JP2020131346A - Honing processing machine - Google Patents

Abstract

To restrict a decrease in accuracy in a honing process.SOLUTION: A tool body (21) is formed in a cylindrical shape, and a through-hole (21a) is provided in a peripheral wall portion. A honing grindstone (22) is disposed in the through-hole (21a) of the tool body (21) and is capable of radially advancing/retreating. A rod (23) is formed in a rod shape, disposed in the tool body (21), and axially moved to radially advance/retreat the honing grindstone (22). A plurality of actuators (40) are fixed in the tool body (21) by their being arranged so as to surround the periphery of the rod (23), and each of these actuators presses the rod (23) in the direction of the rotation axis (R) of a honing tool (20).SELECTED DRAWING: Figure 4

Description

The present invention relates to a honing machine.

Conventionally, a honing machine for grinding the inner peripheral surface of a hole to be machined of a work has been known. For example, Patent Document 1 discloses a honing tool attached to the tip of a rotating spindle of a honing disc. This honing tool reciprocates in the hollow cylindrical hole of the tool body in the axial direction with a hollow cylindrical tool body, a honing wheel that is held so that it can protrude and retract in the radial direction in the grindstone holding opening opened in the tool body. It is equipped with a rod-shaped expansion rod that is movable and allows the honing wheel to project and expand. The tool body is formed by machining a hollow metal pipe having a diameter smaller than the inner diameter of a hole to be machined, which has a small diameter of the workpiece to be machined, into a predetermined structure.

Japanese Unexamined Patent Publication No. 2006-346837

However, in a honing machine as in Patent Document 1, the rod may be deformed in the radial direction due to insufficient rigidity of the rod, and as a result, the posture of the honing grindstone may be displaced. If the posture of the honing grindstone is deviated in this way, it becomes difficult to properly bring the honing grindstone into contact with the inner peripheral surface of the hole to be machined of the work, and the accuracy of honing machining is lowered.

Therefore, an object of the present invention is to provide a honing processing machine capable of suppressing a decrease in accuracy of honing processing.

The first invention relates to a honing machine, and is a tool body formed in a tubular shape and provided with a through hole in a peripheral wall portion, and a honing that is arranged in the through hole of the tool body and can advance and retreat in the radial direction. It has a grindstone and a rod formed in a rod shape and arranged inside the tool body to move the honing grindstone in the radial direction by moving in the axial direction, and the honing grindstone is advanced from the tool body to work. A honing tool that grinds the inner peripheral surface of the workpiece hole of the workpiece by rotating around a rotation axis extending in the axial direction while in contact with the inner peripheral surface of the workpiece hole, and the periphery of the rod. It is provided with a plurality of actuators arranged so as to surround the tool body and fixed to the inside of the tool body, each of which presses the rod in a direction toward the rotation axis of the honing tool.

In the first invention, deformation of the rod in the radial direction can be suppressed by pressing the rod in a direction toward the rotation axis of the honing tool by a plurality of actuators arranged so as to surround the rod. As a result, the rod can be held by the pressing force of the plurality of actuators, so that the deviation of the posture of the honing grindstone can be suppressed, and thus the deterioration of the accuracy of the honing process can be suppressed.

In the second invention, in the first invention, a plurality of load sensors for detecting the pressing force of the plurality of actuators acting on the rod, and the plurality of actuators according to the detection results of the plurality of load sensors. It is a honing machine characterized by having a control unit for controlling.

In the second invention, by controlling a plurality of actuators according to the detection results of the plurality of load sensors, the pressing force of the plurality of actuators is adjusted according to the fluctuation of the pressing force of the plurality of actuators acting on the rod. Can be done. As a result, the balance of the pressing force of the plurality of actuators can be appropriately maintained, so that the rod can be appropriately held by the pressing force of the plurality of actuators, and the deformation of the rod in the radial direction is appropriately suppressed. be able to.

According to a third aspect of the present invention, in the second invention, the control unit has the plurality of actuators acting on the rod according to the detection results of the plurality of load sensors so that the pressing forces of the plurality of actuators are in an equilibrium state. It is a honing machine characterized by adjusting the pressing force of an actuator.

In the third invention, by balancing the pressing forces of the plurality of actuators acting on the rod, the pressing forces of the plurality of actuators act imbalanced on the rod and the rod is deformed in the radial direction. It is possible to make it difficult for such a situation to occur. As a result, the deviation of the posture of the honing grindstone can be suppressed, and the deterioration of the accuracy of the honing process can be suppressed.

The fourth invention includes, in the second or third invention, a plurality of relay portions, a plurality of first conductors, and a plurality of second conductors, and a plurality of conductor insertion holes are provided in the peripheral wall portion of the tool body. The plurality of load sensors are provided on the outer periphery of the rod, and each of the plurality of relay portions has an insulating property and rotates an insulating ring provided on the outer periphery of the tool body and the insulating ring. It has bearings that can support it, and the plurality of first conductors are inserted into the plurality of wire insertion holes of the tool body, and the plurality of load sensors and the bearings of the plurality of relay portions are connected to each other. Each of the plurality of second conducting wires is electrically connected, and the plurality of second conducting wires are honing machines characterized in that the bearings of the plurality of relay units and the control unit are electrically connected to each other.

In the fourth invention, by providing an insulating ring between the tool body and the bearing of the relay portion, a short circuit between the tool body and the bearing of the relay portion is prevented, and the first lead wire, the bearing, and the second from the load sensor are provided. The detection result of the load sensor can be transmitted to the control unit via the lead wire in order. As a result, the detection results of a plurality of load sensors can be transmitted to the control unit even while the honing tool is rotating, so that a plurality of actuators can be controlled according to the detection results of the plurality of load sensors even while the honing tool is rotating. can do.

