixing effect of energy storage fixing plate 8 in the transportation process.

The output end of the second pressurizing air bag 1105 is provided with a pressure release valve 1107, and the air flow entering continuously can be discharged when the second pressurizing air bag 1105 reaches the maximum air pressure through the pressure release valve 1107, so that the service life of the second pressurizing air bag 1105 is ensured.

The working principle of the invention is as follows:

when the energy storage power supply 8 on the luggage van does not have the electricity and needs to be changed, because the gyro wheel 6 can roll under the rotation effect of first bearing 4 through pivot 5, supply framework 1 can remove through gyro wheel 6 on the U type piece 2 to fix the back to energy storage power supply 8 through first fixed plate 7, thereby can let supply framework 1 drive the inside energy storage power supply 8 of placing and steadily transport, be convenient for the supply van to carry out energy storage power supply 8's supply to the luggage van.

When the supply frame body 1 moves through the roller 6, the roller 6 can drive the crankshaft 908 to synchronously rotate through the rotating shaft 5 in the rotating process, the crankshaft 908 can drive the linkage rod 907 to transversely reciprocate through the transmission rod 909 in the rotating process, the linkage rod 907 can drive the extrusion plate 903 to transversely reciprocate in the moving process due to the sliding fit between the sliding hole 904 on the extrusion plate 903 and the fixed rod 902, when the linkage rod 907 moves outwards, the extrusion plate 903 can stretch the extrusion airbag 906 to suck outside air, when the linkage rod 907 resets, the extrusion plate 903 can compress the extrusion airbag 906 under the fit of the second fixed plate 901, and the extrusion airbag 906 is repeatedly compressed to provide operation driving force for the secondary utilization assembly 10.

When extrusion gasbag 906 receives the compression, the air current of inhaling in the extrusion gasbag 906 can enter into first pressure boost gasbag 1001 through connecting pipe 1003, at this moment, in gushing into first pressure boost gasbag 1001 along with a large amount of air currents, first pressure boost gasbag 1001 takes place the volume and upwards expands, thereby can jacking first fixed plate 7, utilize subassembly 11 to form the tight cooperation of clamp to energy storage power supply 8 with the tertiary, guarantee energy storage power supply 8 stability in the transportation, and, when first fixed plate 7 is risen, can stimulate first slider 1005 in first spout 1004 through bracing piece 1006, the bracing piece 1006 that makes both sides is outer "eight" form, at this moment, under the cooperation of first pressure boost gasbag 1001, when making bracing piece 1006 and first pressure boost gasbag 1001 ensure the balance of first fixed plate 7, can form the cushion space, play absorbing effect.

When the atmospheric pressure in first pressure boost gasbag 1001 reaches the maximum value and lasts to gush into the air current, unnecessary air current can enter into check pressure valve 1010 through trachea 1009, be sprayed in the cavity 1007, after the cutting reposition of redundant personnel of guide plate 1011, can flow towards both sides venthole 1014 in the cavity 1007 fast, make the air current for tertiary subassembly 11 provides the operation drive power that utilizes, and, when the air current flows fast in the cavity 1007, according to the venturi principle, through the restriction of check valve 1013, make fixed orifices 1012 can form suction, adsorb from energy storage power supply 8 that can be to on first fixed plate 7, reach fixed effect, make first fixed plate 7 and energy storage power supply 8 form wholly, improve the shock attenuation effect to energy storage power supply 8.

When the air current in the cavity 1007 flows out through the air outlet 1014, the flowing air current can enter the second pressurizing air bag 1105 through the air pipe 1106, so that the second pressurizing air bag 1105 undergoes volume transverse expansion, because the second slider 1102 can transversely slide in the second chute 1101, the second pressurizing air bag 1105 can push the linkage plate 1104 to transversely move in the volume expansion process, so that the second slider 1102 stretches the connecting spring 1103 to transversely move in the second chute 1101, when the two linkage plates 1104 are contacted, at this time, the expanded second pressurizing air bag 1105 and the first fixing plate 7 can form clamping fixation on the energy storage power supply 8, the secondary fixation effect on the energy storage power supply 8 is achieved, and the stability of the energy storage power supply 8 in the transportation process is improved.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (7)

1. A remove supply vehicle for airport energy storage power supply which characterized in that: the mobile supply vehicle for the airport energy storage power supply comprises a supply frame body (1), a U-shaped block (2) is installed at the bottom of the supply frame body (1), a first rotary hole (3) is formed in the U-shaped block (2), a rotary shaft (5) is installed in the first rotary hole (3) through a first bearing (4), a roller (6) is fixedly sleeved on the rotary shaft (5), a primary utilization assembly (9) is arranged on the supply frame body (1), the primary utilization assembly (9) is matched with the rotary shaft (5), the rotary shaft (5) rotates to provide operation driving force for the primary utilization assembly (9), a first fixing plate (7) is installed in the supply frame body (1), and an energy storage power supply (8) is placed on the first fixing plate (7);

the primary utilization assembly (9) comprises a second fixing plate (901), a fixing rod (902), an extrusion plate (903), a sliding hole (904), a limiting block (905), an extrusion air bag (906), a linkage rod (907), a crankshaft (908) and a transmission rod (909);

