CYLINDRICAL-COMPONENT GRINDING DEVICE, AND WORKPIECE ADVANCING APPARATUS AND GRINDING METHOD THEREOF

Abstract

A double-disc straight groove cylindrical-component surface grinding disc, includes a first grinding disc and a second grinding disc, rotating relative to each other; the the first grinding disc's working face is planar; the second grinding disc's surface, opposite the first grinding disc, includes a set of radial straight grooves, with groove faces of the straight grooves are the working face of the second grinding disc; the cross-sectional outline of the working face of the second grinding disc is arcuate or V-shaped or is a V-shape having an arc; during grinding, a workpiece spins inside the straight grooves, while under the effect of an advancing apparatus, the workpiece slides in translational motion along the straight grooves. The described grinding disc device has high-volume production capabilities, and the shape accuracy and size consistency of the cylindrical roller's cylindrical surface and the efficiency in machining are improved, and machining cost is reduced.

Claims

1. A cylindrical-component grinding device, comprising: a loading apparatus (7), a power system (8), and a workpiece advancing apparatus (2), a grinding disc apparatus (1), a workpiece and grinding fluid separating apparatus (5), a workpiece cleaning apparatus (6) and a workpiece mixing apparatus (4), which are all connected to a workpiece conveying apparatus (3) in sequence, the loading apparatus (7) configured for loading the grinding disc apparatus (1), the power system (8) configured for driving the grinding disc apparatus (1), wherein: the grinding disc apparatus (1) comprises a first grinding disc (11) and a second grinding disc (12), the second grinding disc (12) and the first grinding disc (11) rotating relative to each other, the second grinding disc (12) having a rotation axis OO′ relative to the first grinding disc (11), a surface of the first grinding disc 11, opposite to the second grinding disc (12) is planar, which is a working surface (111) of the first grinding disc (11), and a set of radial straight grooves (121) are provided on a surface of the second grinding disc (12) opposite to the first grinding disc (11), the straight groove (121) having a groove surface functioning as a working face (1211) of the second grinding disc (12), the working face (1211) of the second grinding disc (12) having a cross-section outline in an arcuate shape or a V shape or a V shape with an arc; during grinding process, a processing workpiece (9) is arranged in the straight groove (121) along a groove extending direction, and meanwhile, an outer cylindrical surface of the processing workpiece (9) contacts with the working face (1211) of the second grinding disc (12); the straight groove (121) has a reference plane, a plane that passes through an axis/of the processing workpiece arranged in the straight groove, and is perpendicular to the working face (111) of the first grinding disc (11); there is an angle θ between a normal plane at a contacting point or a midpoint of a contacting arc between the processing workpiece (9) and the straight groove (121), and the reference plane of the straight groove (121), the angle θ ranging in 30˜60°; one end of the straight groove (121) close to a center of the second grinding disc (12) is a propulsion port, and the other end of the straight groove (121) is a discharge outlet; an eccentric distance e exists between the reference plane of the straight groove (121) and the rotation axis OO′, and the value of e is larger than or equal to zero, and smaller than a distance from the rotation axis OO′ to the discharge outlet of the straight groove (121); when the value of the eccentric distance e is zero, the straight groove (121) is arranged in a radial arrangement; and the second grinding disc (12) has a central position with a mounting portion of the workpiece advancing apparatus (2) provided thereon; under a condition of a grinding pressure and grinding lubrication, a friction coefficient between materials of the first grinding disc's working face (111) and materials of the processing workpiece is f1, a friction coefficient between materials of the second grinding disc's working face (1211) and materials of the processing workpiece is f2, and f1>f2, so as to ensure the processing workpiece to achieve spinning in the grinding process; the workpiece advancing apparatus (2) comprises a main body, a plurality of material-pushing mechanisms (22) and a plurality of material storage hoppers (23) are arranged on the main body, and the number of the material-pushing mechanism (22) and the number of the material storage hopper (23) are the same with that of the straight grooves (121) in the grinding disc apparatus, each of the material-pushing mechanisms (22) respectively cooperating with one material storage hopper (23); the material storage hopper (23) has a bottom provided with a push rod inlet (231) and a discharge port (232); the material-pushing mechanism (22) comprises a through hole (225) provided at the main body's bottom, the through hole (225) is coaxial with a line connecting a center of the push rod inlet (231) and a center of the discharge port (232); a push rod (224) and a stopper structure of the push rod (224) are formed inside the through hole (225); there is a one-to-one correspondence between the discharge port of the material storage hopper (23) and the propulsion port of the straight groove (121), and all of the push rods (224) are driven one and the same intermittent reciprocating mechanism to pass the processing workpiece (9) in the material storage hopper (23) into the straight groove (121).

