CN114592918A - Rotating wheel capable of realizing radial rotation by means of end face stress - Google Patents

Abstract

A wheel having an end face forced for radial rotation, comprising: the transmission assembly is arranged at the step structure by adopting a lever structure, the transition of a rolling shaft rolling on the large helicoid from the lowest point to the highest point is realized through the transmission assembly, the transition structure is set into a mechanical structure, the structure is simple, the stability is high, the loss energy is lower than that in the prior art during the transition, and the working efficiency is improved.

Description

Rotating wheel capable of realizing radial rotation by means of end face stress

Technical Field

The invention relates to the field of power devices, in particular to a rotating wheel with an end face stressed to realize radial rotation.

Background

The power machine is a machine which converts energy such as heat energy or electric energy into mechanical energy, most of the existing power machines need to consume a large amount of gasoline or diesel oil, such as an internal combustion engine, and part of power can emit a large amount of tail gas to cause air pollution or have lower mechanical efficiency. The existing pneumatic power machine comprises a base, wherein a self-closing switch assembly or a cylinder is arranged on the base, a piston of the cylinder is movably connected with a cam through a connecting rod, a transmission belt pulley is connected onto a convex output shaft, and a high-pressure pipeline is communicated between the front end of the piston of the cylinder and a pneumatic bin of the self-closing switch assembly. The pneumatic power machine comprises: small energy, uniform power transmission part and large motion vibration.

The application number is CN201610166227.2, which discloses a runner with an end face stressed to rotate in a radial direction, comprising a runner body, wherein two end faces of the runner body are respectively provided with at least one first spiral face and at least one second spiral face; and the head-tail combination positions of the first spiral surface and the second spiral surface are respectively provided with a section of transition inclined plane. A pressure power machine comprises a box body, an output shaft and a rotating wheel, wherein the rotating wheel is arranged on the output shaft, and a front end cover and a rear end cover are respectively arranged at two ends of the box body; the inner sides of the front end cover and the rear end cover are respectively provided with a plurality of pressure cylinders, the pressure cylinders and the axis of the output shaft are arranged in an inclined manner, the heads of piston rods of the pressure cylinders on two sides are provided with bearings, and the bearings on two sides are respectively contacted with the first spiral surface and the second spiral surface; the input end of each pressure cylinder is connected with the pressure supply device through the pressure control device and the input pipeline in sequence, and the pressure control device can control the closing/opening of the input pipeline. Pressure is applied to the spiral surface, and the spiral surface converts the pressure into rotating force, so that the rotating wheel is rotated.

Above-mentioned runner is at the course of the work, the piston rod is from the highest position of helicoid to the lowest position after, need just can get back to the highest position through the transition inclined plane and begin the next round of rotation, and current transition structure is transition inclined plane cooperation ejector pad and mechanical control three-way valve, specifically be at the rotatory in-process of runner, push away this mechanical control three-way valve through the ejector pad that sets up at the helicoid lowest position, thereby close compressed gas and get into in the cylinder, then will lose cylinder pressure's piston rod by the transition inclined plane and up push away, thereby realize the transition of lowest position to highest position. This kind of transition structure needs cylinder, mechanical control three-way valve, transition inclined plane and a plurality of structures of ejector pad to mutually support carrying out transition action in-process, and this transition structure is complicated, and has lost too much energy when the transition, has reduced work efficiency.

Disclosure of Invention

The invention aims to provide a runner with an end face stressed to realize radial rotation, which comprises: the transmission assembly is arranged at the step structure by adopting a lever structure, and the transition from the lowest point to the highest point of a rolling shaft rolling on the large helicoid is realized by the transmission assembly.

In one embodiment, the rotating wheel consists of a large spiral surface, a pressure plate and a small spiral surface, wherein the large spiral surface is arranged on one end surface of the pressure plate, and the small spiral surface is arranged on the other end surface of the pressure plate.

In one embodiment, the runner is provided with mounting slots at the step structure for mounting the drive assembly.

In one embodiment, the transmission assembly comprises: the lever is arranged in the rotating wheel, and the pressing block is arranged at the position, close to the stepped structure, of the lever.

In one embodiment, the lever comprises: the rotating end is arranged on the outer surface of the large spiral surface through the rotating support piece, the movable end is arranged on the outer surface of the small spiral surface below the stepped structure, and the pressing block is arranged above the movable end.

