JPH0411003Y2 - - Google Patents

Description

[Detailed description of the invention] [Industrial application field] The present invention is an inner diameter inspection device that detects the diameter of a machined hole in a workpiece, and in particular is attached to a honing machine, and is capable of handling multiple types of workpieces with different hole diameters. This invention relates to an inner diameter inspection device.

[Prior art]

Conventionally, when superfinishing the inner circumferential surface of a workpiece, a honing tool that supports a grindstone so that it can be expanded and contracted is inserted into a machining hole of the workpiece, and the honing tool is rotated while protruding outward. As shown in Japanese Utility Model Application No. 55-138055, a honing device that performs such internal grinding has conventionally inserted a taper cone into a tool holder, thereby moving the grindstone head supporting the grindstone outward. There was one that was made to stick out.

By the way, when internal grinding is performed using such a honing device, the diameter of the hole to be machined in the workpiece is generally measured while machining with, for example, a plug gauge, and in this case, the plug gauge is inserted into the hole for a predetermined length. When this happens, the workpiece is considered to have been finished to a predetermined inner diameter. In an inner diameter inspection device that measures the machined hole diameter with such a plug gauge, of course a different plug gauge is required for workpieces with different set inner diameters. It is necessary to replace the plug gauge each time, and in recent processing lines where multiple types of workpieces are mixed, the replacement work is complicated, and in the end, the conventional inner diameter inspection device described above was used. The machining efficiency of the honing device was low.

[Purpose of invention]

The present invention was developed in response to this conventional situation, and it is possible to inspect the inner diameter of multiple types of workpieces with different machined hole diameters with one device, and as a result, the inner diameter can be improved to improve the work efficiency of internal grinding. The purpose is to provide inspection equipment.

[Structure of the invention] The present invention is such that when the workpiece is honed to the set inner diameter, the gauge part of the gauge means is guided into the machined hole as the honing tool moves, and the completion of honing is detected by the movement of this gauge part. In the inner diameter inspection device, the gauge means is provided with a plurality of gauge parts whose diameters increase in order from the workpiece side in the tool axis direction, and the honing completion detection means is configured to vary the position of the detection part in the tool axis direction with respect to the workpiece. Detection position variable means is provided. As a result, in the present invention, when grinding a workpiece to the machining setting inner diameter corresponding to the gauge part at the tip, the detection part of the honing completion detection means is located at the detection position corresponding to the workpiece, and the workpiece is Detects when the gauge part is honed to a set inner diameter corresponding to the workpiece and inserted into the workpiece,
Also, 2, 3 from the tip with a larger inner diameter than this...
When detecting with the gage part, the detection part of the honing completion detection means is moved to the detection position for each workpiece in the same way as above, and as a result, it is possible to inspect the machined hole diameter of multiple types of workpieces. It becomes possible.

〔Example〕

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

The drawing shows a honing tool equipped with an inner diameter inspection device according to an embodiment of the present invention, and in the drawing, 1
is a honing tool, and six grindstone placement members 3 are disposed on a support portion 2 of the honing tool so as to be slidable in the radial direction. A grindstone 4 is attached to the upper surface of the grindstone holder 3 by a support pin 5, and a sliding contact member 6 having a sliding surface 6a that is inclined inward toward the tip is fixed to the lower surface of the lower surface. Ring springs 7 are wound around the front and rear ends of the grindstone holder 3 to bias them radially inward. A driving member 16 consisting of connecting members 8 and 9 and a driving cylinder 10 is connected to the rear end of the support portion 2, and the grinding wheel 4 is driven to rotate and reciprocated in the axial direction. .

A taper cone 11 is inserted into the sliding member 6 fixed to the grindstone holder 3 so as to be slidable in the axial direction. A contacting conical cam portion 11a is formed. This taper cone 1
1, the tip of a connecting member 12 is connected to the rear end of the connecting member 12 by a universal joint portion 13, and this universal joint portion 13 is for absorbing positioning errors of the workpiece. Further, the connecting member 12 extends rearward within the driving member 16, and is biased rearward by a biasing spring 14. Further, a pressing member 15 is in contact with the rear end of this connecting member 12, and when this pressing member 15 is moved forward, the taper cone 11 is moved forward, and its cam portion 11a causes the grindstone 4 to project outward. It is configured.

A cylindrical gauge member 17 is fitted around the outer periphery of the drive member 16 so as to be slidable in the axial direction. Note that the drawings show a state in which the lower half and the upper half of the gauge member 17 are inserted at different positions from the axis. A first gauge part 18a having a size corresponding to the machining set inner diameter of the first workpiece _W1 is formed at the tip of this gauge member 17, and a part adjacent to the base side of the first gauge part 18a is formed. , a second gauge portion 18b is formed with a size corresponding to a second machining set inner diameter larger than the first machining set inner diameter of the second workpiece _W2 . Further, a flange portion 19 is provided at the rear end portion of the gauge member 17.
is bent outward, and a biasing spring 28 is disposed between this flange portion 19 and the rear end of the drive member 16, thereby biasing the gauge member 17 forward. ing.

A detection device 20 for detecting completion of honing is disposed above the flange portion 19, and the device 20 includes a detection portion 21 and a detection position variable device for moving the detection portion 21 to a predetermined detection position. 2
It is composed of 2. The limit switch 21a of the detection section 21 is attached to a support bracket 21b so as to be able to come into contact with the flange section 19, and the support bracket 21b is attached to the piston rod 2 of the drive cylinder 23 of the detection position variable device 22.
It is fixed to 3a. and the drive cylinder 2
3 and the high pressure air supply source 24.
A switching valve 26 is connected to the switching valve 2.
A switching signal A, which is a vehicle type signal corresponding to the first and second works W ₁ and W ₂ , is input to 6.