2. The cylindrical-component grinding device as described according to claim 1, wherein, the stopper structure, of the push rod consists of a positioning shaft shoulder provided on the push rod (224), a positioning step provided in the through hole, and a spring (223) sheathing the push rod (224).

3. The cylindrical-component grinding device as described according to claim 1, wherein, the intermittent reciprocating mechanism employs a disc cam mechanism or a conical cam mechanism.

4. A workpiece advancing apparatus for a cylindrical-component grinding device, comprising: a main body, wherein a plurality of material-pushing mechanisms (22) and a plurality of material storage hopper (23) are arranged on the main body, and the number of the material-pushing mechanism (22) and the number of the material storage hopper (23) are the same with that of a straight grooves (121) in the grinding disc apparatus, each of the material-pushing mechanisms (22) respectively cooperating with one material storage hopper (23); the material storage hopper (23) has a bottom provided with a push rod inlet (231) and a discharge port (232); the material-pushing mechanism (22) comprises a through hole (225) provided at the main body's bottom, the through hole (225) is coaxial with a line connecting a center of the push rod inlet (231) and a center of the discharge port (232); a push rod (224) and a stopper structure of the push rod (224) are formed inside the through hole (225), there is a one-to-one correspondence between the discharge port of the material storage hopper (23) and the propulsion port of the straight groove (121), and all of the push rods (224) are driven one and the same intermittent reciprocating mechanism to pass a processing workpiece (9) in the material storage hopper (23) into the straight groove (121).

5. The workpiece advancing apparatus for a cylindrical component grinding device as described according to claim 4, wherein, the stopper structure of the push rod consists of a positioning shaft shoulder (222) provided on the push rod (224), a positioning step provided in the through hole, and a spring (223) sheathing the push rod (224).

6. A cylindrical-component grinding method, wherein, the method adopts the cylindrical-component grinding device according to claim 1 and comprises following steps that: step 1 is workpiece feeding, in which the workpiece conveying apparatus (3) feeds the processing workpiece into the material storage hopper (23) of the workpiece advancing apparatus (2), and under the drive of the intermittent reciprocating mechanism, the push rod (224) pushes the processing workpiece (9) in the material storage hopper (23) from the bottom of the material storage hopper to the straight groove (121), until all the straight grooves are fulfilled with the processing workpiece (9): step 2 is grinding processing, in which, the loading apparatus (7) provides loading for the grinding disc apparatus (1), the workpiece (9) contacts with the first grinding disc's working face (111) and the second grinding disc's working face (1211); the power system (8) drives the grinding disc apparatus (1), the second grinding disc (12) rotates relative to the first grinding disc (11), with a joint cooperation of the first grinding disc (11) and the second grinding disc (12), the processing workpiece (9) spins along its axis, and at the same time, the processing workpiece (9) performs translational slide motion from the propulsion port of the straight groove (121) towards the discharge outlet; during the motion, under the effect of free grinding particles in a grinding fluid, a micro material removal of the processing workpiece (9) is achieved, until the processing workpiece (9) has been discharged from the discharge outlet of the straight groove (121); Step 3 is workpiece cleaning, in which the workpiece and grinding fluid separating apparatus (5) separates the workpiece grinded in step 2 from the grinding fluid, and after filtration and precipitation, the grinding fluid is then in reuse; and after the workpiece is cleaned by the workpiece cleaning apparatus (6), the method goes on to step 4; step 4 is that after the workpieces have been disordered by the workpiece mixing apparatus (4), the method goes back to step 1; and after a period of continuous cycle grinding processing, a sampling inspection of the workpiece is made, and if a process requirements are met, the grinding processing ends, or otherwise, the grinding processing continues.

