CN115042016A

CN115042016A - Experimental device for processing slender rod and shaft parts assisted by ultrasonic static pressure oil film

Info

Publication number: CN115042016A
Application number: CN202210559133.7A
Authority: CN
Inventors: 沈志煌; 曹中和; 皮钧; 侯达盘; 姜涛; 盛滨
Original assignee: Jimei University
Current assignee: Jimei University
Priority date: 2022-05-23
Filing date: 2022-05-23
Publication date: 2022-09-13
Anticipated expiration: 2042-05-23
Also published as: CN115042016B

Abstract

The invention provides an experimental device for processing auxiliary slender rod and shaft parts by an ultrasonic static pressure oil film, which comprises: the ultrasonic vibration measuring device comprises a transducer, a tool head, a transducer matching clamp, a set of three-degree-of-freedom moving device, a pair of small machine tool tailstocks containing thimbles, an oil collecting tank, a slide rail, a positioning steel plate, four heavy-load suckers, a quantitative oil supply system, a set of signal generating system and a set of laser vibration measuring device, wherein the transducer, the tool head and the transducer matching clamp form an ultrasonic supporting device. The experimental device for part processing disclosed by the invention has the advantages that the three-degree-of-freedom moving device is utilized to control the ultrasonic supporting device so as to change the thickness of an oil film between a workpiece and the ultrasonic supporting device to achieve the purpose of supporting the workpiece under different amplitudes, meanwhile, the structural parameters of a tool head in the ultrasonic device and the distance between the small machine tool tailstock are changed to realize the experiment of processing the slender rod and shaft parts with different sizes, and the experimental device has the characteristics of high precision and easiness in operation.

Description

Experimental device for processing slender rod and shaft parts assisted by ultrasonic static pressure oil film

Technical Field

The invention relates to the field of precision manufacturing and processing of slender rods and shaft parts, and is applicable to processing experimental devices of weak rigidity shaft parts such as slender rods, shafts and the like. The experimental device is specifically designed for processing the auxiliary slender rod and shaft parts by the aid of the ultrasonic static pressure oil film.

Background

The application of slender rods and shaft parts on high-precision equipment is more and more extensive, and the performance of the equipment is directly influenced by the accuracy and stability of the slender rods and the shaft parts. In recent years, the attention of the front-end manufacturing industry is deeply paid to the large aspect ratio helical surface part as a typical representative of the slender rod part, and the reason is that the precision and the stability of the large aspect ratio helical surface part greatly influence the high-end digital equipment, and the main reason influencing the performance of the large aspect ratio helical surface part is that: the workpiece with the large length-diameter ratio belongs to a weak rigidity workpiece, and is easy to vibrate due to stress, deform due to heating and the like under the action of cutting force, so that the problems of poor product stability, low precision and the like are caused. On the basis of solving the precision problem of finished products of slender rod type spiral surface parts, generally, an excircle of one end surface of a workpiece is clamped by a claw disc, the other end of the workpiece is positioned by a tip, and the rigidity of the whole system is increased by adopting a mode of fixing a center frame in the middle of a slender rod. Furthermore, the influence of the rake angle parameter and the cutting depth parameter of the tool on the vibration generated in the machining process is considered. However, the problems of the machining process are lack of significant research results and related machining methods, and the problems of vibration, high-temperature deformation and the like generated in the machining process of the workpiece cannot be effectively solved.

Disclosure of Invention

The invention aims to provide a processing experimental device aiming at the problem that the precision of finished products of slender rods and shafts is not high. The specific invention content is as follows:

an experimental device for processing slender rod and shaft parts assisted by an ultrasonic static pressure oil film comprises at least one transducer 16, a tool head, a transducer clamp 17, a set of three-degree-of-freedom moving device 8, a pair of small machine tool tailstocks 2 containing thimbles, an oil collecting tank 6, a slide rail 3, a positioning steel plate 4, four heavy-load suckers 5, a quantitative oil supply system 10, a set of signal generating system 1 and a set of laser vibration measuring device 9,