In one embodiment, the compact comprises: fixed connection is in the briquetting locating part of mounting groove, sets up the briquetting main part in the briquetting locating part and sets up the slip auxiliary member between briquetting locating part and briquetting main part.

In one embodiment, the rotational support comprises: the reset spring on the rotation support rod is located to rotation support rod and cover, and rotation support rod one end fixed connection is in the runner, and the other end is equipped with the assembly groove, and this assembly groove bilateral symmetry is equipped with the bar hole, and this bar hole is connected with the lever through setting up the pivot.

In one embodiment, a protruding structure is further arranged between two ends of the lever and adjacent to the large spiral surface, and the protruding structure is used as a fulcrum of the lever.

The invention also comprises a rotating method of the rotating wheel, the end surface of which is stressed to realize radial rotation, comprising the following steps:

s1, arranging a plurality of rolling shafts on a large spiral surface and a small spiral surface of a rotating wheel, and applying pressure to the rotating wheel through the rolling shafts;

s2, the large helicoid of the runner starts to rotate after being pressurized until any rolling shaft arranged at one end of the large helicoid performs circular motion along the large helicoid and moves to a step structure;

s3, when S2 happens, the rolling shaft arranged on the small helicoid displaces to the movable end of the lever to provide pressure for the movable end of the lever, so that the pressing block is driven to transition the rolling shaft displaced to the step structure of the large helicoid from the lowest point to the highest point, and the rotating wheel completes one-circle rotation;

and S4, repeating the actions from S2 to S3 to enable the rotating wheel to continuously rotate.

In one embodiment, the rollers of the small helicoids are arranged in pairs at equal intervals, the rollers of the large helicoids are arranged at one time of the rollers of the small helicoids at equal intervals, the positions of the rollers of the large helicoids are fixed, and the rollers at one end of the small helicoids and the rotating wheel do reverse circular motion at the same angular speed.

The rotating wheel with the end face stressed to realize radial rotation is simple in structure and high in stability, the transition structure is a mechanical structure, the loss energy in transition is lower than that in the prior art, and the working efficiency is improved.

Drawings

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

FIG. 1 is an overall block diagram of the rotor of the present invention;

FIG. 2 is an exploded view of the wheel of the present invention;

FIG. 3 is a top view of the wheel of the present invention;

FIG. 4 is a side view of the wheel of the present invention;

FIG. 5 is an exploded view of the lever of the present invention;

FIG. 6 is an exploded view of the compact of the present invention;

FIG. 7 is a schematic view of the construction of the rotating support of the present invention;

FIG. 8 is a schematic view of the lever of the present invention;

FIG. 9 is an overall side view of the present invention;

FIG. 10 is a schematic representation of the operating principle of the transmission assembly of the present invention;

FIG. 11 is an overall structural view of the spiral disk of the present invention;

FIG. 12 is a side view of a spiral disk of the present invention;

FIG. 13 is a cross-sectional view of a lever of the present invention;

FIG. 14 is a schematic view a of the operating principle of the transmission assembly of the present invention;

FIG. 15 is a schematic view b of the operating principle of the transmission assembly of the present invention;

FIG. 16 is a schematic representation c of the operating principle of the transmission assembly of the present invention;

FIG. 17 is a schematic distance diagram of pressure points of the transmission assembly of the present invention.

Detailed Description

It should be noted that all directional indicators (such as upper, lower, left, right, front, rear, inner and outer, and the center … …) in the embodiment of the present invention are only used for explaining the relative position relationship between the components, the movement situation, etc. in a specific posture (as shown in the drawing), and if the specific posture is changed, the directional indicator is changed accordingly.

In the present invention, unless otherwise expressly stated or limited, the terms "connected," "secured," and the like are to be construed broadly, and for example, "secured" may be a fixed connection, a removable connection, or an integral part; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In addition, the technical solutions in the embodiments of the present invention may be combined with each other, but it must be based on the realization of those skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination of technical solutions should not be considered to exist, and is not within the protection scope of the present invention.