According to a fifth aspect of the present invention, in any one of the first to fourth inventions, one of the plurality of actuators sandwiches the rod with the honing grindstone when viewed from the axial direction. It is a honing machine characterized by facing each other.

In the fifth invention, by arranging the actuator so as to face the honing grindstone with the rod sandwiched between them, the reaction force of the work acting on the honing grindstone during the honing processing operation (that is, the honing grindstone is retracted in the radial direction). The pressing force of the actuator can be applied to the rod in a direction that opposes the reaction force acting in the direction. As a result, deformation in the radial direction of the rod due to the reaction force of the work acting on the honing grindstone can be effectively suppressed.

The sixth invention includes, in any one of the first to fifth inventions, a drive mechanism for moving the rod in the axial direction, and the rod is directed from a side closer to the drive mechanism to a side farther from the drive mechanism. It has a first rod portion, a second rod portion, and a third rod portion arranged in order, the first rod portion is connected to the drive mechanism, and the second rod portion is far from the side close to the drive mechanism. It is formed in a conical shape that gradually becomes thinner toward the side, and when the rod moves in the direction from the side closer to the drive mechanism to the side farther away, it comes into contact with the honing grindstone and advances the honing grindstone in the radial direction. The plurality of actuators are honing machines characterized in that they are arranged so as to surround the periphery of the third rod portion.

In the sixth invention, by arranging a plurality of actuators so as to surround the circumference of the third rod portion, the third rod which is easily deformed in the radial direction among the first rod portion, the second rod portion and the third rod portion. The pressing force of a plurality of actuators can be applied to the portion. As a result, deformation of the rod in the radial direction can be effectively suppressed.

A seventh aspect of the present invention is, in any one of the first to sixth aspects, an auxiliary member provided with an opening into which the tool body is inserted, and an auxiliary member arranged so as to surround the tool body. The honing machine is characterized in that it is fixed inside an opening of an auxiliary member and each includes a plurality of auxiliary actuators that press the tool body in a direction toward the rotation axis of the honing tool.

In the seventh invention, a plurality of auxiliary actuators arranged so as to surround the tool body press the tool body in the direction toward the rotation axis of the honing tool, thereby holding the tool body by the pressing force of the auxiliary actuator. Therefore, it is possible to suppress the deviation of the radial position of the tool body. As a result, it is possible to prevent a situation in which the contact state between the honing grindstone and the inner peripheral surface of the work hole of the work is changed due to the deviation of the radial position of the tool body, so that the accuracy of honing processing can be improved. The decrease can be suppressed.

The eighth invention relates to a honing machine, and the tool body is formed in a tubular shape and has a through hole in a peripheral wall portion, and a honing that is arranged in the through hole of the tool body and can advance and retreat in the radial direction. It has a grindstone and a rod formed in a rod shape and arranged inside the tool body to move the honing grindstone in the radial direction by moving in the axial direction, and the honing grindstone is advanced from the tool body to work. The honing tool for grinding the inner peripheral surface of the hole to be machined and the tool body by rotating around the rotation axis extending in the axial direction in contact with the inner peripheral surface of the hole to be machined. An auxiliary member provided with an opening to be inserted and an auxiliary member arranged so as to surround the tool body and fixed inside the opening of the auxiliary member, respectively, in a direction toward the rotation axis of the honing tool. It is equipped with multiple auxiliary actuators that press the tool body.

In the eighth invention, a plurality of auxiliary actuators arranged so as to surround the tool body press the tool body in the direction toward the rotation axis of the honing tool, thereby holding the tool body by the pressing force of the auxiliary actuator. Therefore, it is possible to suppress the deviation of the radial position of the tool body. As a result, it is possible to prevent a situation in which the contact state between the honing grindstone and the inner peripheral surface of the work hole of the work is changed due to the deviation of the radial position of the tool body, so that the accuracy of honing processing can be improved. The decrease can be suppressed.

According to the present invention, it is possible to suppress a decrease in the accuracy of honing processing.

It is a perspective view which illustrates the structure of the honing processing machine by embodiment. It is a vertical cross-sectional view which illustrates the structure of the honing processing machine by embodiment. It is sectional drawing which illustrates the structure of the honing tool. It is sectional drawing which illustrates the structure of the actuator and the load sensor. It is sectional drawing which illustrates the structure of the auxiliary actuator and the auxiliary load sensor. It is sectional drawing which illustrates the structure of the honing processing machine. It is sectional drawing which illustrates the structure of the main part of a honing machine.

Hereinafter, embodiments will be described in detail with reference to the drawings. The same or corresponding parts in the drawings are designated by the same reference numerals, and the description thereof will not be repeated.

(Honing processing machine)
1 to 6 illustrate the configuration of the honing machine 10 according to the embodiment. 3, FIG. 4 and FIG. 5 are cross-sectional views taken along the line III-III, IV-IV, and VV of FIG. 2, respectively. Further, in FIG. 6, hatching attached to the cross section of the member is omitted.

The honing machine 10 is a device for grinding the inner peripheral surface of a hole to be machined of a work (not shown), and includes a honing tool 20, an auxiliary member 25, a drive mechanism 30, and a control unit 100. .. The work is supported in a floating state by a work holding jig (not shown) so that the honing tool 20 and the work are centered. This work holding jig may be composed of a known work holding jig.

Further, in the following description, the "axial direction" is the direction of the rotation axis R of the honing tool 20, and the "radial direction" is the direction orthogonal to the direction of the rotation axis R of the honing tool 20. The "circumferential direction" is the direction around the rotation axis R of the honing tool 20. In this example, the rotation axis R of the honing tool 20 extends in the vertical direction.

