CN109228799A - Fluid drive-type tire energy recovery assemblies - Google Patents

Abstract

The present invention relates to energy regenerating fields, relate to a kind of fluid drive-type tire energy recovery assemblies, it is circular on its wheel hub to be equipped with multiple energy taking devices, it is intracavitary that the piston of energy taking device is built in cylinder, and piston is connected directly or indirectly to the inner wall of tire, when tire is compressed, the periphery interplanar distance of tire inner wall and wheel hub reduces, tire forces piston in the intracavitary movement of cylinder, the intracavitary fluid of cylinder is pushed by piston and passes through the first check valve incoming fluid driving device, fluid drive apparatus converts mechanical rotation energy for the flowing kinetic energy of fluid under the promotion of fluid, and then complete the conversion recycling of energy.

Description

Fluid drive-type tire energy recovery assemblies

Technical field

The present invention relates to energy regenerating fields, more particularly to a kind of fluid drive-type tire energy recovery assemblies.

Background technique

Automobile is the main vehicles, and Global Auto demand and ownership are huge, and sustainable growth.The traveling of automobile Caused by energy consumption and environmental issue it is increasingly prominent, energy-saving and emission-reduction have become the important directions of development of automobile.And energy regenerating It is one of the important means of current energy-saving and emission-reduction.Automobile tire causes tire because the gravity of bearing automobile generates biggish deformation Larger frictional force is produced between road surface, causes the reactive loss of automobile power larger, and the consumption of the energy is increased from this.That , as can energy caused by the deformation of this tire is recycled, it will the energy consumption for substantially saving automobile reaches To the purpose of energy-saving and emission-reduction.

Summary of the invention

To solve the above-mentioned problems, the object of the present invention is to provide a kind of fluid drive-type tire energy recovery assemblies, with It solves the problems, such as that energy consumed by automobile tyre deformation can not be recycled at present.

Based on this, the present invention provides a kind of fluid drive-type tire energy recovery assemblies, including wheel hub and it is mounted on The tire of the wheel hub excircle further includes fluid drive apparatus and multiple energy taking devices；

The energy taking device includes piston and the cylinder chamber for being actively sheathed on the piston, and the cylinder chamber is fixedly connected on institute Wheel hub is stated, the piston is connected directly or indirectly to the inner wall of the tire；

The input end of the fluid drive apparatus is directly or indirectly connected to the cylinder chamber by the first check valve, described The outlet end of fluid drive apparatus is directly or indirectly connected to the cylinder chamber by second one-way valve.

Preferably, each energy taking device has multiple pistons, the quantity of the cylinder chamber and the number of piston Measure equal, and multiple pistons in each energy taking device are connected.

Preferably, being circumferentially equipped with a circle conducting part on bottom wall in the tire, the piston is direct or indirect Ground is connected on the conducting part.

Preferably, the energy taking device further includes drive rod, one end of the drive rod actively penetrates the cylinder The other end of chamber and the one end for being connected to the piston, the drive rod is connected to the inner wall of the tire.

Preferably, the energy taking device further includes elastic component, one end of the elastic component is connected to the drive rod, The other end is connected to the cylinder chamber, and the elastic force of the elastic component forces the drive rod from the intracavitary stretching of the cylinder.

Preferably, the cylinder chamber is divided into the first cavity and is connected to the of the fluid drive apparatus by the piston Two cavitys, first cavity have air inlet and exhaust outlet, and the air inlet is connected to air collecting chamber by third check valve, institute It states exhaust outlet and the external world is connected to by the 4th check valve, there is filtered clean gas in the air collecting chamber.

Preferably, the air collecting chamber is located in the wheel hub, the end of the air collecting chamber is communicated with towards the wheel hub Installation extreme direction extend blowdown pipe.

Preferably, the hub rotation is connected to vehicle frame, the fluid drive apparatus is located on the vehicle frame.

Preferably, the first-class body cavity of structure in disk form is additionally provided in the wheel hub, the first-class body cavity There is the first through hole that the cylinder chamber is connected to by first check valve, the end of the first-class body cavity is logical on inner sidewall It crosses first fluid slip ring and is connected to the fluid drive apparatus, two slip ring ends of the first fluid slip ring are respectively fixedly connected with In the wheel hub and vehicle frame.