7. A cylindrical-component grinding method, wherein, the method adopts the cylindrical-component grinding device according to claim 2 and comprises following steps that: step 1 is workpiece feeding, in which the workpiece conveying apparatus (3) feeds the processing workpiece into the material storage hopper (23) of the workpiece advancing apparatus (2), and under the drive of the intermittent reciprocating mechanism, the push rod (224) pushes the processing workpiece (9) in the material storage hopper (23) from the bottom of the material storage hopper to the straight groove (121), until all the straight grooves are fulfilled with the processing workpiece (9): step 2 is grinding processing, in which, the loading apparatus (7) provides loading for the grinding disc apparatus (1), the workpiece (9) contacts with the first grinding disc's working face (111) and the second grinding disc's working face (1211); the power system (8) drives the grinding disc apparatus (1), the second grinding disc (12) rotates relative to the first grinding disc (11), with a joint cooperation of the first grinding disc (11) and the second grinding disc (12), the processing workpiece (9) spins along its axis, and at the same time, the processing workpiece (9) performs translational slide motion from the propulsion port of the straight groove (121) towards the discharge outlet; during the motion, under the effect of free grinding particles in a grinding fluid, a micro material removal of the processing workpiece (9) is achieved, until the processing workpiece (9) has been discharged from the discharge outlet of the straight groove (121); Step 3 is workpiece cleaning, in which the workpiece and grinding fluid separating apparatus (5) separates the workpiece grinded in step 2 from the grinding fluid, and after filtration and precipitation, the grinding fluid is then in reuse; and after the workpiece is cleaned by the workpiece cleaning apparatus (6), the method goes on to step 4: step 4 is that after the workpieces have been disordered by the workpiece mixing apparatus (4), the method goes back to step 1; and after a period of continuous cycle grinding processing, a sampling inspection of the workpiece is made, and if a process requirements are met, the grinding processing ends, or otherwise, the grinding processing continues.

Description

DESCRIPTION OF THE DRAWINGS

[0018] FIG. 1 is a schematic view of an excircle surface super-finishing device for a double-disc straight groove cylindrical component;

[0019] FIG. 2 is a schematic view of a grinding disc apparatus;

[0020] FIG. 3 is a schematic view of second grinding disc having a straight groove;

[0021] FIG. 4 is a cross section view of a workpiece to be processed in the grinding disc apparatus, wherein: (a) illustrates a V-shaped cross-section outline of a working face of the straight groove of the second grinding disc; (b) illustrates an arc-shaped cross-section outline of the working face of the straight groove of the second grinding disc; and (c) illustrates a cross-section outline of a working face the second grinding disc in a V shape with an arc;

[0022] FIG. 5-1 schematically illustrates a cross section view of a feeding apparatus driven by a disc cam;

[0023] FIG. 5-2 shows a view of the disc cams in FIG. 5-1 with different lift limit, wherein: (a) illustrates is a disc cam with a single lift limit, (b) shows a disc cam with double lift limits, and (c) is a view of a disc cam with triple lift limits;

[0024] FIG. 6 is a schematic longitudinal section view of an advancing apparatus driven by a disc cam;

[0025] FIG. 7 is a schematic diagram of an advancing apparatus driven by a conical cam;

[0026] In the figures:

[0027] reference sign 1 indicates a grinding disc apparatus; reference sign 2 indicates a workpiece advancing mechanism;

[0028] reference sign 3 indicates a workpiece conveying apparatus; reference sign 4 indicates a workpiece mixing apparatus;

[0029] reference sign 5 indicates a workpiece and grinding fluid separation apparatus; reference sign 6 indicates a workpiece cleaning apparatus;

[0030] reference sign 7 indicates a loading apparatus; reference sign 8 indicates a power system;

[0031] reference sign 9 indicates a processing workpiece; reference sign 11 indicates a first grinding disc;

[0032] reference sign 111 indicates the first grinding disc's working face; reference sign 12 indicates a second grinding disc;

[0033] reference sign OO′ indicates a rotation axis of the second grinding disc relative to the first grinding disc; reference sign 121 indicates a straight groove on the second grinding disc;

[0034] reference sign 1211 indicates the second grinding disc's working face; reference sign 1212 indicates a chip-hold groove at the bottom of the straight groove of the second grinding disc;

[0035] reference sign 211 indicates a disc cam; reference sign 212 indicates a conical cam;

[0036] reference sign 22 indicates a material-pushing mechanism; reference sign 222 indicates a positioning shaft shoulder;

[0037] reference sign 223 indicates a spring; reference sign 224 indicates a push rod;

[0038] reference sign 225 indicates a through hole; reference sign 23 indicates a material storage hopper.