wherein the ultrasonic supporting device 7 consists of a transducer 16, a tool head and a transducer clamp 17, the ultrasonic supporting device 7 is connected with the three-degree-of-freedom moving device 8, the three-degree-of-freedom moving device 8 is used for realizing the position transformation of the ultrasonic supporting device 7, the ultrasonic supporting device 7 and the laser vibration measuring device 9 are oppositely arranged, the real-time measurement of the motion state of a workpiece 14 caused by the ultrasonic supporting device 7 is realized, the signal generating system 1 provides excitation for the ultrasonic supporting device 7, when the energy converter 16 is excited, the energy converter starts to enter a working state, the heavy-load suckers 5 are arranged at four corners of the positioning steel plate 4, the functions of improving the stability of the system and adjusting the levelness of the positioning steel plate 4 are achieved, the positioning steel plate 4, the slide rail 3 and the pair of small machine tool tailstocks 2 containing the thimbles form a structure for fixing workpieces with different sizes; the oil collecting tank 6 is arranged below a workpiece and plays a role in collecting oil, the quantitative oil supply system 10 comprises a servo oil supply system and an oil return system, the quantitative oil supply system 10 is provided with an oil outlet and an oil return port, the oil outlet is connected with the transducer 16 of the ultrasonic supporting device 7 to supply oil to the ultrasonic supporting device 7, and the oil return port is connected with the oil collecting tank 6 to recover used oil and filter the used oil and then feed the oil into the oil supply system oil tank 21.

Furthermore, the ultrasonic transducer 16 (including the horn with a special structure) and the horn with an oil inlet and an oil outlet and an internal oil passage are used in cooperation with the quantitative oil supply system 10 through an oil pipe, the tool head (specially designed) is provided with the oil passage matched with the horn and one end face of the tool head is provided with a static pressure oil cavity and an arc-shaped structure, the transducer 16 is connected with the tool head in a matching mode and then fixed on a transducer clamp 17 matched with the transducer 16, and when the transducer 16 is excited, the tool head starts to enter a working state.

Furthermore, the oil collecting tank 6, the pair of small machine tool tailstocks 2 with ejector pins and the slide rail 3 are arranged on the positioning steel plate 4, the workpiece 14 is arranged between the pair of ejector pins, and after the relative positions of the pair of ejector pins are changed, processing experiments can be carried out on slender rods and shaft parts with different lengths.

Further, the oil collecting tank 6 comprises an oil return pipe 11 matched with the quantitative oil supply system 10, and when the oil in the oil collecting tank 6 is collected and drawn out, the oil is drawn out by an oil return device in the quantitative oil supply system 10 and enters the oil filter 23, and then returns to the quantitative oil supply system 10 again.

Further, the three-degree-of-freedom moving device 8 is an X, Y, Z three-axis axial displacement device, by which the relative position of the ultrasonic support device 7 and the workpiece 14 can be changed.

Further, the quantitative oil supply system 10 is a quantitative oil supply station, and includes a servo control system 22, an oil filter 23, an oil suction pump 25, and a motor 24, the servo output system can adjust output oil quantity and oil pressure and can directly read the output oil quantity and the oil pressure, and the oil suction pump 25, the motor 24 and the oil filter 23 are used in cooperation to achieve the effects of oil return and oil filtration.

Further, the laser vibration measuring device 9 is used for measuring the motion state of the workpiece, is arranged opposite to the ultrasonic supporting device 7, and plays a role in real-time measurement.

Furthermore, the heavy-duty suckers 5 are arranged at four corners of the positioning steel plate 4, so that the stability of the whole device is improved.

The invention has the following technical effects:

the experimental device is simple to operate, can be used for carrying out experimental research on workpieces with different sizes by adjusting the distance between the ejector pins, and can be used for carrying out real-time measurement on different positions of the workpieces.