[Honing tool]
The honing tool 20 is formed in a rod shape, and one end (base end) thereof is connected to the drive mechanism 30. The honing tool 20 has a tool body 21, one or more honing grindstones 22, a rod 23, and a plurality of urging members 24. In this example, three honing grindstones 22 are provided, and two urging members 24 (six urging members 24 in total) are provided for each of the three honing grindstones 22.

<Tool body>
The tool body 21 is formed in a tubular shape. One or more through holes 21a are provided in the peripheral wall portion of the tool body 21. The through hole 21a penetrates the peripheral wall portion of the tool body 21 in the radial direction.

In this example, the inner peripheral surface of the tool body 21 is a cylindrical surface. The axis of the tool body 21 is coaxial with the rotation axis R of the honing tool 20. Further, the tool body 21 is provided with three through holes 21a corresponding to the three honing grindstones 22 respectively. The three through holes 21a are arranged at equal intervals in the circumferential direction of the honing tool 20. The cross-sectional shape of the through hole 21a in the penetrating direction (that is, the radial direction) corresponds to the cross-sectional shape of the honing grindstone 22 in the radial direction. Due to such a shape, the through hole 21a holds the honing grindstone 22 so as to be able to advance and retreat in the radial direction.

<Honing whetstone>
The honing grindstone 22 is arranged in the through hole 21a of the tool body 21 and can move forward and backward in the radial direction. In this example, three honing grindstones 22 are arranged in the three through holes 21a of the tool body 21.

Further, in this example, the honing grindstone 22 has a mounting portion 22a and a grindstone portion 22b. The mounting portion 22a has a main body portion formed in a square columnar shape extending in the axial direction, and a protruding portion that protrudes inward in the radial direction from the main body portion and comes into contact with the rod 23. The contact surface of the protruding portion of the mounting portion 22a with the rod 23 is an inclined surface that inclines from the outside to the inside in the radial direction from the side closer to the drive mechanism 30 toward the far side. The grindstone portion 22b is formed in a square columnar shape extending in the axial direction, and is provided on the outer side in the radial direction of the main body portion of the mounting portion 22a.

<rod>
The rod 23 is formed in a rod shape and is arranged inside the tool body 21. Then, the rod 23 moves one or more (three in this example) honing grindstones 22 in the radial direction by moving in the axial direction. In this example, the cross-sectional shape of the rod 23 is formed in a circular shape.

Further, in this example, the rod 23 has a first rod portion 23a, a second rod portion 23b, and a third rod portion 23c. The first rod portion 23a, the second rod portion 23b, and the third rod portion 23c are arranged in this order from the side closer to the drive mechanism 30 to the side farther from it.

The first rod portion 23a is formed in a columnar shape. The first rod portion 23a is connected to the drive mechanism 30.

The second rod portion 23b is formed in a conical shape that gradually becomes thinner from the side closer to the drive mechanism 30 toward the far side. Then, the second rod portion 23b comes into contact with one or a plurality of honing grindstones 22 when the rod 23 moves in the direction from the side closer to the drive mechanism 30 to the side farther away, and brings the one or more honing grindstones 22 together. Advance in the radial direction. In this example, the second rod portion 23b is in contact with the contact surfaces of the three honing grindstones 22 (specifically, the contact surfaces of the protruding portions of the mounting portions 22a).

The third rod portion 23c is formed in a columnar shape. The third rod portion 23c constitutes the tip portion of the rod 23. In this example, the cross-sectional shape of the third rod portion 23c is larger than the cross-sectional shape of the tip portion of the second rod portion 23b.

<Bending member>
The plurality of urging members 24 are provided to urge one or more honing grindstones 22 in a direction toward the rotation axis R of the honing tool 20. In this example, two urging members 24 are provided at both ends in the axial direction of one honing wheel 22. The urging member 24 is, for example, a leaf spring.

<Advance and retreat of honing whetstone in honing tool>
In the honing tool 20, when the rod 23 moves in the axial direction from the side closer to the drive mechanism 30 to the side farther from the drive mechanism 30, the second rod portion 23b of the rod 23 pushes the honing grindstone 22 outward in the radial direction. As a result, the honing grindstone 22 advances in the radial direction, and the amount of advance of the honing grindstone 22 increases. On the other hand, when the rod 23 moves in the axial direction from the far side to the near side from the drive mechanism 30, the urging member 24 pushes the honing grindstone 22 inward in the radial direction. As a result, the honing grindstone 22 retracts in the radial direction, and the amount of advance of the honing grindstone 22 decreases.

<Operation of honing tool>
In the honing operation for grinding the inner peripheral surface of the hole to be machined of the work (not shown), the honing tool 20 is first inserted into the hole to be machined of the work. After that, the honing tool 20 advances one or more (three in this example) honing grindstones 22 from the tool body 21. Then, the honing tool 20 has a rotation axis R extending in the axial direction of the honing tool 20 in a state where one or a plurality of honing grindstones 22 are advanced from the tool body 21 and are in contact with the inner peripheral surface of the hole to be machined of the work. The inner peripheral surface of the work hole to be machined is ground by rotating around.