[0039] Reference sign/indicates the axis of the processing workpiece in the straight groove;

[0040] Reference sign Δω indicates the relative rotational speed of the second grinding disc and the first grinding disc;

[0041] reference sign ω.sub.1 indicates the spin angular velocity of processing workpiece under the processing;

[0042] reference sign α indicates a plane passing through the axis/and perpendicular to the working face of the first grinding disc;

[0043] reference sign β indicates a normal plane at an unique contacting point or a midpoint A of a contacting arc between the processing workpiece and the straight groove;

[0044] reference sign θ indicates an angle between plane α and plane β;

[0045] reference sign e indicates an eccentric distance from the plane α to the second grinding disc's rotational axis OO′ relative to the first grinding disc;

[0046] reference sign r indicates an excircle radius of the processing workpiece.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

[0047] The technical solution of the present invention will now be described in further detail with reference to the accompanying drawings and specific examples.

[0048] As shown in FIG. 1, a cylindrical-component grinding device proposed in the present invention includes a loading apparatus 7, a power system 8, and a workpiece advancing apparatus 2, a grinding disc apparatus 1, a workpiece and grinding fluid separating apparatus 5, a workpiece cleaning apparatus 6 and workpiece mixing apparatus 4, the later five apparatuses connecting with a workpiece conveying apparatus 3 in sequence. The loading apparatus 7 is configured for material loading of the grinding disc apparatus 1 and the power system 8 is configured for driving the grinding disc apparatus 1.

[0049] As shown in FIG. 2, the grinding disc apparatus 1 includes a first grinding disc 11 and a second grinding disc 12, and the second grinding disc 12 and the first grinding disc 11 rotate relative to each other. The second grinding disc 12 has a rotation axis OO′ relative to the first grinding disc 11, a surface of the first grinding disc 11, opposite to the second grinding disc 12, is planar, which is a working surface 111 of the first grinding disc 11. As shown in FIG. 3, a set of radial straight grooves 121 are provided on a surface of the second grinding disc 12 opposite to the first grinding disc 11, and a groove surface of the straight groove 121 is a working surface 1211 of the second grinding disc 12. As shown in FIG. 4, the working face 1211 of the second grinding disc 12 has a cross-section outline in an arcuate shape or a V shape or a V shape with an arc. Herein, the cross-section outline of the working face 1211 of the second grinding disc 12 shown in FIG. 4-(a) is V-shaped, the cross-section outline of the work surface 1211 of the second grinding disc 12 shown in FIG. 4-(b) is in an arcuate shape, and the cross-section outline of the working face 1211 of the second grinding disc 12 as shown in FIG. 4-(c) is a V shape with an arc. The bottom of the straight groove is provided with a chip-hold groove 212. Processing workpieces 9 are laterally disposed on the eccentric straight groove 121, to be processed in a grinding working area consisting of the working face 111 of the first grinding disc 11 and the working face 1211 of the second grinding disc 12. Under load conditions and lubrication conditions of the grinding fluid described in the present invention, the friction pair formed by the material of the working face 111 of the first grinding disc 11 and the material of the processing workpiece 9 has a friction coefficient f1 larger than a friction coefficient f2 of the friction pair formed by the material of the working face 1211 of the second grinding disc 12 and the material of the processing workpiece 9 under the same conditions.