the bottom of the supply frame body (1) is provided with a second fixing plate (901), fixing rods (902) are symmetrically arranged on two sides of the second fixing plate (901), an extrusion plate (903) is arranged on the fixing rods (902), a sliding hole (904) is formed in the extrusion plate (903), the fixing rods (902) penetrate through the sliding hole (904) and are in sliding fit, a limiting block (905) is arranged at the end, far away from the second fixing plate (901), of the fixing rods (902), the extrusion plate (903) is connected with the second fixing plate (901) through an extrusion air bag (906), a linkage rod (907) is fixedly arranged on one side, far away from the extrusion air bag (906), of the extrusion plate (903), two rotating shafts (5) on the same side are connected through a crankshaft (908), a transmission rod (909) is arranged on the crankshaft (908), and the end, far away from the extrusion plate (903), of the linkage rod (907) is hinged.

2. The mobile supply cart for an airport energy storage power supply of claim 1, further comprising: the transmission rod (909) is provided with a second rotating hole (910), a second bearing (911) is installed in the second rotating hole (910), the crankshaft (908) penetrates through the second bearing (911), the crankshaft (908) is a 'n' -shaped shaft, the two crankshafts (908) are parallel, and the protruding parts of the two crankshafts (908) are opposite.

3. A mobile supply cart for an airport energy storage power supply of claim 2, wherein: supply frame (1) is last to be provided with second grade and to utilize subassembly (10) and tertiary subassembly (11) of utilizing, subassembly (9), second grade utilize subassembly (10) and tertiary subassembly (11) to cooperate, and subassembly (9) are utilized to the one-level to provide the operation drive power for second grade utilizes subassembly (10) and tertiary subassembly (11).

4. A mobile supply cart for energy storage power at airports according to claim 3, characterised in that: the secondary utilization assembly (10) comprises a first pressurization air bag (1001), a through hole (1002), a connecting pipe (1003), a first sliding groove (1004), a first sliding block (1005) and a supporting rod (1006);

the utility model discloses a pressure-boosting air bag, including supply framework (1), first fixed plate (7), perforation (1002) have been seted up to the bottom of supply framework (1), extrusion gasbag (906) are connected through connecting pipe (1003) with first pressure-boosting gasbag (1001), perforation (1002) are run through to connecting pipe (1003), two first spout (1004) have been seted up to the inboard bottom of supply framework (1) front and back symmetry, slidable mounting has two first slider (1005) in first spout (1004), first slider (1005) are connected through bracing piece (1006) with first fixed plate (7), bracing piece (1006) are articulated with first slider (1005) and first fixed plate (7), two the contained angle that bracing piece (1006) formed is the obtuse angle, and when first pressure-boosting gasbag (1001) takes place the volume inflation, the contained angle of two bracing piece (1006) reduces.

5. A mobile supply cart for energy storage power at airports according to claim 4, wherein: the secondary utilization assembly (10) further comprises a chamber (1007), a through hole (1008), an air pipe (1009), a one-way pressure valve (1010), a guide plate (1011), a fixing hole (1012), a one-way valve (1013) and an air outlet (1014);

be equipped with cavity (1007) in first fixed plate (7), through-hole (1008) have been seted up to cavity (1007) bottom, through-hole (1008) are located the bottom intermediate position of cavity (1007), be connected with trachea (1009) on the output of first pressure boost gasbag (1001), trachea (1009) are connected with through-hole (1008), install one-way pressure valve (1010) on through-hole (1008), guide plate (1011) are installed at the chamber top of cavity (1007), guide plate (1011) are located through-hole (1008) directly over, fixed orifices (1012) have been seted up at the top of cavity (1007), install one-way valve (1013) on the lower port of fixed orifices (1012), energy storage power supply (8) contact with fixed orifices (1012) upper port, venthole (1014) have been seted up to the both sides that guide plate (1011) were kept away from to cavity (1007).

6. A mobile supply cart for an airport energy storage power supply of claim 5, wherein: the tertiary utilization assembly (11) comprises a second sliding groove (1101), a second sliding block (1102), a connecting spring (1103), a linkage plate (1104), a second pressurizing air bag (1105) and an air conveying pipe (1106);

the air supply device is characterized in that second sliding grooves (1101) are symmetrically formed in the front and back of the upper portion of the inner side of the supply frame body (1), two second sliding blocks (1102) are arranged in the second sliding grooves (1101) in a sliding mode, the back faces of the two second sliding blocks (1102) are connected with the groove walls of the second sliding grooves (1101) through connecting springs (1103), the front sliding blocks (1102) and the back sliding blocks (1102) which are located on the same side are connected through a linkage plate (1104), the linkage plate (1104) is connected with the upper portion of the inner side of the supply frame body (1) through a second pressurizing air bag (1105), an air pipe (1106) is connected to the input end of the second pressurizing air bag (1105), and the air pipe (1106) is connected with an air outlet (1014).

7. The mobile supply cart for an airport energy storage power supply of claim 6, further comprising: and a pressure release valve (1107) is arranged on the output end of the second pressurization air bag (1105).

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