<Deformation in the radial direction of the rod>
In the honing tool 20, the rod 23 may be deformed in the radial direction due to insufficient rigidity of the rod 23, and as a result, the posture of the honing grindstone 22 may be displaced. For example, the honing grindstone 22 is displaced or tilted. In particular, in this example, since the second rod portion 23b of the rod 23 is formed in a conical shape, the third rod portion 23c located on the tip end side of the second rod portion 23b of the rod 23 is easily deformed in the radial direction. It has become. If the posture of the honing grindstone 22 deviates in this way, it becomes difficult to properly bring the honing grindstone 22 into contact with the inner peripheral surface of the hole to be machined (not shown), and the accuracy of honing machining deteriorates. Whetstone. Further, due to the deviation of the posture of the honing grindstone 22, sliding failure between the honing grindstone 22 and the rod 23, detachment of the honing grindstone 22 from the through hole 21a of the tool body 21 and the like occur.

[Auxiliary member]
The auxiliary member 25 rotatably and auxiliaryly holds the tip of the tool body 21 of the honing tool 20. In this example, the auxiliary member 25 is formed in a thick plate shape. Further, the auxiliary member 25 is provided with an opening 25a. The tool body 21 is inserted into the opening 25a. In this example, the inner peripheral surface of the opening 25a is a cylindrical surface. The axis of the opening 25a is coaxial with the rotation axis R of the honing tool 20.

[Drive mechanism]
The drive mechanism 30 drives the honing tool 20. In this example, the drive mechanism 30 has a rotary spindle, a spindle rotation drive unit, a spindle reciprocating drive unit, and a grindstone drive unit. The rotation spindle can rotate around a rotation axis extending in the axial direction, and can reciprocate in the direction of the rotation axis. Then, the honing tool 20 is attached to the rotating spindle. The rotation axis R of the honing tool 20 is coaxial with the rotation axis of the rotation spindle. The spindle rotation drive unit rotates the rotation spindle around the rotation axis. The spindle reciprocating drive unit reciprocates the rotating spindle in the direction of the rotating axis. The grindstone driving unit moves the rod 23 of the honing tool 20 in the axial direction. The drive mechanism 30 may be configured by a known drive mechanism.

[Control unit]
The control unit 100 is electrically connected to each part of the honing machine 10 (for example, the drive mechanism 30) and can transmit an electric signal between each part of the honing machine 10. Then, the control unit 100 controls each part of the honing machine 10 based on the signal from each part of the honing machine 10 and the signal from the outside of the honing machine 10. For example, the control unit 100 is composed of a processor, a memory for storing programs and information for operating the processor, and the like.

[Actuator and load sensor]
As shown in FIGS. 2 to 4, the honing machine 10 includes a plurality of actuators 40 and a plurality of load sensors 50. The control unit 100 is electrically connected to a plurality of actuators 40 and a plurality of load sensors 50, and can transmit an electric signal between them.

<Actuator>
The plurality of actuators 40 are arranged so as to surround the rod 23 and are fixed to the inside of the tool body 21. Then, each of the actuators 40 presses the rod 23 in the direction toward the rotation axis R of the honing tool 20. The pressing force of the actuator 40 against the rod 23 can be controlled. Further, one of the plurality of actuators 40, the actuator 40, faces the honing grindstone 22 with the rod 23 sandwiched between them when viewed from the axial direction of the honing tool 20.

In this example, three actuators 40 are provided. The three actuators 40 are arranged at equal intervals in the circumferential direction of the honing tool 20. Further, the three actuators 40 are arranged so as to face each of the three honing grindstones 22 with the rod 23 sandwiched between them when viewed from the axial direction of the honing tool 20.

Specifically, in this example, the actuator 40 has an air bag 41, an air passage 42, and an air supply unit 43. The air bag 41 is made of a stretchable material (for example, rubber) and is configured to expand or contract according to the amount of air stored therein. Further, the air bag 41 is fixed to the inner peripheral surface of the tool body 21. Then, the air bag 41 expands and comes into contact with the rod 23 to push the rod 23 toward the rotation axis R of the honing tool 20. As the amount of air stored in the air bag 41 increases, the pressing force of the air bag 41 against the rod 23 increases. The air passage 42 is a passage that connects the air bag 41 and the air supply unit 43, and is provided on the peripheral wall portion of the tool body 21. The air supply unit 43 selectively performs a supply operation of supplying air to the air bag 41 and a discharge operation of discharging air from the air bag 41. For example, the air supply unit 43 is an air pump.

When air is supplied from the air supply unit 43 to the air bag 41 through the air passage 42, the amount of air stored in the air bag 41 increases, and the pressing force of the air bag 41 against the rod 23 increases. On the other hand, when air is discharged from the air bag 41 to the air supply unit 43 through the air passage 42, the amount of air stored in the air bag 41 is reduced, and the pressing force of the air bag 41 against the rod 23 is reduced.

<Load sensor>
The plurality of load sensors 50 each detect the pressing force of the plurality of actuators 40 acting on the rod 23. Specifically, the load sensor 50 outputs an electric signal corresponding to the pressing force of the actuator 40 acting on the rod 23. For example, the load sensor 50 is a strain gauge. The detection results (electric signals) of the plurality of load sensors 50 are transmitted to the control unit 100.

In this example, three load sensors 50 corresponding to each of the three actuators 40 are provided. The three load sensors 50 are provided on the outer periphery of the rod 23. Then, the three load sensors 50 are arranged at equal intervals in the circumferential direction so as to face each of the three actuators 40 in the radial direction, and each of them comes into contact with the pressing portion (specifically, the air bag 41) of the actuator 40. ..

[Relay section, 1st lead wire, 2nd lead wire and lead wire insertion hole]
As shown in FIGS. 1 and 6, the honing machine 10 includes a plurality of relay units 60, a plurality of first conductors 71, and a plurality of second conductors 72. Further, a plurality of lead wire insertion holes 21b are provided in the peripheral wall portion of the tool body 21.