With reference to the attached figures 1-4,

a wheel having an end face forced for radial rotation, comprising: the device comprises a rotating wheel 1 and a transmission assembly 11 arranged on the rotating wheel 1, wherein a large spiral surface 15 is arranged on one end surface of the rotating wheel 1, the large spiral surface 15 is arranged in an annular spiral mode from the highest point to the lowest point, a step structure 16 is formed between the highest point and the lowest point, the transmission assembly 11 is arranged at the step structure 16, and the transition from the lowest point to the highest point of a roller rolling on the large spiral surface 15 is realized through the transmission assembly 11.

Preferably, the rotating wheel 1 is composed of a large spiral surface 15, a pressure plate 18 and a small spiral surface 19, wherein the large spiral surface 15 is arranged on one end surface of the pressure plate 18, and the small spiral surface 19 is arranged on the other end surface of the pressure plate 18.

Further, the large spiral surface 15 and the small spiral surface 19 are both made of wear-resistant metal materials with smooth surfaces. The smooth surface of the roller is beneficial to reducing the rolling friction force, so that the energy loss is reduced, and the service life can be prolonged by adopting a wear-resistant metal material in a matching way.

Further, the large spiral surface 15 is composed of a plurality of metal blocks, and is fixed by screws.

Further, the large spiral surface 15 is formed in a truncated cone shape with a high middle and a low periphery.

Preferably, the wheel 1 is provided with mounting slots 17 adjacent the step structure 16 for mounting the transmission assembly 11. The mounting groove 17 leads from the large spiral surface 15 to the small spiral surface 19.

Preferably, the transmission assembly 11 comprises: a lever 12 arranged in the wheel 1 and a pressure piece 14 arranged at the lever 12 near the step structure 16.

Wherein the lever 12 comprises: the rotating end 121 and the movable end 122 are both arranged on the outer surface of the large spiral surface 15 and the outer surface of the small spiral surface 19 through the mounting grooves 17, the rotating end 121 is connected with the rotating wheel 1 through the rotating support 13, the movable end 122 is arranged on the outer surface of the small spiral surface 19 below the stepped structure 16, the rest part of the lever 12 is positioned in the mounting grooves 17, the pressing block 14 is arranged above the movable end 122 and is in contact with the movable end 122, and the pressing block 14 moves in the vertical direction through the movable end 122.

Preferably, the compact 14 comprises: the pressing block limiting part 141 is fixedly connected to the mounting groove 17, the pressing block main body 142 is disposed in the pressing block limiting part 141, and the sliding auxiliary part 143 is disposed between the pressing block limiting part 141 and the pressing block main body 142. Through setting up briquetting locating part 141 and reducing the range of rocking when briquetting main part 142 carries out the motion in the vertical direction, the slip that sets up between briquetting locating part 141 and briquetting main part 142 is supplementary to be made for the smooth wear-resisting metal material in surface, and its surface is smooth to be favorable to reducing rolling friction, reduces the loss of energy on the one hand, and on the other hand cooperation adopts wear-resisting metal material can increase of service life.

Preferably, the rotating support 13 comprises: the rotating support rod 131 and the return spring 132 sleeved on the rotating support rod 131, one end of the rotating support rod 131 is fixedly connected to the rotating wheel 1, the other end of the rotating support rod 131 is provided with an assembling groove 133, two sides of the assembling groove 133 are symmetrically provided with strip-shaped holes 134, and the strip-shaped holes 134 are connected with the lever 12 through the rotating shaft 135. The lever 12 is disposed in the mounting groove 133 and connected to the bar hole 134 through the rotation shaft 135, so that the lever 12 can rotate through the rotation shaft 135, and the rotation shaft 135 is disposed in the bar hole 134 to enable the lever 12 to vertically move within the range of the bar hole 134.

In another embodiment, a protruding structure 123 is further disposed between two ends of the lever 12 and adjacent to the large spiral surface 15, and the protruding structure 123 is used as a fulcrum of the lever 12. By providing the protruding structure 123, the ratio of the moment arms of the lever 12 can be changed during operation, thereby further saving the energy that is consumed when the roller passes through the step structure 16.

Further, a gradual transition is provided between the protruding structure 123 and the fixed end of the lever 12, which is more gradual as the roller passes over the lever 12.

