CN220248672U - Axis self-adaptive adjusting sliding mechanism - Google Patents
Axis self-adaptive adjusting sliding mechanism Download PDFInfo
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- CN220248672U CN220248672U CN202320427999.2U CN202320427999U CN220248672U CN 220248672 U CN220248672 U CN 220248672U CN 202320427999 U CN202320427999 U CN 202320427999U CN 220248672 U CN220248672 U CN 220248672U
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Abstract
The utility model discloses an axis self-adaptive adjusting sliding mechanism, which comprises an elastic layer formed by taking a high polymer material as a matrix composite material, wherein the elastic layer is attached to a sliding sleeve, and the deflection of the sliding sleeve is automatically adjusted by utilizing the elastic deformation of the elastic material so as to adapt to the inclination of an axis.
Description
Technical Field
The utility model relates to the technical field of sliding bearings and mechanical transmission, in particular to an axis self-adaptive adjusting sliding mechanism.
Background
The components commonly used for supporting and transmitting motion are a shaft and a bearing, and the inclination angle and the swing error between an inner hole of the bearing and a shaft neck can obviously influence the bearing performance of the bearing, so that uneven loading and irregular heating are caused, the bearing capacity is reduced, and the friction coefficient is increased; the edge of the bearing is worn, glued, blocked and the like in severe cases, so that equipment is in fault and even safety accidents occur.
In the ideal situation, the rotor should rotate around its axis as shown in fig. 1, but in actual operation, the rotor axis cannot be completely consistent due to unavoidable errors in manufacturing and installation processes, and meanwhile, the rotor cannot stably rotate around its axis due to the influence of eccentric load and overturning moment, so that the rotor can be rubbed against a bearing hole when the radial forces are large, and serious safety accidents are caused.
The center line of the bearing is not aligned with the center line of the journal due to the influence of bending and unbalanced load, and the influence of errors in machining and mounting of the shaft or the bearing. The inclination of the axis reduces the bearing capacity of the bearing, increases friction power consumption and even causes locking failure of the bearing, and in order to improve the reliability of the bearing, the inclination of the axis is necessary to be improved. Current conventional practice employs aligning knuckle bearings, or tilt-able shoe structures, and contour modification of the shaft.
The self-aligning joint bearing is adopted, so that the joint bearing is difficult to be qualified under the condition of frequent rotation;
the tilting pad has the advantages that the tilting pad is complex in structure, occupies a large space, and cannot be installed in occasions with compact radial space;
the shape curve of the shaft profile is complex, and the shaft profile is difficult to process and even difficult to realize; even if it can be realized, either the accuracy is not ideal or the cost is high.
Disclosure of Invention
Aiming at the defects existing in the prior art, the embodiment of the utility model aims to provide an axis self-adaptive sliding mechanism so as to solve the problems in the background art.
In order to achieve the above purpose, the present utility model provides the following technical solutions:
the self-adaptive axial line regulating sliding mechanism includes one elastic layer of high molecular polymer material as matrix composite material and adhered to the sliding sleeve, and the elastic layer has elastic deformation to regulate the deflection of the sliding sleeve automatically to adapt to the inclination of the axial line.
As a further aspect of the present utility model, when the elastic layer is attached to the inner wall of the sliding sleeve, the sliding sleeve and the shaft are assembled into a single body by interference, and the outer surface of the sliding sleeve is used as a sliding friction surface to perform grinding with the gear hole or the bearing hole.
As a further scheme of the utility model, when the elastic layer is attached to the outer wall surface of the sliding sleeve, the sliding sleeve and the bearing hole or the gear hole are assembled into a whole in an interference mode, and the inner surface of the sliding sleeve is used as a sliding friction surface to perform counter grinding with the shaft.
As a further scheme of the utility model, the sliding sleeve is a metal sleeve or a nonmetal sleeve or a metal and nonmetal nest.
As a further scheme of the utility model, when the sliding sleeve is a metal sleeve, the sliding sleeve is formed by casting, die casting, forging and overlaying, or formed by adopting a mechanical processing mode, and the used materials comprise cast iron, copper alloy, aluminum alloy, zinc alloy and Babbitt alloy bearing alloy with lubricating performance, and the sliding sleeve is cast, nested, overlaying copper alloy, bus alloy and aluminum-tin alloy on steel materials and aluminum materials.