<Relay section>
The plurality of relay units 60 correspond to the plurality of load sensors 50, respectively. In this example, three relay units 60 corresponding to each of the three load sensors 50 are provided. The three relay units 60 are arranged side by side in the axial direction of the honing tool 20. Further, as shown in FIG. 7, each of the plurality of relay portions 60 has a support base 61, an insulating ring 62, and a bearing 63.

《Support stand》
The support base 61 is formed in the shape of a thick plate. An opening into which the tool body 21 is inserted is formed in the central portion of the support base 61. In this example, the support base 61 is provided with a hollow portion 61a through which the second lead wire 72 is inserted.

《Insulation ring》
The insulating ring 62 has an insulating property and is provided on the outer periphery of the tool body 21. In this example, the insulating ring 62 is made of a material having an insulating property (for example, rubber) and is formed in a cylindrical shape. Then, the tool body 21 is fitted into the insulating ring 62.

"bearing"
The bearing 63 rotatably supports the insulating ring 62. Further, the bearing 63 has conductivity. In this example, the bearing 63 is provided in the opening of the support 61. Further, the bearing 63 has an inner cylinder portion 63a, an outer cylinder portion 63b, and a plurality of rolling portions 63c. The inner cylinder portion 63a, the outer cylinder portion 63b, and the plurality of rolling portions 63c are made of a conductive metal. The inner cylinder portion 63a is formed in a cylindrical shape and is provided on the outer periphery of the insulating ring 62. The outer cylinder portion 63b is formed in a cylindrical shape and is provided on the outer periphery of the inner cylinder portion 63a at a predetermined distance from the inner cylinder portion 63a. The plurality of rolling portions 63c roll between the inner cylinder portion 63a and the outer cylinder portion 63b.

<lead wire insertion hole>
The plurality of lead wire insertion holes 21b correspond to the plurality of load sensors 50, respectively. Each of the plurality of lead wire insertion holes 21b penetrates the peripheral wall portion of the tool body 21 in the radial direction. In this example, the tool body 21 is provided with three lead wire insertion holes 21b corresponding to the three load sensors 50, respectively. The three lead wire insertion holes 21b are arranged side by side at predetermined intervals in the axial direction of the honing tool 20. In addition, in FIGS. 6 and 7, one of the three lead wire insertion holes 21b is shown, and the remaining two lead wire insertion holes 21b are omitted. Specifically, assuming that the side of the honing tool 20 near the drive mechanism 30 is the base end side and the side far from the drive mechanism 30 is the tip side, the first lead wire insertion hole 21b (counting from the tip side of the honing tool 20) ( 6 and 7) are located closer to the tip of the honing tool 20 than the support 61 of the first relay portion 60 counting from the tip of the honing tool 20, and the second lead wire insertion hole 21b (see FIG. 7). (Not shown) is located between the support 61 of the first relay unit 60 and the support 61 of the second relay unit 60, and the third lead wire insertion hole 21b (not shown) is. , Is located between the support 61 of the second relay unit 60 and the support 61 of the third relay unit 60.

<1st lead wire>
The plurality of first lead wires 71 correspond to the plurality of load sensors 50, respectively. Then, the plurality of first lead wires 71 are electrically connected to the plurality of load sensors 50 and the bearings 63 of the plurality of relay portions 60, respectively, in a state of being inserted into the plurality of lead wire insertion holes 21b of the tool body 21. ing. As shown in FIG. 3, in this example, three first lead wires 71 corresponding to the three load sensors 50 are provided. The three first lead wires 71 are electrically connected to the three load sensors 50 and the inner cylinder portion 63a of the bearing 63 of the three relay portions 60, respectively, in a state of being inserted into the three lead wire insertion holes 21b. are doing. In this example, the first lead wire 71 is covered with an insulating film.

<Second lead wire>
The plurality of second conductors 72 correspond to the plurality of relay units 60, respectively. The plurality of second conducting wires 72 electrically connect the bearings 63 of the plurality of relay units 60 and the control unit 100, respectively. As shown in FIG. 6, in this example, three second conductors 72 corresponding to each of the three relay units 60 are provided. The three second conductors 72 electrically connect the outer cylinder portion 63b of the bearing 63 of the three relay portions 60 and the control unit 100, respectively. In this example, the second lead wire 72 is covered with an insulating film.

[Auxiliary actuator and auxiliary load sensor]
Further, as shown in FIGS. 2 to 5, the honing machine 10 includes a plurality of auxiliary actuators 80 and a plurality of auxiliary load sensors 90. The control unit 100 is electrically connected to a plurality of auxiliary actuators 80 and a plurality of auxiliary load sensors 90, and can transmit an electric signal between them.

<Auxiliary actuator>
The plurality of auxiliary actuators 80 are arranged so as to surround the tool body 21 and are fixed to the inside of the opening 25a of the auxiliary member 25. Then, each of the plurality of auxiliary actuators 80 presses the tool body 21 in the direction toward the rotation axis R of the honing tool 20. The pressing force of the auxiliary actuator 80 against the tool body 21 can be controlled.

In this example, three auxiliary actuators 80 are provided. The three auxiliary actuators 80 are arranged at equal intervals in the circumferential direction of the honing tool 20.

Specifically, in this example, the auxiliary actuator 80 has an auxiliary air bag 81, an auxiliary air passage 82, and an auxiliary air supply unit 83. The configuration of the auxiliary air bag 81, the auxiliary air passage 82, and the auxiliary air supply unit 83 is the same as the configuration of the air bag 41, the air passage 42, and the air supply unit 43.