Preferably, the second body cavity of structure in disk form is additionally provided in the wheel hub, the second body cavity There is the second through-hole that the cylinder chamber is connected to by the second one-way valve, the end of the second body cavity is logical on inner sidewall It crosses second fluid slip ring and is connected to the fluid drive apparatus, two slip ring ends of the second fluid slip ring are respectively fixedly connected with In the wheel hub and vehicle frame.

Fluid drive-type tire energy recovery assemblies of the invention, it is circular on wheel hub to be equipped with multiple energy taking devices, it takes Can the piston of device be built in that cylinder is intracavitary, and piston is connected directly or indirectly to the inner wall of tire, when tire is compressed, wheel The periphery interplanar distance of tire inner wall and wheel hub reduces, and tire forces piston in the intracavitary movement of cylinder, and the intracavitary fluid of cylinder is pushed by piston And by the first check valve incoming fluid driving device, fluid drive apparatus turns the flowing kinetic energy of fluid under the promotion of fluid Mechanical rotation energy is turned to, and then completes the conversion recycling of energy, and when tire is uncompressed, the periphery of tire inner wall and wheel hub Interplanar distance is restored, and the fluid of fluid drive apparatus discharge is intracavitary eventually by second one-way valve inflow cylinder, to energy next time Amount recycling.

Detailed description of the invention

Fig. 1 is the external structure schematic side view of the fluid drive-type tire energy recovery assemblies of the embodiment of the present invention；

Fig. 2 is the external structure schematic elevation view of the fluid drive-type tire energy recovery assemblies of the embodiment of the present invention；

Fig. 3 is the radial cross section of the fluid drive-type tire energy recovery assemblies of the embodiment of the present invention；

Fig. 4 is the energy taking device structural schematic diagram of the fluid drive-type tire energy recovery assemblies of the embodiment of the present invention；

Fig. 5 is the axial sectional diagrammatical view illustration of the fluid drive-type tire energy recovery assemblies of the embodiment of the present invention；

Fig. 6 is the conducting part schematic cross-section of the fluid drive-type tire energy recovery assemblies of the embodiment of the present invention；

Fig. 7 is the hub interior structural schematic diagram of the fluid drive-type tire energy recovery assemblies of the embodiment of the present invention；

Fig. 8 is the structural schematic diagram of multiple cylinder chambers of the fluid drive-type tire energy recovery assemblies of the embodiment of the present invention.

Wherein, 1, wheel hub；11, first-class body cavity；111, first through hole；112, first fluid slip ring；12, second fluid Chamber；121, the second through-hole；122, second fluid slip ring；2, tire；21, conducting part；211, small end；212, big end；3, taking can fill It sets；31, piston；32, cylinder chamber；321, the first check valve；322, second one-way valve；33, drive rod；331, connecting plate；34, elastic Part；35, the first cavity；351, air inlet；352, exhaust outlet；353, third check valve；354, the 4th check valve；36, the second chamber Body；4, air collecting chamber；41, blowdown pipe；5, vehicle frame.

Specific embodiment

With reference to the accompanying drawings and examples, specific embodiments of the present invention will be described in further detail.Implement below Example is not intended to limit the scope of the invention for illustrating the present invention.

In conjunction with shown in Fig. 1 to Fig. 5, fluid drive-type tire energy recovery assemblies of the invention are schematically showed, wrap Include wheel hub 1, the tire 2 for being mounted on 1 excircle of wheel hub, fluid drive apparatus (not shown) and multiple energy taking devices 3, wherein Multiple energy taking devices 3 are arranged circumferentially on wheel hub 1.Energy taking device 3 includes drive rod 33, elastic component 34, piston 31 and activity Ground is sheathed on the cylinder chamber 32 of piston 31, and cylinder chamber 32 is fixedly connected on wheel hub 1, and piston 31 is connected directly or indirectly to tire 2 Inner wall.In the present embodiment, cylinder chamber 32 is cylindrical structure, and the axis of cylinder chamber 32 is arranged perpendicular to the axis of wheel hub 1, drive rod 33 one end actively penetrates in cylinder chamber 32 and is connected to one end of piston 31, and the other end of drive rod 33 is connected to tire 2 Inner wall, wherein drive rod 33 is connected on one end of 2 inner wall of tire and is additionally provided with connecting plate 331, such as Fig. 4, the one of connecting plate 331 The inner wall of a side and tire 2 is bonded (i.e. face contact), another side of connecting plate 331 is fixedly connected on the end of drive rod 33 Portion, so that drive rod 33 increases in the contact surface of 2 inner wall of tire.One end of elastic component 34 is connected to drive rod 33, and the other end connects It is connected to cylinder chamber 32, the elastic force of elastic component 34 forces drive rod 33 to stretch out out of cylinder chamber 32, when tire 2 is not compressed by external force, bullet Property part 34 can reset piston 31 and drive rod 33, to energy regenerating next time.In conjunction with Fig. 6 and Fig. 7, fluid drive apparatus Input end is directly or indirectly connected to cylinder chamber 32 by the first check valve 321, and the outlet end of fluid drive apparatus passes through second Check valve 322 is directly or indirectly connected to cylinder chamber 32, and the first check valve 321 can prevent at the input end of fluid drive apparatus For fluid countercurrent current to cylinder chamber 32, second one-way valve 322 can prevent the fluid countercurrent current in cylinder chamber 32 to the outlet end of fluid drive apparatus, The flow direction of fluid is limited with this.