[0050] During grinding process, the processing workpiece 9 is arranged in the straight groove 121 along a groove extending direction, meanwhile, an outer cylindrical surface of the processing workpiece 9 contacts with the working face 1211 of the second grinding disc 12, and the working face 1211 of the straight groove 121 locates the position of the excircle surface of the workpiece 9. The straight, groove 121 has a reference plane α, a plane that passes through an axis/of the processing workpiece arranged in the straight groove, and is perpendicular to the working face 111 of the first grinding disc 11. There is an angle θ between a normal plane β at a contacting point or a midpoint A of a contacting arc between the processing workpiece 9 and the straight groove 121, and the reference plane of the straight groove 121. The angle θ ranges in 30˜60°. One end, of the straight groove 121 close to the center of the second grinding disc 12 is a propulsion port of the processing workpiece, and the other end of the straight groove 121 is a discharge outlet. An eccentric distance e exists between the reference plane a of the straight groove 121 and the second grinding disc's rotation axis OO′ relative to the first grinding disc. The value of e is larger than or equal to zero, and smaller than a distance from the rotation axis OO′ to the discharge outlet of the straight groove 121. When the value of the eccentric distance e is zero, the straight groove 121 is actually arranged in a radial arrangement, and the second grinding disc 12 has a mounting portion of the workpiece advancing apparatus 2, provided at a central position thereof.

[0051] Under the conditions of the grinding pressure and grinding lubrication, the friction coefficient between the material of the first grinding disc's working face 111 and the material of the processing workpiece is f1, and the friction coefficient between the material of the second grinding disc's working face 1211 and the material of the processing workpiece is f2, and f1>f2, so as to ensure that the processing workpiece may achieve spinning in the grinding process.

[0052] The workpiece advancing apparatus 2 according to the present invention has a structure as shown in FIGS. 5-1, 5-2, 6 and 7, including a main body, wherein a plurality of material-pushing mechanisms 22 and a plurality of material storage hoppers 23 are arranged on the main body, the plurality of material-pushing mechanisms 22 are arranged along circumferential distribution, and both the number of the plurality of material-pushing mechanisms 22 and the plurality of the number of the material storage hopper 23 are the same with the number of the straight grooves 121 in the grinding disc apparatus. The material storage hopper 23 has a section dimension matching the dimension of the processing workpiece 9, and the processing requirements of the processing workpiece 9 with different diameters can be met by replacing the material storage hopper 23 with different cross-section dimensions. Each of the material-pushing mechanisms 22 respectively cooperates with one material storage hopper 23, the bottom of the material storage hopper 23 is provided with a push rod inlet 231 and a discharge port 232, the material-pushing mechanism 22 including a through hole 225 provided at the bottom of the main body. The through hole 225 is coaxial with a line connecting the center of the push rod inlet 231 and the center of the discharge port 232, the through hole 225 communicates with the push rod inlet 231, and a push rod 224 and a stopper structure of the push rod 224 are provided inside the through hole 225, The stopper structure consists of a positioning shaft shoulder 222 provided on the push rod 224, a positioning step provided in the through hole, and a spring 223 disposed on the push rod 224, the positioning shaft 222 confining the stroke of the push rod 224, the spring 223 keeping the push rod 224 contacting with the cam. There is a one-to-one correspondence between the discharge port of the material storage hopper 23 and the propulsion port of the straight groove 121, and all of the push rods 224 always contact with the same intermittent reciprocating mechanism (for example, the disc cam 211 shown in FIG. 5-1 or the conical cam 212 as shown in FIG. 7). That is to say, driven by the same intermittent reciprocating mechanism, the cam pushes all of the push rods 224 to reciprocate in the through hole 225, so as to pass the processing workpiece 9 in the material storage hopper 23 into the straight groove 121 through the discharge port 232 at the bottom of the material storage hopper 23. The processing workpieces 9 are stacked one by one in the material storage hopper 23 and the one workpiece 9 at the bottom has an axis aligned with the axis/of the processing workpiece 9 in the straight groove 121 corresponding to the material storage hopper 23. When grinding is continued, the workpiece conveying apparatus 3 conveys the processing workpiece 9 to the workpiece advancing mechanism 2, and the workpiece 9 is then stored in the material storage hopper 23.