Drawings

FIG. 1 is a schematic perspective view of an experimental apparatus according to the present invention;

FIG. 2 is a schematic view of the experimental apparatus according to the present invention;

FIG. 3 is a schematic diagram of the experimental setup of the present invention;

FIG. 4 is a schematic view of an ultrasonic support device and a three-degree-of-freedom mobile device according to the present invention;

FIG. 5 is a schematic view of the constant oil supply system of the present invention;

1-a signal generating system, 2-a small machine tool tailstock with a thimble, 3-a slide rail, 4-a positioning steel plate, 5-a heavy-load sucker, 6-an oil collecting tank, 7-an ultrasonic supporting device, 8-a three-degree-of-freedom moving device, 9-a laser vibration measuring device, 10-a quantitative oil supply system, 11-an oil return pipe, 12-an oil conveying pipe and 13-a fixed table top, 14-workpiece, 15-lead, 16-transducer, 17-transducer clamp, 18-Z axis (axial) moving device, 19-X axis (axial) moving device, 20-Y axis (axial) moving device, 21-oil supply system oil tank, 22-servo control system, 23-oil filter, 24-motor, 25-oil suction pump and 26-flowmeter.

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.

In the description of the present invention, it is to be understood that the terms "center", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "axial", "circumferential", and the like, indicate orientations or positional relationships based on those shown in the drawings, and are used merely for convenience of description and for simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be considered as limiting the present invention. In the present invention, unless otherwise expressly specified or limited, the terms "disposed," "mounted," "connected," and "fixed" are to be construed broadly and may, for example, be fixedly connected or detachably connected; may be a mechanical connection; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood according to specific situations by those of ordinary skill in the art.

Furthermore, the terms "first", "second", etc. are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature.

As shown in fig. 1, 2, and 3, the experimental apparatus of the present invention includes a signal generating system 1, a pair of small machine tool tailstocks 2 containing ejector pins, a slide rail 3, a positioning steel plate 4, a heavy-duty suction cup 5, an oil collecting tank 6, an ultrasonic supporting device 7, a three-degree-of-freedom moving device 8, a laser vibration measuring device 9, a quantitative oil supply system 10, an oil return pipe 11, an oil delivery pipe 12, a fixed table 13, a workpiece 14, and a conducting wire 15.

The ultrasonic support means 7 comprises a transducer 16, a tool head (at one end of the transducer 16, i.e. at the working end, i.e. the right end as viewed in fig. 4), a transducer holder 17, and the transducer 16 and the tool head are fixed to the transducer holder 17. The ultrasonic supporting device 7 is connected to the signal generating system 1 through a lead 15, the signal generating system 1 provides excitation for the ultrasonic supporting device 7, and meanwhile, the ultrasonic supporting device 7 is connected to an oil outlet (an interface of a flow meter 26 in fig. 5) of the quantitative oil supply system 10 through an oil pipeline 12. An oil outlet of the quantitative oil supply system 10 is connected with an oil inlet of an amplitude transformer of the transducer 16 through an oil pipeline 12 by threads, when the signal generation system 1 inputs excitation to the transducer 16 and the quantitative oil supply system 10 supplies oil to the ultrasonic supporting device 7, the whole experimental device starts to enter an experimental working state, as shown in fig. 1, 2 and 3, a workpiece in the drawings takes a ball screw as an example. The quantitative oil supply system 10 comprises an oil supply system tank 21, a pumping device (not shown in the figure) arranged in the oil supply system tank 21, an oil delivery pipe 12 connected with the pumping device, and a flow meter 26 arranged on the oil delivery pipe 12, wherein the quantitative oil supply system 10 controls the oil delivery through a servo control system 22. The workpiece 14 is tightly pressed between two thimbles of the small machine tool tailstock 2 with the thimbles, the tool head of the ultrasonic supporting device 7 is aligned to the surface of the workpiece 14, and meanwhile, the laser vibration measuring device 9 is arranged on one side of the oil collecting tank 6 relative to the ultrasonic supporting device 7, so that the motion state of the workpiece can be measured in real time.