Specifically, as shown in fig. 6, being circumferentially equipped with a circle conducting part 21 on bottom wall in tire 2, piston 31 directly or Ground connection is connected on conducting part 21, and in the present embodiment, one end of drive rod 33 is connected to piston 31, and the other end is connected to conduction In portion 21.From the section of tire 2, the profile of tire 2 is U-shaped structure, and the profile of conducting part 21 is trapezium structure, wherein The big end 212 of the trapezium structure is connected on the bottom wall in tire 2, the small end 211 of the trapezium structure and one end of drive rod 33 Mutually abut.Power when conducting part 21 can not only compress tire 2 is transferred to drive rod 33, also increases to a certain extent The bottom wall thickness of tire 2, so that tire 2 is not easy to be pierced, meanwhile, the conducting part 21 of the trapezoidal structure in section can also inhibit tire 2 deformation (can generally generate such deformation in Ackermann steer angle) in 2 axial direction of tire inhibits the fever of tire 2 with this.

Therefore, it is known that, when tire 2 is compressed by external force, the periphery interplanar distance of 2 inner wall of tire and wheel hub 1 reduces, tire 2 inner walls compressing drive rod 33 simultaneously forces piston 31 to move the fluid in squeeze cylinder chamber 32 in cylinder chamber 32, and piston 31 pushes cylinder chamber By the input end of 321 incoming fluid driving device of the first check valve, fluid drive apparatus moves the fluid of fluid for fluid in 32 It can be converted into mechanical rotation energy, when tire 2 is not affected by external force compression, the fluid of fluid drive apparatus outlet end discharge is eventually It is back in cylinder chamber 32 by second one-way valve 322.In the present embodiment, fluid drive apparatus is hydraulic motor, i.e. fluid is Hydraulic oil, since the compressibility of liquid is lower compared with gas, the power that hydraulic oil can transmit in above-mentioned fluid system is more Greatly.

For high speed carrier or heavy carrier, the decrement of tire 2 or the frequency of compression are higher, therefore energy taking device 3 In the working efficiency of single piston 31 and cylinder chamber 32 can be slightly inadequate, therefore in such carrier, each energy taking device 3 has Multiple pistons 31, as shown in figure 8, certainly, the quantity of cylinder chamber 32 and the quantity of piston 31 are equal, and in each energy taking device 3 Multiple pistons 31 are connected, and specifically, multiple pistons 31 in cylindrical structure in each energy taking device 3 are coaxially disposed, and It shares same drive rod 33 and is connected to 2 inner wall of tire.Due to being equivalent to each 3 single of energy taking device fortune with multiple pistons 31 More fluids can be pumped out when moving identical stroke, to drive fluid drive apparatus to be converted to more mechanical rotation energies.Separately Outside, multiple pistons 31 work at the same time, and the total working area for being equivalent to the piston 31 in each energy taking device 3 increases, therefore each The Fluid pressure that piston 31 is born is lower, in order to avoid 31 stress of piston is excessive and deformation, or fluid is caused to leak.