When air is supplied from the auxiliary air supply unit 83 to the auxiliary air bag 81 through the auxiliary air passage 82, the amount of air stored in the auxiliary air bag 81 increases, and the pressing force of the auxiliary air bag 81 against the tool body 21 becomes large. Become. On the other hand, when air is discharged from the auxiliary air bag 81 to the auxiliary air supply unit 83 through the auxiliary air passage 82, the amount of air stored in the auxiliary air bag 81 is reduced, and the pressing force of the auxiliary air bag 81 against the tool body 21 is reduced. Becomes smaller.

<Auxiliary load sensor>
The plurality of auxiliary load sensors 90 each detect the pressing force of the plurality of auxiliary actuators 80 acting on the tool body 21. Specifically, the auxiliary load sensor 90 outputs an electric signal corresponding to the pressing force of the auxiliary actuator 80 acting on the tool body 21. For example, the auxiliary load sensor 90 is a strain gauge. The detection results (electric signals) of the plurality of auxiliary load sensors 90 are transmitted to the control unit 100.

In this example, three auxiliary load sensors 90 corresponding to each of the three auxiliary actuators 80 are provided. The three auxiliary load sensors 90 are provided on the outer periphery of the tool body 21. The three auxiliary load sensors 90 are arranged at equal intervals in the circumferential direction so as to face each of the three auxiliary actuators 80 in the radial direction, and each of them is a pressing portion of the auxiliary actuator 80 (specifically, the auxiliary air bag 81). ).

[Attitude control by control unit]
Further, in this example, the control unit 100 performs rod attitude control, which is an operation for controlling the posture of the rod 23, and tool body attitude control, which is an operation for controlling the posture of the tool body 21.

[Rod attitude control]
In the rod attitude control, the control unit 100 controls a plurality of actuators 40 according to the detection results of the plurality of load sensors 50. Specifically, the control unit 100 adjusts the pressing force of the plurality of actuators 40 according to the detection results of the plurality of load sensors 50 so that the pressing forces of the plurality of actuators 40 acting on the rod 23 are in an equilibrium state. To do. In this equilibrium state, the pressing forces of the plurality of actuators 40 can be regarded as substantially equal, and specifically, the variation in the pressing forces of the plurality of actuators 40 is within a predetermined allowable range. It is a state that fits in. In this example, the control unit 100 responds to the detection results of the plurality of load sensors 50 so that each of the pressing forces of the plurality of actuators 40 detected by the plurality of load sensors 50 becomes a predetermined target pressing force. Control each of the plurality of actuators 40.

In the rod attitude control, the imbalance of the pressing force of the plurality of actuators 40 is mainly due to the shape error of the component parts of the honing tool 20 and the variation in the sharpness of the honing grindstone 22 during the rotation of the honing tool 20. It has become. These factors do not fluctuate abruptly during honing operation.

Therefore, in order not to react sensitively to fluctuations in the pressing force of the plurality of actuators 40, a dead zone may be provided in the response of the control unit 100 in the rod attitude control. That is, a dead zone may be provided in the response of the control unit 100 to the fluctuation of the pressing force of the actuator 40 detected by the load sensor 50. For example, in the rod attitude control, the control unit 100 presses the actuator 40 corresponding to the load sensor 50 until the fluctuation amount of the pressing force of the actuator 40 detected by the load sensor 50 exceeds a predetermined fluctuation amount threshold. When the amount of fluctuation of the pressing force of the actuator 40 detected by the load sensor 50 exceeds the fluctuation amount threshold while waiting without changing the force, the pressing force of the actuator 40 detected by the load sensor 50 (specifically, pressing). The pressing force of the actuator 40 corresponding to the load sensor 50 may be changed according to the difference between the force and the target pressing force). For example, the fluctuation amount threshold (dead band width) is set to about 5% of the target pressing force. The fluctuation amount threshold value may be set individually for each of the plurality of load sensors 50. For example, a fluctuation amount threshold value corresponding to each of the plurality of load sensors 50 may be set according to the variation in the load (pressing force of the actuator 40) acting on each of the plurality of load sensors 50.

Further, by configuring the actuator 40 with a mechanism for driving the actuator 40 using air pressure (specifically, an air bag 41, an air passage 42, and an air supply unit 43), the actuator 40 is driven with electric power (for example, with a motor). The responsiveness of the actuator 40 can be made slower than in the case of being configured with a conversion mechanism that converts the rotational motion of the motor into a linear motion). As a result, it is possible to prevent the plurality of actuators 40 from reacting sensitively to fluctuations in the pressing force.

[Tool body attitude control]
In the tool body attitude control, the control unit 100 controls a plurality of auxiliary actuators 80 according to the detection results of the plurality of auxiliary load sensors 90. Specifically, the control unit 100 uses the plurality of auxiliary actuators 80 according to the detection results of the plurality of auxiliary load sensors 90 so that the pressing forces of the plurality of auxiliary actuators 80 acting on the tool body 21 are in an equilibrium state. Adjust the pressing force. In addition, this equilibrium state is a state in which the pressing forces of the plurality of auxiliary actuators 80 can be regarded as substantially equal, and specifically, the variation in the pressing forces of the plurality of auxiliary actuators 80 is a predetermined tolerance. It is a state that is within the range. In this example, the control unit 100 detects the plurality of auxiliary load sensors 90 so that each of the pressing forces of the plurality of auxiliary actuators 80 detected by the plurality of auxiliary load sensors 90 becomes a predetermined target pressing force. A plurality of auxiliary actuators 80 are controlled according to the result.