When the experiment is started, the laser vibration measuring device 9 can measure the motion state of the workpiece 14 in real time, as shown in fig. 3. The pair of small lathe tailstock 2 containing the ejector pins is arranged on the sliding rail 3, the fixing mode of the pair of small lathe tailstock 2 containing the ejector pins for the workpiece 14 is a mode of tightly pushing two ends of the workpiece, machine tailstock and ejector pins with different specifications and sizes can be selected according to workpieces with different sizes, the sliding rail 3 is arranged on the positioning steel plate 4, the positioning steel plate 4 is arranged on the fixed desktop 13 through the heavy-load suckers 5, the heavy-load suckers 5 are arranged at four corners of the positioning steel plate 4, and the functions of improving the stability of the system and adjusting the levelness of the positioning steel plate 4 are achieved. The oil collecting tank 6 is arranged below the workpiece 14, between the pair of small machine tool tailstocks 2 with ejector pins and above the slide rails 3, an oil return pipe 11 of the oil collecting tank 6 is connected to an oil return port (an interface of an oil filter 23 in fig. 5) of the quantitative oil supply system 10, and the oil return pipe is filtered by an oil return device and then returns to an oil tank (an oil supply system oil tank 21 in fig. 5) of the quantitative oil supply system 10. As shown in fig. 5, the oil return device of the present invention includes a motor 24, an oil suction pump 25, an oil return pipe 11 and an oil filter 23, the oil return port is connected to the oil collection tank 6 through the oil return pipe 11 to recover used oil, the filtered oil is fed into the oil supply system tank 21 of the constant-volume oil supply system 10 through the oil filter 23, and the motor 24 is controlled by the servo control system 22 to drive the oil suction pump 25 to operate.

Before the experiment is started, the distance between the ultrasonic supporting device 7 and the workpiece 14 in fig. 2 is changed by adjusting the three-degree-of-freedom moving device 8, so that the relative position between the ultrasonic supporting device 7 and the workpiece 14 in fig. 2 is changed, and different supporting influences on the workpiece are realized, wherein the three-degree-of-freedom moving device 8 comprises a Z-axis moving device 18, an X-axis moving device 19 and a Y-axis moving device 20. The ultrasonic supporting device 7 and the three-degree-of-freedom moving device 8 can have various specifications and sizes, and the transducer clamp 17 and the three-degree-of-freedom moving device 8 can select corresponding sizes according to the size of the transducer 16 so as to meet the requirements of fixing and moving the transducer 16. For example, the support on the different height surfaces of the workpiece can be changed by adjusting the component Z-axis moving device 18 in fig. 4, the support on the different horizontal positions of the workpiece 14 in fig. 2 can be changed by adjusting the component X-axis moving device 19 in fig. 4, the support effect on the workpiece 14 in the figure by different oil film thicknesses can be realized by adjusting the component Y-axis moving device 20 in fig. 4, and the support effect on the workpiece 14 under different pressures can also be tested by adjusting the oil outlet pressure of the servo control system 22 in fig. 5.

The above description is only for the specific embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention are included in the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the appended claims.

Claims

1. The utility model provides an experimental apparatus that is used for supersound hydrostatic oil film to assist processing of slender pole, axle type parts which characterized in that: comprises at least one transducer (16), a tool head, a transducer clamp (17), a set of three-degree-of-freedom moving device (8), a pair of small machine tool tailstocks (2) containing thimbles, an oil collecting tank (6), a slide rail (3), a positioning steel plate (4), four heavy-load suckers (5), a quantitative oil supply system (10), a set of signal generating system (1) and a set of laser vibration measuring device (9),