[0053] The workpiece conveying apparatus 3 according to the present invention employs a common vibration feeding mechanism and a screw feeding mechanism on the market, which function to realize a continuous feeding of the processing workpiece 9, The workpiece mixing apparatus 4 according to the present invention adopts a common cylindrical workpiece mixing mechanism on the market, for achieving disordering the sequence of the workpiece and improving the randomness of the processing. The workpiece and grinding fluid separating apparatus 5 of the present invention is provided with a precipitation tank, a grinding fluid delivery pipe and a grinding fluid separation apparatus, for conveying the grinding fluid to the device, collecting the used grinding fluid, and for separating the grinding debris and grinding fluid after precipitation and filtration, thus to achieve a recycling of grinding fluid. The workpiece cleaning apparatus 6 of the present invention employs a common workpiece cleaning apparatus on the market, for cleaning the primarily grinded workpiece with a cleaning liquid and for recovering the cleaning liquid. In order to prevent environment pollution, the wastewater produced by cleaning of rollers firstly flows into the precipitation tank to precipitate through the pipe, and precipitated wastewater enters the grinding fluid separation apparatus for a centrifugal separation and filtration. Separated cleaning liquid then returns to the roller cleaning apparatus and gets a reuse.

[0054] The intermittent reciprocating mechanism in the device of the present invention is driven by a disc cam mechanism or a conical cam mechanism, and in order to complete a function of intermittent reciprocating, the workpiece advancing mechanism 2 can adopt a structure in a variety of solutions: a first embodiment is shown in FIGS. 5-1, 5-2 and 6, wherein, (a), (b) and (c) in FIG. 5-2 show a structure of a disc cam with a single, a double and a triple lift limits, respectively, and a multi-lift-limit disc cam 211 can be used to achieve an intermittent reciprocation, with an operation process that a multi-lift-limit disc cam 211 is used to connect to the first grinding disc 11, the push rod 224 connects to the second grinding disc 12, and by virtue of a rotation speed difference between the two grinding discs, the push rod 224 is driven to advance the processing workpiece 9 into the straight groove 121 via the change in the lift distance of the disc cam 211.

[0055] Embodiment 2 is shown in FIG. 7, in this case, the intermittent reciprocating mechanism is driven by the conical cam 212, with an operation process that the conical cam 212 reciprocates linearly under the drive of an external power source, so as to further drive the push rod 224 to advance the processing workpiece 9 into the straight groove 121. Both the embodiment 1 and the embodiment 2 can be adapted to meet the needs of the processing workpiece in different dimensions by changing the cross-section dimension of the cam and by changing the cross-section dimension of the material storage hopper 23, thus involving a strong applicability.

[0056] To realize grinding on cylindrical components by virtue of the cylindrical-component grinding device of the present invention, following steps are included.

[0057] Step 1 is workpiece feeding. Herein, the workpiece conveying apparatus 3 feeds the processing workpiece into the material storage hopper 23 of the workpiece advancing apparatus 2, and under the drive of the intermittent reciprocating mechanism, the push rod 224 pushes the processing workpiece 9 in the material storage hopper 23 from the bottom of the material storage hopper to the straight groove 121, until all the straight grooves are fulfilled with the processing workpiece 9.

[0058] Step 2 is grinding processing. Herein, the loading apparatus 7 provides loading for the grinding disc apparatus 1, the workpiece 9 contacts with the first grinding disc's working face 111 and the second grinding disc's working face 1211; the power system 8 drives the grinding disc apparatus 1, the second grinding disc 12 rotates relative to the first grinding disc 11, the processing workpiece 9 is processed in the grinding working area formed by the working face 111 of the first grinding disc 11 and the working face 1211 of the second grinding disc 12. Under the conditions of the grinding pressure and grinding lubrication, the friction coefficient f1 between the material of the first grinding disc's working face 111 and the material of the processing workpiece is larger than the friction coefficient f2 between the material of the second grinding disc's working face 1211 and the material of the processing workpiece, so with the joint cooperation of the first grinding disc 11 and the second grinding disc 12, the processing workpiece may spinning along its axis, and at the same time, the advancing apparatus 2 keeps pushing the processing workpiece 9 into the straight groove 121. Pushed by following processing workpieces 9, the processing workpiece 9 in the straight groove 121 performs translational slide motion from the propulsion port of the straight groove 121 towards the discharge outlet. During the above-described motion, the contacting region between the working face of the grinding disk apparatus 1 and an outer cylindrical surface of the processing workpiece 9, under the effect of free grinding particles in the grinding fluid, may realize a micro material removal of the processing workpiece 9, until the processing workpiece 9 has been discharged from the discharge outlet of the straight groove 121.