Similar to the rod attitude control, in the tool body attitude control, the imbalance of the pressing force of the plurality of auxiliary actuators 80 is caused by the shape error of the component parts of the honing tool 20 and the honing grindstone 22 during the rotation of the honing tool 20. The main factor is variation in sharpness. These factors do not fluctuate abruptly during honing operation.

Therefore, in order not to react sensitively to fluctuations in the pressing force of the plurality of auxiliary actuators 80, a dead zone may be provided in the response of the control unit 100 in the tool body attitude control. That is, a dead zone may be provided in the response of the control unit 100 to the fluctuation of the pressing force of the auxiliary actuator 80 detected by the auxiliary load sensor 90. For example, in the tool body posture control, the control unit 100 exceeds a predetermined fluctuation amount threshold (for example, about 5% of the target pressing force) of the fluctuation amount of the pressing force of the auxiliary actuator 80 detected by the auxiliary load sensor 90. Until, the auxiliary actuator 80 corresponding to the auxiliary load sensor 90 stands by without changing the pressing force, and when the fluctuation amount of the pressing force of the auxiliary actuator 80 detected by the auxiliary load sensor 90 exceeds the fluctuation amount threshold, the auxiliary is assisted. The pressing force of the auxiliary actuator 80 corresponding to the auxiliary load sensor 90 is changed according to the pressing force of the auxiliary actuator 80 (specifically, the difference between the pressing force and the target pressing force) detected by the load sensor 90. It may be configured in.

Further, by configuring the auxiliary actuator 80 with a mechanism for driving the auxiliary actuator 80 using air pressure (specifically, the auxiliary air bag 81, the auxiliary air passage 82, and the auxiliary air supply unit 83), the auxiliary actuator 80 is driven by using electric power. The responsiveness of the auxiliary actuator 80 can be made slower than when it is composed of a mechanism. As a result, it is possible to prevent the plurality of auxiliary actuators 80 from reacting sensitively to fluctuations in the pressing force.

[Effect of Embodiment]
As described above, the plurality of actuators 40 arranged so as to surround the rod 23 press the rod 23 in the direction toward the rotation axis R of the honing tool 20, and the rod 23 is pressed by the pressing force of the plurality of actuators 40. Since it can be held, deformation of the rod 23 in the radial direction can be suppressed. As a result, the deviation of the posture of the honing grindstone 22 can be suppressed, so that the deterioration of the accuracy of the honing process can be suppressed.

Further, by controlling the plurality of actuators 40 according to the detection results of the plurality of load sensors 50, the pressing force of the plurality of actuators 40 is adjusted according to the fluctuation of the pressing force of the plurality of actuators 40 acting on the rod 23. be able to. As a result, the balance of the pressing forces of the plurality of actuators 40 can be appropriately maintained, so that the rod 23 can be appropriately held by the pressing forces of the plurality of actuators 40. Deformation of the rod 23 in the radial direction can be appropriately suppressed.

Further, by balancing the pressing forces of the plurality of actuators 40 acting on the rod 23, the pressing forces of the plurality of actuators 40 act imbalanced on the rod 23, and the rod 23 is deformed in the radial direction. It is possible to make it difficult for the situation to occur. As a result, the deviation of the posture of the honing grindstone 22 can be suppressed, and the deterioration of the accuracy of the honing process can be suppressed.

Further, by providing the insulating ring 62 between the tool body 21 and the bearing 63 of the relay unit 60, the load sensor 50 to the first lead wire 71 while preventing a short circuit between the tool body 21 and the bearing 63 of the relay unit 60. The detection result of the load sensor 50 can be transmitted to the control unit 100 via the bearing 63 and the second lead wire 72 in this order. As a result, the detection results of the plurality of load sensors 50 can be transmitted to the control unit 100 even while the honing tool 20 is rotating, so that the detection results of the plurality of load sensors 50 can be transmitted even while the honing tool 20 is rotating. A plurality of actuators 40 can be controlled.

Further, by arranging the actuator 40 so as to face the honing grindstone 22 with the rod 23 in between, the reaction force of the work acting on the honing grindstone 22 during the honing processing operation (that is, the honing grindstone 22 is retracted in the radial direction). The pressing force of the actuator 40 can be applied to the rod 23 in a direction that opposes the reaction force that acts in the direction of causing the actuator 40. As a result, deformation in the radial direction of the rod 23 due to the reaction force of the work acting on the honing grindstone 22 can be effectively suppressed.

Further, by arranging a plurality of actuators 40 so as to surround the third rod portion 23c, the third rod portion 23a, the second rod portion 23b, and the third rod portion 23c are easily deformed in the radial direction. The pressing force of the plurality of actuators 40 can be applied to the rod portion 23c. As a result, deformation of the rod 23 in the radial direction can be effectively suppressed.

Further, a plurality of auxiliary actuators 80 arranged so as to surround the tool body 21 press the tool body 21 in the direction toward the rotation axis R of the honing tool 20, thereby suppressing the deviation of the radial position of the tool body 21. can do. As a result, it is possible to prevent a situation in which the contact state between the honing grindstone 22 and the inner peripheral surface of the work hole to be machined changes due to the deviation of the radial position of the tool body 21. It is possible to suppress a decrease in accuracy.

Further, by controlling the plurality of auxiliary actuators 80 according to the detection results of the plurality of auxiliary load sensors 90, the plurality of auxiliary actuators 80 may be subjected to fluctuations in the pressing force of the plurality of auxiliary actuators 80 acting on the tool body 21. The pressing force can be adjusted. As a result, the balance of the pressing forces of the plurality of auxiliary actuators 80 can be appropriately maintained, so that the tool body 21 can be appropriately held by the pressing forces of the plurality of auxiliary actuators 80. Deformation of the tool body 21 in the radial direction can be appropriately suppressed.