As a further scheme of the utility model, when the sliding sleeve is a non-metal sleeve, the sliding sleeve is formed in a winding, injection molding, mould pressing, hot melting and vulcanization mode; the materials used comprise carbon fiber, glass fiber, aramid fiber, PTFE, PEEK, PI, POM, PPS, PE, PA, PPS and PU or the mixture of a plurality of materials.
As a further scheme of the utility model, when the sliding sleeve is a metal and nonmetal nesting, at least one nonmetal material is injection molded, coated, cast, nested, wound or sprayed on a steel base, an aluminum base and a copper base.
As a further scheme of the utility model, the elastic layer is adhered to the sliding shaft sleeve in a glue bonding mode, a hot melting mode, a vulcanizing mode, a spraying mode or an embedding mode.
As a further aspect of the present utility model, the elastic material used for the elastic layer includes SBS, SIS, SEBS, EPDM, POE, TPE, TPV, TPO, TPU, TPEE, PPE or a non-metal sleeve material, including one or more of carbon fiber, glass fiber, aramid fiber, PTFE, PEEK, PI, POM, PPS, PE, PA, PPS, PU.
As a further aspect of the present utility model, the elastic layer has a thickness of 0mm to 15mm.
Through the structure of the blocking type, the deflection degree of the shaft sleeve is automatically adjusted by utilizing the elastic deformation of the elastic material, so that the shaft sleeve is inclined in the axial direction or in the circumferential direction, wherein the inclination in the circumferential direction means slight swing in a radial clearance passing manner, and the purpose of balanced loading is achieved.
The utility model has the following beneficial effects:
1. the utility model adopts an axis self-adaptive adjusting technology and is applied to a gear box to solve the problems of unbalanced stress of a gear box shaft, difficult shape modification of a pin shaft in processing, inconsistent axis caused by flexible deformation such as bending moment, overturning force and the like, and the phenomenon of edge abrasion of the shaft and a gear hole.
2. The utility model adopts the high polymer material as the matrix composite material as the elastic layer, designs the elastic modulus of the material according to the working condition, proportions the material components and proportions according to the elastic modulus, and utilizes the elastic deformation of the material to automatically adjust the deformation amount to adapt to the inclination of the axis, thereby achieving the purposes of consistent axis and balanced loading.
In order to more clearly illustrate the structural features and efficacy of the present utility model, the present utility model will be described in detail below with reference to the accompanying drawings and examples.
Drawings
Fig. 1 is a schematic view of a prior art central axis tilt.
Fig. 2 and 3 are schematic views showing the elastic layer attached to the inner wall of the sliding sleeve in embodiment 1 of the present utility model.
Fig. 4 and 5 are schematic views showing the structure of the elastic layer attached to the outer wall surface of the sliding sleeve according to embodiment 2 of the present utility model.
Detailed Description
The utility model will be further described in the following clear and complete description with reference to the figures and the associated knowledge, it being evident that the described applications are only some, but not all embodiments of the utility model.
Referring to fig. 1 to 5, in the prior art, components commonly used for supporting and transmitting motion are a shaft and a bearing, and inclination angles and swing errors between an inner hole of the bearing and a shaft neck can have significant influence on the bearing performance, so that uneven loading, irregular heating, bearing capacity reduction and friction coefficient increase are caused; the phenomena of abrasion, gluing, blocking and the like of the edge of the bearing can be caused in severe cases, so that equipment is in fault and even safety accidents occur;
in fig. 1, the rotor should rotate around its axis in an ideal state, but in actual operation, the rotor axis cannot be completely consistent due to unavoidable errors in manufacturing and installation processes, and meanwhile, the rotor cannot stably rotate around its axis due to the influence of eccentric load and overturning moment, so that the rotor can be rubbed against a bearing hole when the radial forces are large, and serious safety accidents are caused.
To illustrate the effect of the axis tilt angle β on bearing performance, water lubrication is taken as an example; the diameter D=80 mm of the mating grinding surface of the sliding sleeve is calculated in a simulation mode, the ratio L/D of the bearing is=1, the relative gap psi is=0.1%, the rotating speed N is=3000 r/min, and the eccentricity epsilon is=0.6; the axial tilt angles β=0, 0.1, 0.225, 0.35mrad were calculated. Under different inclination angles, the water film thickness and the water film dynamic pressure distribution condition of the matching surface of the sliding sleeve.
For the same load:
when the axis is not inclined, beta=0, the thickness of the water film is the same along the axial direction, the thickness value of the water film is the largest (16 um), the maximum pressure distribution is positioned in the middle of the bearing, and the maximum water film pressure value is the smallest (0.976 Mpa); when the axis is centered, the bearing cannot be eccentrically worn, the thickness of the water film is large, and two pairs of grinding surfaces cannot be directly contacted, so that inclined friction is avoided. The bearing has long service life.