The invention also comprises a rotating method of the rotating wheel, the end surface of which is stressed to realize radial rotation, comprising the following steps:

s1, arranging a plurality of rollers on a large spiral surface 15 and a small spiral surface 19 of a runner 1, and applying pressure to the runner 1 through the rollers;

s2, the large spiral surface 15 of the runner 1 starts to rotate after being pressurized until any roller arranged at one end of the large spiral surface 15 makes circular motion along the large spiral surface 15 and moves to a step structure 16;

s3, when S2 happens, the roller arranged on the small spiral surface 19 displaces to the movable end 122 of the lever 12, pressure is provided for the movable end 122 of the lever 12, the pressing block 14 is driven to transition the roller displaced to the step structure 16 of the large spiral surface 15 from the lowest point to the highest point, and the rotating wheel 1 completes a circle of rotation;

s4, repeating the actions from S2 to S3 to enable the turning wheel 1 to continue to rotate continuously.

In one embodiment, under the condition that the pressure applied to the small helicoid 19 is the same as the pressure applied to the large helicoid 15, the rollers of the small helicoid 19 are arranged in pairs at equal intervals, the rollers of the large helicoid 15 are arranged at one time of the rollers of the small helicoid 19 at equal intervals, the positions of the rollers of the large helicoid 15 are fixed, and the rollers at one end of the small helicoid 19 and the rotating wheel 1 do reverse circular motion at the same angular speed.

Furthermore, the rollers of the small spiral surface 19 are arranged at equal intervals of 4, and the rollers of the large spiral surface 15 are arranged at equal intervals of 8; the pressure on the small spiral surface 19 and the pressure on the large spiral surface 15 are both 800N, so the pressure output by the roller of each large spiral surface 15 is 100N, the pressure output by the roller of each small spiral surface 19 is 200N, wherein the position of the roller of the large spiral surface 15 is fixed, and the roller at one end of the small spiral surface 19 and the rotating wheel 1 perform reverse circular motion at the same angular speed.

Wherein, the rollers of the small spiral surface 19 are arranged at equal intervals of 4, and the angle interval between the adjacent rollers is 90 degrees; the rollers of the large helicoid 15 are arranged at equal intervals of 8, and the angle interval between the adjacent rollers is 45 degrees. Under the condition that the roller on one side of the large helicoid 15 is fixed, the rotating wheel 1 starts to rotate after being stressed, so that the angular speeds of the rollers arranged on the two sides (the large helicoid 15 and the small helicoid 19) of the rotating wheel 1 are the same, when the rotating wheel 1 rotates 45 degrees relative to the roller of the small helicoid 19, the roller of the rotating wheel 1 also rotates 45 degrees relative to the roller of the large helicoid 15, on the basis, the roller of the small helicoid 19 does reverse circular motion at the same angular speed, namely when the roller of the large helicoid 15 rotates 45 degrees relative to the roller of the small helicoid 19, the roller of the small helicoid 19 rotates 90 degrees, and therefore, when the roller of the large helicoid 15 displaces to the step structure 16, the roller of the small helicoid 19 can be displaced to the corresponding position to drive the lever 12, and the transition of the roller of the large helicoid 15 is completed.

Further, a protruding structure 123 is further disposed between two ends of the lever 12 and adjacent to the large spiral surface 15, and the protruding structure 123 is used as a fulcrum of the lever 12. According to the principle of the lever 12, it can be known that the ratio of the moment arms between the rollers on the lever 12 is changed through the movement of the rollers, so that the required energy can be reduced when the rollers complete the transition at the step structure 16, and the transition process is more moderate.

Example 2

Referring to fig. 11 to 16, the difference from the above embodiment is that the structure of the pressing piece 14 in embodiment 1 is eliminated, and in combination with fig. 11 to 13, the lever 12 includes: a rotating end 121 and a moving end 122, wherein the rotating end 121 and the moving end 122 are respectively arranged on the outer surface of the large spiral surface 15 and the outer surface of the small spiral surface 19 through the mounting groove 17, the rotating end 121 is connected with the spiral disc 1 through the rotating support 13, the moving end 122 is arranged on the outer surface of the small spiral surface 19 below the stepped structure 16, the rest part of the lever 12 is arranged in the mounting groove 17, the lifting end 14 is arranged above the moving end 122, and the lifting end 14 moves in the vertical direction through the moving end 122.