Further, by balancing the pressing forces of the plurality of auxiliary actuators 80 acting on the tool body 21, the pressing forces of the plurality of auxiliary actuators 80 act imbalanced on the tool body 21 and the tool body 21 has a diameter. It is possible to make it difficult for the situation of being deformed in the direction to occur. As a result, it is possible to prevent a situation in which the contact state between the honing grindstone 22 and the inner peripheral surface of the work hole to be machined changes due to the deviation of the radial position of the tool body 21. It is possible to suppress a decrease in accuracy.

(Other embodiments)
In the above description, the case where the honing machine 10 includes three actuators 40 and three load sensors 50 has been taken as an example, but the honing machine 10 has four or more actuators 40 and four or more actuators 40. The actuator 40 may be provided with four or more load sensors 50 corresponding to each of the actuators 40. Similarly, the honing machine 10 may include four or more auxiliary actuators 80 and four or more auxiliary load sensors 90 corresponding to each of the four or more auxiliary actuators 80.

Further, the above embodiments may be combined as appropriate. The above embodiments are essentially preferred examples and are not intended to limit the scope of the present invention, its applications, or its uses.

As described above, the present invention is useful as a honing machine.

10 Honing machine 20 Honing tool 21 Tool body 21a Through hole 22 Honing grindstone 23 Rod 24 Biasing member 25 Auxiliary member 25a Opening 30 Drive mechanism 40 Actuator 50 Load sensor 60 Relay part 61 Support base 62 Insulation ring 63 Bearing 71 1st Lead wire 72 Second lead wire 80 Auxiliary actuator 90 Auxiliary load sensor

Claims (8)

A tool body formed in a tubular shape and provided with a through hole in the peripheral wall portion, a honing grindstone arranged in the through hole of the tool body and capable of advancing and retreating in the radial direction, and a rod-shaped tool body formed inside the tool body. It has a rod that moves the honing grindstone forward and backward in the radial direction by being arranged and moving in the axial direction, and the honing grindstone is advanced from the tool body and brought into contact with the inner peripheral surface of the hole to be machined of the work. A honing tool that grinds the inner peripheral surface of the work hole of the workpiece by rotating around a rotation axis extending in the axial direction.
Honing characterized in that it is arranged so as to surround the rod and is fixed inside the tool body, each of which is provided with a plurality of actuators that press the rod in a direction toward the rotation axis of the honing tool. Processing machine. In claim 1,
A plurality of load sensors that detect the pressing force of the plurality of actuators acting on the rod, and
A honing processing machine including a control unit that controls the plurality of actuators according to the detection results of the plurality of load sensors. In claim 2,
The control unit is characterized in that the pressing force of the plurality of actuators is adjusted according to the detection results of the plurality of load sensors so that the pressing force of the plurality of actuators acting on the rod is in an equilibrium state. Honing processing machine to do. In claim 2 or 3,
With multiple relays
With multiple first leads,
Equipped with multiple second conductors
A plurality of lead wire insertion holes are provided in the peripheral wall portion of the tool body.
The plurality of load sensors are provided on the outer circumference of the rod.
Each of the plurality of relay portions has an insulating ring provided on the outer periphery of the tool body having an insulating property, and a bearing that rotatably supports the insulating ring.
The plurality of first conductors are electrically connected to the plurality of load sensors and the bearings of the plurality of relay portions in a state where the plurality of first conductors are respectively inserted into the plurality of conductor insertion holes of the tool body.
The honing processing machine is characterized in that the plurality of second conducting wires electrically connect the bearings of the plurality of relay units and the control unit, respectively. In any one of claims 1 to 4,
A honing machine characterized in that one of the plurality of actuators faces the honing grindstone with the rod sandwiched between them when viewed from the axial direction. In any one of claims 1 to 5,
A drive mechanism for moving the rod in the axial direction is provided.
The rod has a first rod portion, a second rod portion, and a third rod portion that are arranged in order from the side closer to the drive mechanism to the side farther from the drive mechanism.
The first rod portion is connected to the drive mechanism and is connected to the drive mechanism.
The second rod portion is formed in a conical shape that gradually becomes thinner from the side closer to the drive mechanism to the far side, and when the rod moves in the direction from the side closer to the drive mechanism to the far side. In contact with the honing grindstone, the honing grindstone is advanced in the radial direction.
A honing machine characterized in that the plurality of actuators are arranged so as to surround the periphery of the third rod portion. In any one of claims 1 to 6,
An auxiliary member provided with an opening into which the tool body is inserted, and
A plurality of auxiliary actuators arranged so as to surround the tool body and fixed inside the opening of the auxiliary member, each of which presses the tool body in a direction toward the rotation axis of the honing tool. A honing machine that features this. A tool body formed in a tubular shape and provided with a through hole in the peripheral wall portion, a honing grindstone arranged in the through hole of the tool body and capable of advancing and retreating in the radial direction, and a rod-shaped tool body formed inside the tool body. It has a rod that moves the honing grindstone forward and backward in the radial direction by being arranged and moving in the axial direction, and the honing grindstone is advanced from the tool body and brought into contact with the inner peripheral surface of the hole to be machined of the work. A honing tool that grinds the inner peripheral surface of the work hole of the workpiece by rotating around a rotation axis extending in the axial direction.
An auxiliary member provided with an opening into which the tool body is inserted, and
A plurality of auxiliary actuators arranged so as to surround the tool body and fixed inside the opening of the auxiliary member, each of which presses the tool body in a direction toward the rotation axis of the honing tool. A honing machine that features this.

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