When the axis is inclined, beta is not equal to 0, the thicknesses of the water films are different along the axial direction, the thicknesses of the water films are smaller and smaller (the minimum water film thickness is 2 um) along with the increase of the inclination angle, the maximum water film pressure is larger and larger (the maximum water film pressure is 3.64 Mpa); when the axis is not centered, the bearing can cause eccentric wear, the water film is smaller and smaller, the maximum water film pressure is larger and larger, and the running state of the bearing is worsened, so that the bearing generates friction, the temperature is increased, and the condition of seizing of the shaft is caused.
In order to solve the problems, the utility model adopts the high polymer material as the matrix composite material as the elastic layer, the elastic layer is attached to the sliding sleeve, and the deflection of the sliding sleeve is automatically adjusted by utilizing the elastic deformation of the elastic material so as to adapt to the inclination of the axis, thereby achieving the aim of centering the axis and balancing the load.
The self-adaptive axial centering adjusting sliding mechanism formed by the elastic material of the high polymer material and the shaft or the sliding sleeve has a series of excellent characteristics of antifriction, wear resistance, low noise and the like, and has long service life.
According to the utility model, the self-adaptive adjustment sliding mechanism is centered by adopting the axis formed by the elastic material of the high polymer material and the shaft or the sliding sleeve, the elastic modulus of the material is designed according to the working condition, the material components and the respective duty ratio are proportioned according to the elastic modulus, the deformation amount is automatically adjusted by utilizing the elastic deformation of the material so as to realize the inclination of the sliding sleeve in all directions, so that the sliding sleeve is suitable for the deflection of the shaft or the seat hole, the compensation can be carried out along with the different rotation speeds and loads within a certain range, the stress concentration is avoided, and the high adaptability is realized.
The self-adaptive axial centering adjusting sliding mechanism is formed by the elastic material of the high polymer material and the shaft or the sliding sleeve, and the matching sliding surface is a cylindrical surface, so that the self-adaptive axial centering adjusting sliding mechanism has the advantages of simple processing and wide application range; the contour curve can be processed without a special machine tool.
The utility model adopts the self-adaptive adjustment sliding mechanism with the axis centering formed by the elastic material of the high polymer material and the shaft or the sliding sleeve, directly integrates the sliding sleeve and the shaft or the bearing hole, greatly reduces the radial dimension of the bearing, and has important significance for improving the power torque density, reducing the cost and facilitating the disassembly and assembly.
The following provides specific examples of the utility model
Example 1
In the embodiment, the high polymer material is used as a matrix composite material and is used as an elastic layer, the elastic modulus of the material is designed according to the working condition, the material components and the proportion are proportioned according to the elastic modulus, and the elastic deformation of the material is utilized to automatically adjust the deformation amount to adapt to the inclination of the axis, so that the purposes of consistent axis and balanced loading are achieved; the method comprises the following steps:
an axis self-adaptive adjusting sliding mechanism comprises a shaft 1, a sliding sleeve 2, an elastic layer 3 and a gear 4 or a bearing hole (when the shaft is matched with the bearing hole), wherein the elastic layer is attached to the inner wall of the sliding sleeve, the sliding sleeve and the shaft are assembled into a whole in an interference way, and the outer surface of the sliding sleeve is used as a sliding friction surface to be subjected to grinding with the gear hole or the bearing hole; the elastic layer is attached to the sliding sleeve, and the deflection of the sliding sleeve is automatically adjusted by utilizing the elastic deformation of the elastic material so as to adapt to the inclination of the axes of the gears or the bearing seat holes, thereby achieving the purpose of parallel axes and balanced loading;
the sliding sleeve can be a metal sleeve or a non-metal sleeve; or metal and non-metal nesting.
When the sliding sleeve is a metal sleeve, the sliding sleeve can be formed by casting, die casting, forging, overlaying and the like, and also can be formed by adopting a mechanical processing mode. The materials used include cast iron, copper alloy, aluminum alloy, zinc alloy, babbitt alloy and other bearing alloys with lubricating performance, and casting, nesting, overlaying copper alloy, bus alloy, aluminum-tin alloy and the like on steel materials and aluminum materials are all within the protection scope of the patent.