Further, in conjunction with fig. 14 to 16, a protruding structure 123 is further provided between two ends of the lever 12 and adjacent to the large spiral surface 15, and the protruding structure 123 is used as a fulcrum of the lever 12. According to the principle of the lever 12, it can be known that the proportion of the moment arm between the piston rod assemblies 3 on the lever 12 is changed through the movement of the piston rod assemblies 3, so that the required energy can be reduced when the piston rod assemblies 3 complete the transition at the stepped structure 16, and the transition process is more moderate.

Specifically, the calculation formula of the downward pressure applied to the lever is as follows:

F＝[F_{general assembly}/(α+β)]*α；

Wherein: f is the actual force of the lever, F_{General assembly}The pressure applied to the cylinder is provided by alpha, which is used for providing a downward pressure piston to form an angle with the large spiral surface, and beta, which is used for providing a downward pressure piston to form an angle with the lever.

Referring to fig. 17, the actual pressing force F of the end roller on the raised end 14 of the lever 12₁F/a b; actual pressure F of the end roller against the rotating end 121 of the lever 12₁＝F/a*a；

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (10)

1. A runner with an end face forced to rotate radially, comprising: the transmission assembly is arranged at the step structure by adopting a lever structure, and the transition from the lowest point to the highest point of a rolling shaft rolling on the large helicoid is realized through the transmission assembly.

2. The rotating wheel with end face stressed for realizing radial rotation of the claim 1, is characterized in that the rotating wheel is composed of a large spiral face, a pressure plate and a small spiral face, the large spiral face is arranged on one end face of the pressure plate, and the small spiral face is arranged on the other end face of the pressure plate.

3. The runner with end face forced for radial rotation of claim 1, wherein the runner is provided with mounting grooves at the stepped structure for mounting the transmission assembly.

4. A rotor wheel with end faces forced to rotate radially according to any of claims 1 or 3, wherein said transmission assembly comprises: the lever is arranged in the rotating wheel, and the pressing block is arranged at the position, close to the stepped structure, of the lever.

5. The wheel of claim 4, wherein the lever comprises: the rotating end is arranged on the outer surface of the large spiral surface through a rotating support piece, the movable end is arranged on the outer surface of the small spiral surface below the stepped structure, and the pressing block is arranged above the movable end.

6. The rotating wheel with the end face forced to rotate in the radial direction according to claim 4, wherein the pressing block comprises: the briquetting locating part of fixed connection in the mounting groove, set up in briquetting main part in the briquetting locating part and set up in the briquetting locating part with the slip auxiliary member between the briquetting main part.

7. A rotor wheel with end-face forced radial rotation according to claim 5, wherein the rotational support comprises: the rotary support rod and the reset spring sleeved on the rotary support rod, one end of the rotary support rod is fixedly connected with the rotating wheel, the other end of the rotary support rod is provided with an assembly groove, strip-shaped holes are symmetrically arranged on two sides of the assembly groove, and the strip-shaped holes are connected with the lever through rotating shafts.

8. The rotating wheel with the end face stressed to realize radial rotation according to claim 4, wherein a protruding structure is further arranged between two ends of the lever and adjacent to the large spiral face, and the protruding structure is used as a fulcrum of the lever.

9. A method of turning a rotor wheel having an end surface forced for radial rotation according to any one of claims 1 to 8, comprising the steps of:

s1, arranging a plurality of rolling shafts on a large spiral surface and a small spiral surface of a rotating wheel, and applying pressure to the rotating wheel through the rolling shafts;

s2, the large helicoid of the runner starts to rotate after being pressurized until any rolling shaft arranged at one end of the large helicoid performs circular motion along the large helicoid and moves to a step structure;

s3, when S2 happens, the rolling shaft arranged on the small helicoid displaces to the movable end of the lever to provide pressure for the movable end of the lever, so that the pressing block is driven to transition the rolling shaft displaced to the step structure of the large helicoid from the lowest point to the highest point, and the rotating wheel completes one-circle rotation;

and S4, repeating the actions from S2 to S3 to enable the rotating wheel to continuously rotate.

10. The method as claimed in claim 8, wherein the rollers of the small helicoids are equally spaced and arranged in pairs, the rollers of the large helicoids are equally spaced and arranged twice as long as the rollers of the small helicoids, the rollers of the large helicoids are fixed, and the rollers of the small helicoids and the rollers of the rotating wheel perform reverse circular motion at the same angular velocity.

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