In conjunction with shown in Fig. 4, Fig. 6 and Fig. 7, cylinder chamber 32 is divided for the first cavity 35 and is connected to fluid drive apparatus by piston 31 The second cavity 36, i.e. filled with working media in the second cavity 36 (working media is hydraulic oil in the present embodiment).First Cavity 35 has air inlet 351 and exhaust outlet 352, and air inlet 351 is connected to air collecting chamber 4, exhaust outlet by third check valve 353 352 are connected to the external world by the 4th check valve 354, wherein third check valve 353 can prevent the back flow of gas in the first cavity 35 To air collecting chamber 4, and the 4th check valve 354 can prevent in extraneous back flow of gas to the first cavity 35.Have in air collecting chamber 4 and passes through The clean gas of filter, when piston 31 pushes fluid to flow to fluid drive apparatus, the volume in the first cavity 35 increases, and second Volume in cavity 36 reduces, the clean gas in the air collecting chamber 4 of the first cavity 35 sucking at this time, in order to avoid mix in the first cavity 35 There is pollutant, leads to the increased friction between piston 31 and cylinder chamber 32.Conversely, the volume in the first cavity 35 reduces, the second chamber Volume in body 36 increases, its internal gas is discharged the first cavity 35 by the 4th check valve 354 at this time.Certainly, air collecting chamber 4 On can be equipped with and be connected to extraneous opening, the filter devices such as filter screen are set in opening, when the volume of the first cavity 35 increases, Negative pressure is generated in air collecting chamber 4 and is open by it and sucks outside air, and outside air is by filter screen filtration at above-mentioned clean gas And it is passed through in the first cavity 35.And in the present embodiment, air collecting chamber 4 is located in wheel hub 1, and the end of air collecting chamber 4 is linked with towards wheel The blowdown pipe 41 that the installation extreme direction of hub 1 extends, on the air filter that the end of blowdown pipe 41 can plug into vehicle body, with Clean gas is supplemented from vehicle body end.

Further, wheel hub 1 is rotationally connected with vehicle frame 5, and fluid drive apparatus is located on vehicle frame 5, by fluid drive apparatus It is placed on vehicle frame 5 and in non-hub 1, the weight of wheel is advantageously reduced, and then reduce the rotary inertia of wheel, so that carrier Driving device (fuel engines or motor etc.) wheel can be driven to higher with same power within the unit time The brake apparatus of speed or carrier earlier can be stopped wheel from high-speed rotation brake with same brake force, to enhance carrier Operability.Moreover, fluid drive apparatus is located on vehicle frame 5, rather than it is located in wheel hub 1, the weight of vehicle frame 5 and wheel can be changed The ratio between amount, and then influence the damping effect (damping device certainly, can be equipped between vehicle frame 5 and wheel at this time) of carrier.According to Kinetic energy conservation law, when the weight of vehicle frame 5 be greater than wheel weight when, wheel by road surface impact and obtain perpendicular to ground Movement velocity A upwardly, after the kinetic energy of wheel is transferred to vehicle frame 5, vehicle frame 5 also obtains the movement speed to face upward perpendicular to ground Spend B because the weight of vehicle frame 5 is greater than the weight of wheel, speed B certainly less than speed A, i.e., vehicle frame 5 perpendicular to ground to On movement velocity be less than analysis of wheel vertical in ground face upward movement velocity, so vehicle frame 5 perpendicular to ground face upward fortune The dynamic movement than wheel more mitigates.It can be seen that the damping performance in damping device is constant and the entirety of wheel and vehicle frame 5 is heavy In the case that amount is constant, the weight of carrier is transferred to vehicle frame 5 by wheel as far as possible, is able to ascend the damping property of carrier Energy.

Referring to figs. 7 and 8, the first-class body cavity 11 of structure in disk form, first-class body cavity 11 are additionally provided in wheel hub 1 Inner sidewall on have the first through hole 111 of cylinder chamber 32 be connected to by the first check valve 321, the end of first-class body cavity 11 is logical Cross first fluid slip ring 112 and be connected to fluid drive apparatus, two slip ring ends of first fluid slip ring 112 be respectively fixedly connected in Wheel hub 1 and vehicle frame 5, first-class body cavity 11 by the fluid that the cylinder chamber 32 of multiple energy taking devices 3 is discharged for collecting and being delivered to stream Body drive.Likewise, being additionally provided with the second body cavity 12 of structure in disk form, the inside of second body cavity 12 in wheel hub 1 There is the second through-hole 121 that cylinder chamber 32 is connected to by second one-way valve 322, the end of second body cavity 12 passes through second on wall Fluid slip ring 122 is connected to fluid drive apparatus, and two slip ring ends of second fluid slip ring 122 are respectively fixedly connected in wheel hub 1 With vehicle frame 5, second body cavity 12 is similar with the effect of first-class body cavity 11.