When the sliding sleeve is a nonmetallic sleeve, the sliding sleeve can be formed by winding, injection molding, compression molding, hot melting, vulcanization and the like, including but not limited to the forming method. The materials used include, but are not limited to, carbon fiber, glass fiber, aramid fiber, PTFE, PEEK, PI, POM, PPS, PE, PA, PPS, PU, etc., and mixtures of one or more of these materials.
When the sliding sleeve is a metal or nonmetal nesting, the sliding sleeve can be steel-based, aluminum-based, copper-based, injection-molded, plastic-coated, cast, nested, wound or sprayed with at least one nonmetal material.
The elastic layer is adhered to the sliding shaft sleeve in a glue bonding mode, a hot melting mode, a vulcanizing mode, a spraying mode or an embedding mode. The elastic material used includes, but is not limited to, SBS, SIS, SEBS, EPDM, POE, TPE, TPV, TPO, TPU, TPEE, PPE and the like. Non-metallic sleeve materials may also be used, including, but not limited to, carbon fiber, fiberglass, aramid fiber, PTFE, PEEK, PI, POM, PPS, PE, PA, PPS, PU, and the like, and mixtures of one or more of these materials.
In this embodiment, the elastic layer has a thickness of 0mm to 15mm. Preferably 0.5-3mm thick.
In this embodiment, the shape of the outer wall of the sliding sleeve is not particularly limited, and may be machined according to practical use requirements by methods well known to those skilled in the art. Obviously, the sliding sleeve adopts a multi-section structure, and is provided with different oil grooves to break or layer metal, nonmetal and metal and nonmetal layers, which are all within the protection scope of the utility model.
Example 2
Referring to fig. 4 and 5, an axis-adaptive sliding mechanism includes a shaft 1, a sliding sleeve 2, an elastic layer 3, and a gear 4 or a bearing hole. In the embodiment, a high polymer material is used as a matrix composite material and is used as an elastic layer, the elastic layer is attached to the outer wall surface of the sliding sleeve, the sliding sleeve and the bearing hole or the gear hole are assembled into a whole in an interference mode, and the inner surface of the sliding sleeve is used as a sliding friction surface to be subjected to grinding with the shaft.
The embodiment utilizes the elastic layer to be attached to the sliding sleeve, and utilizes the elastic deformation of the elastic material to automatically adjust the deflection of the sliding sleeve so as to adapt to the inclination of the shaft, thereby achieving the purpose that the shaft and the bearing hole are parallel in axis and uniformly loaded.
The elastic modulus of the elastic layer is designed according to the working condition, and then the material components and the respective proportions are proportioned according to the elastic modulus.
The sliding sleeve can be a metal sleeve or a non-metal sleeve; or metal and non-metal nesting.
When the sliding sleeve is a metal sleeve, the sliding sleeve can be formed by casting, die casting, forging, overlaying and the like, and also can be formed by adopting a mechanical processing mode. The materials used include cast iron, copper alloy, aluminum alloy, zinc alloy, babbitt alloy and other bearing alloys with lubricating performance, and casting, nesting, overlaying copper alloy, bus alloy, aluminum-tin alloy and the like on steel materials and aluminum materials are all within the protection scope of the patent.
When the sliding sleeve is a nonmetallic sleeve, the sliding sleeve can be formed by winding, injection molding, compression molding, hot melting, vulcanization and the like, including but not limited to the forming method. The materials used include, but are not limited to, carbon fiber, glass fiber, aramid fiber, PTFE, PEEK, PI, POM, PPS, PE, PA, PU, etc., and mixtures of one or more of these materials.
When the sliding sleeve is a metal or nonmetal nesting, the sliding sleeve can be steel-based, aluminum-based, copper-based, injection-molded, plastic-coated, cast, nested, wound or sprayed with at least one nonmetal material.
The elastic layer is adhered to the sliding shaft sleeve in a glue bonding mode, a hot melting mode, a vulcanizing mode, a spraying mode or an embedding mode. The elastic material used includes, but is not limited to, SBS, SIS, SEBS, EPDM, POE, TPE, TPV, TPO, TPU, TPEE, PPE and the like. Non-metallic sleeve materials may also be used, including, but not limited to, carbon fiber, fiberglass, aramid fiber, PTFE, PEEK, PI, POM, PPS, PE, PA, PPS, PU, and the like, and mixtures of one or more of these materials.
In this embodiment, the elastic layer has a thickness of 0 to 15mm. Preferably 0.5-3mm thick.