wherein, supersound strutting arrangement (7) are constituteed to transducer (16), instrument head, transducer anchor clamps (17), supersound strutting arrangement (7) with three degrees of freedom mobile device (8) are connected, realize through three degrees of freedom mobile device (8) the position of supersound strutting arrangement (7) changes, supersound strutting arrangement (7) with laser vibration measuring device (9) are installed relatively, realize that supersound strutting arrangement (7) cause the real-time measurement of motion state to work piece (14), signal generation system (1) provides the excitation for supersound strutting arrangement (7), when transducer (16) receive the excitation and begin to get into operating condition, heavy-duty sucking disc (5) install in location steel sheet (4) four corners, play the stability that improves the system and adjust the effect of location steel sheet (4) levelness, location steel sheet (4) are, The sliding rail (3) and the pair of small machine tool tailstocks (2) containing the thimble form a structure for fixing workpieces with different sizes; the oil collecting tank (6) is arranged below a workpiece and plays a role in collecting oil, the quantitative oil supply system (10) comprises a servo oil supply system and an oil return system, the quantitative oil supply system (10) is provided with an oil outlet and an oil return port, the oil outlet is connected with a transducer (16) of the ultrasonic supporting device (7) to supply oil to the ultrasonic supporting device (7), and the oil return port is connected with the oil collecting tank (6) to recover used oil and filter the oil and then feed the oil into an oil supply system oil tank (21).

2. The experimental device for processing the auxiliary slender rod and shaft parts with the ultrasonic static-pressure oil film as claimed in claim 1, wherein: the horn-horn in the ultrasonic transducer (16) comprises an oil inlet, an oil outlet and an internal oil passage, the oil inlet is matched with the quantitative oil supply system (10) through an oil pipe for use, the tool head is provided with the oil passage matched with the horn, and one end face of the tool head comprises a static pressure oil cavity and an arc structure; the transducer (16) is fixed on a transducer clamp (17) which is designed by matching the transducer (16) after being matched and connected with the tool head, and the tool head starts to enter a working state when the transducer (16) is input and excited.

3. The experimental device for processing the auxiliary slender rod and shaft parts with the ultrasonic static-pressure oil film as claimed in claim 1, wherein: the oil collecting tank (6), the pair of small machine tool tailstock (2) with the ejector pins and the slide rail (3) are arranged on the positioning steel plate (4), the workpiece (14) is arranged between the pair of ejector pins, and after the relative positions of the pair of ejector pins are changed, processing experiments can be carried out on slender rods and shaft parts with different lengths.

4. The experimental device for processing the auxiliary slender rod and shaft parts with the ultrasonic static-pressure oil film as claimed in claim 1, wherein: the oil collecting tank (6) comprises an oil return pipe (11) matched with the quantitative oil supply system (10), and when the oil in the oil collecting tank (6) is collected and can be drawn out, the oil is drawn out by an oil return device in the quantitative oil supply system (10) and enters an oil filter (23) and then returns to the quantitative oil supply system (10) again.

5. The experimental device for processing the auxiliary slender rod and shaft parts with the ultrasonic static-pressure oil film as claimed in claim 1, wherein: the three-degree-of-freedom moving device (8) is an X, Y, Z three-axis axial moving device, and the relative position of the ultrasonic supporting device (7) and the workpiece (14) can be changed through the three-degree-of-freedom moving device.

6. The experimental device for auxiliary machining of slender rods and shaft parts with the ultrasonic static pressure oil film according to claim 1, is characterized in that: the quantitative oil supply system (10) is a quantitative oil supply station and comprises a servo control system (22), an oil filter (23), an oil suction pump (25) and a motor (24), the servo output system can adjust the output oil quantity and the oil pressure and can directly read the output oil quantity and the oil pressure, and the oil suction pump (25) and the motor (24) are matched with the oil filter (23) to achieve the effects of oil return and oil filtration.

7. The experimental device for processing the auxiliary slender rod and shaft parts with the ultrasonic static-pressure oil film as claimed in claim 1, wherein: the laser vibration measuring device (9) is used for measuring the motion state of a workpiece, is arranged opposite to the ultrasonic supporting device (7), and plays a role in real-time measurement.

8. The experimental device for processing the auxiliary slender rod and shaft parts with the ultrasonic static-pressure oil film as claimed in claim 1, wherein: the heavy-load suckers (5) are installed at four corners of the positioning steel plate (4), and the effect of improving the stability of the whole device is achieved.