[0059] During the grinding process, plenty of processing workpieces 9 distributed in the plurality of straight grooves 121 at the same time are simultaneously engaged in the grinding process, and the combination of the processing workpieces 9 at the same time is highly random, the load endured by the processing workpiece 9 with a larger diameter is greater than that of the processing workpiece 9 with a smaller diameter, thus facilitating a large material removal on excircle surfaces of the processing workpiece 9 in a larger diameter, as well as a small material removal on excircle surfaces of the processing workpiece 9 in a smaller diameter, further to improve the processing efficiency, and dimensional accuracy and consistency of excircle surfaces of the processing workpiece 9.

[0060] Step 3 is workpiece cleaning. Herein, the workpiece and grinding fluid separating apparatus 5 separates the workpiece grinded in step 2 from the grinding fluid, and after filtration and precipitation, the grinding fluid is then in reuse. After the workpiece is cleaned by the workpiece cleaning apparatus 6, the process goes on to step 4.

[0061] Step 4 is that after the workpieces have been disordered by the workpiece mixing apparatus 4, the process goes back to step 1;

[0062] After a period of continuous cycle grinding processing, a sampling inspection of the workpiece is made, and if the result meets the process requirements, the grinding processing ends, or otherwise, the grinding processing continues.

[0063] With the grinding method of the present invention, plenty of the processing workpieces 9 distributed in the straight groove 121 at the same time are engaged in the grinding process and the combination of the processing workpieces 9 at the same time is highly random, the load endured by the processing workpiece 9 with a larger diameter is greater than that of the processing workpiece 9 with a smaller diameter, thus facilitating a large material removal on excircle surfaces of the processing workpiece 9 in a larger diameter, as well as a small material removal on excircle surfaces of the processing workpiece 9 in a smaller diameter, further to improve the dimensional consistency of cylindrical surfaces of the processing workpiece 9. A large removal of the material at a high position and a larger material removal of the processing workpiece 9 in a larger diameter, contribute to the improvement of processing efficiency on cylindrical surface of the processing workpiece 9.

[0064] Though the invention has been described above with reference to the accompanying drawings, the invention shall not be limited to the specific embodiments described above, and the specific embodiments described above are merely illustrative and not restrictive, and for one of ordinary skill in the art, under the inspiration of the present invention, many modifications may be made without departing from the spirit of the invention, which shall fall into the protection scope of the present invention.

CYLINDRICAL-COMPONENT GRINDING DEVICE, AND WORKPIECE ADVANCING APPARATUS AND GRINDING METHOD THEREOF

Assignee

Inventors

Cpc classification

Classification Explorer

B24B37/345

PERFORMING OPERATIONS; TRANSPORTING

Classification Explorer

B24B37/26

PERFORMING OPERATIONS; TRANSPORTING

Classification Explorer

B24B37/08

PERFORMING OPERATIONS; TRANSPORTING

Classification Explorer

B24B37/02

PERFORMING OPERATIONS; TRANSPORTING

Classification Explorer

B24B37/04

PERFORMING OPERATIONS; TRANSPORTING

Classification Explorer

B24B37/16

PERFORMING OPERATIONS; TRANSPORTING

Classification Explorer

B24B37/025

PERFORMING OPERATIONS; TRANSPORTING

Classification Explorer

B24B37/022

PERFORMING OPERATIONS; TRANSPORTING

International classification

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B24B37/02

PERFORMING OPERATIONS; TRANSPORTING

Classification Explorer

B24B37/025

PERFORMING OPERATIONS; TRANSPORTING

Classification Explorer

B24B37/04

PERFORMING OPERATIONS; TRANSPORTING

Classification Explorer

B24B37/26

PERFORMING OPERATIONS; TRANSPORTING

Classification Explorer

B24B37/16

PERFORMING OPERATIONS; TRANSPORTING

Classification Explorer

B24B37/08

PERFORMING OPERATIONS; TRANSPORTING

Classification Explorer

B24B37/34

PERFORMING OPERATIONS; TRANSPORTING

Abstract

Claims

Description