It is circular on wheel hub 1 to be equipped with multiple take in conclusion fluid drive-type tire energy recovery assemblies of the invention Energy device 3, the piston 31 of energy taking device 3 is built in cylinder chamber 32, and piston 31 is connected directly or indirectly to the interior of tire 2 Wall, when tire 2 is compressed, the periphery interplanar distance of 2 inner wall of tire and wheel hub 1 reduces, and tire 2 forces piston 31 in cylinder chamber 32 It moves, the fluid in cylinder chamber 32 is pushed by piston 31 and by 321 incoming fluid driving device of the first check valve, fluid driving dress It sets and converts mechanical rotation energy for the flowing kinetic energy of fluid under the promotion of fluid, and then complete the conversion recycling of energy, and work as When tire 2 is uncompressed, the periphery interplanar distance of 2 inner wall of tire and wheel hub 1 is restored, and the fluid of fluid drive apparatus discharge finally leads to It crosses second one-way valve 322 to flow into cylinder chamber 32, to energy regenerating next time.

The above is only a preferred embodiment of the present invention, it is noted that for the ordinary skill people of the art For member, without departing from the technical principles of the invention, several improvement and replacement can also be made, these are improved and replacement Also it should be regarded as protection scope of the present invention.

Claims (10)

1. A fluid-driven tire energy recovery assembly, comprising a wheel hub and a tire mounted on the outer circumference of the wheel hub, characterized in that it also includes a fluid driving device and a plurality of energy-receiving devices; The energy obtaining device comprises a piston and a cylinder cavity movably sleeved on the piston, the cylinder cavity is fixedly connected to the wheel hub, and the piston is directly or indirectly connected to the inner wall of the tire; The inlet end of the fluid driving device is directly or indirectly communicated with the cylinder chamber through a first check valve, and the outlet end of the fluid driving device is directly or indirectly communicated with the cylinder chamber through a second check valve. 2 . The fluid-driven tire energy recovery assembly according to claim 1 , wherein each of the energy-receiving devices has a plurality of the pistons, the number of the cylinder chambers is equal to the number of the pistons, and each A plurality of the pistons in the energy taking device are connected. 3 . The fluid-driven tire energy recovery assembly according to claim 1 , wherein a ring of conduction parts is arranged on the bottom wall of the tire, and the piston directly or indirectly abuts against the conduction part. 4 . Ministry. 4 . The fluid-driven tire energy recovery assembly according to claim 1 , wherein the energy obtaining device further comprises a transmission rod, one end of the transmission rod movably penetrates the cylinder cavity and is connected to the One end of the piston and the other end of the transmission rod abut against the inner wall of the tire. 5 . The fluid-driven tire energy recovery assembly according to claim 4 , wherein the energy obtaining device further comprises an elastic member, one end of the elastic member is connected to the transmission rod, and the other end is connected to the A cylinder cavity, and the elastic force of the elastic member forces the transmission rod to protrude from the cylinder cavity. 6 . The fluid-driven tire energy recovery assembly of claim 1 , wherein the piston divides the cylinder cavity into a first cavity and a second cavity connected to the fluid driving device, so the The first cavity has an air inlet and an exhaust port, the air inlet is communicated with the air collecting chamber through a third one-way valve, the exhaust port is communicated with the outside through a fourth one-way valve, and the air collecting The chamber has filtered clean gas. 7 . The fluid-driven tire energy recovery assembly of claim 6 , wherein the air collection cavity is located in the wheel hub, and an end of the air collection cavity communicates with a mounting end direction toward the wheel hub. 8 . Extended air supply tube. 8 . The fluid-driven tire energy recovery assembly of claim 1 , wherein the wheel hub is rotatably connected to a frame, and the fluid-driven device is located on the frame. 9 . 9 . The fluid-driven tire energy recovery assembly according to claim 8 , wherein the wheel hub is further provided with a first fluid cavity in a disc-shaped structure, and an inner side wall of the first fluid cavity has a passage through the wheel. 10 . The first one-way valve is communicated with the first through hole of the cylinder cavity, the end of the first fluid cavity is communicated with the fluid driving device through a first fluid slip ring, and the two The ends of the slip ring are respectively fixedly connected to the wheel hub and the frame. 10 . The fluid-driven tire energy recovery assembly according to claim 8 , wherein the wheel hub is further provided with a second fluid cavity in a disc-shaped structure, and the inner sidewall of the second fluid cavity has a The second through hole of the cylinder cavity is communicated with the second one-way valve, and the end of the second fluid cavity is communicated with the fluid driving device through a second fluid slip ring. The second fluid slip ring The two ends of the slip ring are respectively fixedly connected to the wheel hub and the frame.