Next, the effects will be explained.

The apparatus of this embodiment is capable of inspecting the inner diameter of the first and second workpieces W ₁ and W ₂ to be machined to the first machining setting inner diameter or the second machining setting inner diameter larger than the first machining setting inner diameter. The lower part of the member 17 than the axis line shows the state of the first workpiece _W1 , and the upper part shows the state of the second workpiece _W2 at the time of completion of honing.

First, to explain the internal grinding of the first workpiece _W1 , first, the first
A switching signal A corresponding to the first work W ₁ is input, whereby the drive cylinder 23 is extended and the limit switch 21a is moved to the detection position corresponding to the first work W ₁ indicated by the dashed line in the figure. Become. Next, the workpiece W ₁ is supported by a chucking device (not shown), and the pressing member 15 is
When retracted, the taper cone 11 is retracted by the spring 14, thereby causing each grindstone 4 to contract inward. Then, the whetstone 4 is inserted into the machining hole of the work W ₁ while being rotated in a contracted state, and when the pressing member 15 is advanced little by little in this state, the taper cone 11 pushes the sliding member 6 outward and expands the whetstone. 4 is extended outward. If the honing tool 1 is rotated and reciprocated in this way while the grindstone 4 is extended, the inner surface of the workpiece _W1 is ground little by little.

At this time, if the diameter of the machined hole of the work W ₁ is still smaller than the first set inner diameter, even if the grindstone 4 is inserted into the machined hole, the first gauge part 18a will not come into contact with the rear end of the machined hole. Therefore, the gauge member 17 does not move much in the axial direction, and in this case, as the grinding wheel 4 moves forward, the biasing spring 26
will contract.

When the diameter of the machined hole of the work W ₁ reaches the first set inner diameter, the first gauge part 18a is inserted into the machined hole as the grinding wheel 4 moves forward, and as a result, as shown by the dashed line in the figure, The flange portion 19 of the gauge member 17 contacts the limit switch 21a and turns it on, detecting the completion of internal grinding, stopping the advance of the taper cone 11 by the pressing member 15, and moving the honing tool 1 away from the workpiece _W1 . Extracted outward. Further, at this time, since the grindstone portion of the honing tool 1 is guided by the guide member 27, it does not swing around.

Furthermore, when machining a second workpiece W ₂ having a second machining setting inner diameter, a switching signal A corresponding to the second workpiece W ₂ is input to the switching valve 26 . Then, as shown by the solid line in the figure, the drive cylinder 23 contracts, and the limit switch 21a is thereby located at the detection position corresponding to the second workpiece _W2 . Then, the inner surface of the second workpiece W ₂ is ground in the same manner as above, and when the machined hole diameter reaches the second machining setting inner diameter, the second gauge part 18b is inserted into the workpiece W2, and the gauge part 18b is inserted into the workpiece _W2 . The member 17 moves in the axial direction, causing the flange portion 19 to come into contact with the limit switch 21a, and as a result, completion of the grinding process is detected.

In this way, in the device of this embodiment, the gauge member 17
are provided with first and second gauge parts 18a and 18b of sizes corresponding to the first and second workpieces _W1 and _W2 ,
The limit switch 21a is connected to each of the above works W ₁ and W ₂
Since the inner diameter of two types of workpieces can be detected with one device, only one limit switch 21a is required, which increases the cost of the detection device. I won't end up doing it.

In the above embodiment, the limit switch 21a is used as the detection section, and the drive cylinder 23 is used as the detection position variable means, but it goes without saying that these can have various structures. A rack pin-on mechanism may be used as the switch and the detection position variable means.

Further, in the above embodiment, a case has been described in which it is possible to handle two types of workpieces, but the present invention can also be applied to three or more types of workpieces. It is sufficient to form three or more gauge parts and to configure the sensor so that a detection part such as a limit switch can be moved to three or more detection positions corresponding to each workpiece.

[Effect of idea]

As described above, according to the inner diameter inspection device of the present invention, the gauge means is provided with a plurality of gauge parts whose diameters increase in order from the workpiece side in the direction of the tool axis, and the detection means is used to detect the position of the detection part relative to the workpiece along the tool axis. Since the detection position variable means is provided, the inner diameter of a plurality of types of workpieces can be inspected with one device, and the work efficiency of internal grinding can be greatly improved.

[Brief explanation of the drawing]

The drawing is a configuration diagram of an inner diameter inspection device according to an embodiment of the present invention. DESCRIPTION OF SYMBOLS 1... Honing tool, 17... Gauge member (gauge means), 18a, 18b... Gauge part, 2
0...Detection device (honing completion detection means), 2
DESCRIPTION OF SYMBOLS 1...Detection part, 22...Detection position variable device (detection position variable means), _W1 , _W2 ...Work.

Claims (1)

[Scope of utility model registration request] a gauge means having a gauge part that is movably provided in the axial direction on the outer circumference of the honing tool and is guided into the machined hole as the honing tool moves when the inner diameter of the workpiece is honed to a set inner diameter;
and a honing completion detection means for detecting completion of honing when the gauge section moves a predetermined stroke into the machined hole, the gauge means having a plurality of holes whose diameters increase in order from the workpiece side to the tool axis direction. A gauge section is provided,
Inner diameter inspection characterized in that the honing completion detection means is provided with detection position variable means for varying the position of the detection part of the detection means in the tool axis direction with respect to the workpiece in accordance with the type of workpiece. Device.