In this embodiment, the shape of the outer wall of the sliding sleeve is not particularly limited, and may be machined according to practical use requirements by methods well known to those skilled in the art. Obviously, the sliding sleeve adopts a multi-section structure, and is provided with different oil grooves to break or layer metal, nonmetal and metal and nonmetal layers, which are all within the protection scope of the utility model.
In the embodiment 1 and the embodiment 2 of the utility model, the high polymer material is used as the matrix composite material as the elastic layer, the elastic layer is attached to the sliding sleeve, and the deflection of the sliding sleeve is automatically adjusted by utilizing the elastic deformation of the elastic material so as to adapt to the inclination of the axis, thereby achieving the aim of centering the axis and balancing the loading. The self-adaptive sliding mechanism with the axial line centering formed by the elastic material of the high polymer material and the shaft or the sliding sleeve has a series of excellent characteristics of antifriction, wear resistance, low noise and the like, and has long service life. The self-adaptive sliding mechanism is centered on an axis formed by elastic materials of high polymer materials and a shaft or a sliding sleeve, the elastic modulus of the materials is designed according to working conditions, the material components and the respective duty ratio are proportioned according to the elastic modulus, the deformation amount is automatically adjusted by utilizing the elastic deformation of the materials so as to realize the inclination of the sliding sleeve in all directions, so that the sliding sleeve adapts to the deflection of the shaft or a seat hole, and the sliding mechanism can compensate along with different rotation speeds and loads within a certain range, avoids stress concentration and has higher adaptability. The self-adaptive adjustment sliding mechanism for axial alignment is formed by adopting an elastic material of a high polymer material and a shaft or a sliding sleeve, and the matching sliding surface of the self-adaptive adjustment sliding mechanism is a cylindrical surface, so that the self-adaptive adjustment sliding mechanism has the advantages of simple processing and wide application range; the contour curve can be processed without a special machine tool. The self-adaptive sliding mechanism is aligned with the axis formed by the elastic material of the high polymer material and the shaft or the sliding sleeve, the sliding sleeve and the shaft are directly integrated or the bearing hole is integrated, so that the radial size of the bearing is greatly reduced, and the self-adaptive sliding mechanism has important significance in improving the power torque density, reducing the cost and facilitating the disassembly and assembly.
The technical principle of the present utility model has been described above in connection with specific embodiments, but is only the preferred embodiment of the present utility model. The protection scope of the present utility model is not limited to the above embodiments, and all technical solutions belonging to the concept of the present utility model belong to the protection scope of the present utility model. Other embodiments of the utility model will occur to those skilled in the art without the exercise of inventive effort and are intended to fall within the scope of the utility model.
Claims (5)
1. The utility model provides an axis self-adaptation adjustment slide mechanism which characterized in that, including regard high polymer material as the elastic layer that matrix composite constitutes, the elastic layer adheres to the slip cap, utilizes elastic deformation of elastic material to automatically adjust the deflection volume of slip cap to adapt to the slope of axis, when the elastic layer adheres to on the inner wall of slip cap, slip cap and axle interference fit become an organic whole, and the surface of slip cap carries out the regrinding with gear hole or bearing hole as the slip friction face.
2. An axis-adaptive sliding mechanism according to claim 1, wherein when the elastic layer is attached to the outer wall surface of the sliding sleeve, the sliding sleeve is interference-fitted with the bearing hole or the gear hole, and the inner surface of the sliding sleeve is subjected to counter-grinding with the shaft as a sliding friction surface.
3. An axis adaptive slide mechanism as recited in claim 2 wherein the slide sleeve is a metal sleeve or a non-metal sleeve or a metal and non-metal nest.
4. An axis-adaptive sliding mechanism according to claim 3, wherein the elastic layer is attached to the sliding sleeve by means of glue bonding, hot melting, vulcanization, spraying or embedding.
5. An axis adaptive sliding mechanism according to claim 1, wherein the elastic layer has a thickness of 0mm to 15mm.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202320427999.2U CN220248672U (en) | 2023-03-09 | 2023-03-09 | Axis self-adaptive adjusting sliding mechanism |
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| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202320427999.2U CN220248672U (en) | 2023-03-09 | 2023-03-09 | Axis self-adaptive adjusting sliding mechanism |
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| Publication Number | Publication Date |
|---|---|
| CN220248672U true CN220248672U (en) | 2023-12-26 |
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| CN202320427999.2U Active CN220248672U (en) | 2023-03-09 | 2023-03-09 | Axis self-adaptive adjusting sliding mechanism |
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| CN (1) | CN220248672U (en) |
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- 2023-03-09 CN CN202320427999.2U patent/CN220248672U/en active Active
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