JPH07276104A - Installation device of grinding machine on lathe - Google Patents

Abstract

PURPOSE:To provide an installation device of a polishing board to a lathe capable of polishing and machining instantly without removing a work after machining from a chuck of a main spindle. CONSTITUTION:A cross slide 9 is provided on a carriage 8 on a bed 3 of a lathe 1 furnished with a feed controlling device 15. A tool rest 10 is installed on the front side of a horizontal top surface of the cross slide 9, a base plate 22 with a horizontal bottom surface of a polishing body 25 with a motor 23 is installed on the other side, and simultaneously, the center of a shaft 24 of a polishing board 21 is provided in parallel with and roughly as high as the center of a main spindle 5 of the lathe 1.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a device for mounting a lapping machine on a lathe, and more particularly, by providing a tool rest 10 and a lapping machine 21 on the front side and the opposite side of a lateral feed table 9 of the lathe 1. The lathe 1 is attached to the lathe 1 such that the turning W and the lathe for the work W attached to the chuck 6 of the lathe 1 can be continuously processed without removing the work from the chuck 6 of the lathe 1. It relates to the device.

[0002]

2. Description of the Related Art As a conventional lathe, there are, for example, those whose principal parts are shown in schematic plan explanatory views and schematic front explanatory views in FIGS. This lathe is held by a chuck 6 at the end of a spindle 5 mounted on a spindle stock 4 and at the same time a tailstock 7 is held.
The work W which is tailed by the tailstock shaft 7A is rotationally driven by the main shaft 5 while it is reciprocally moved along the bed 3 in front of the transverse feed base 9 (lower side in FIG. 7). Tool 10 attached to the tool rest 10 provided on the
Depending on B, required turning processing, for example, round bar cutting, inner diameter cutting, taper cutting, inner surface cutting, profile cutting, thread cutting,
It is used for cutting such as automatic sizing and chamfering.

In FIGS. 7 and 8, 2 is the base of the lathe 1,
8A is a vertical feed handle for manually operating the carriage 8 in the left-right direction, 9A is a lateral feed handle for manually operating the tool rest 9 in the front-back direction of the lathe 1 (vertical direction in FIG. 7), and 10F is provided in the tool rest 10. Abrasion amount detection sensor for bite 10B,
Reference numeral 11 is a cooling water pipe for supplying cooling water to the cutting portion of the work W by the cutting tool 10B. The end of this cooling water pipe 11 is flexible and can be bent in any direction, and its pouring position can be freely adjusted. The bendable structure itself is almost the same as the existing cooling water pipe.

Reference numeral 15 is a control device provided in a proper place around the lathe 1, and the storage unit 15C of the control device 15 stores the bite to the work W held by the chuck 6 at the end of the spindle 5 of the lathe 1. The cutting command signal by 10B, for example, the cutting command signal for the outer diameter cutting, the inner diameter cutting, the taper cutting, the profile cutting, the thread cutting, the automatic sizing, the chamfering, etc. of the round bar is inputted to the input unit 15A or not shown. It is preliminarily input and stored by an appropriate input means such as a keyboard or a card having a machining command signal, while it is preliminarily stored in the storage unit 15C by input of a turning machining start signal by the lathe 1. The central processing unit CPU 15D calls the generated cutting command signal, drives the drive parts of the carriage 8 and the lateral feed table 9 based on the machining command signal, and performs the required turning process on the work W. What you do However, the control device 15 itself
The storage unit 15C, the central processing unit CPU 15D, and the like are configured in substantially the same manner as a control device in an existing automatic lathe.

A stored value as a machining command signal previously input to the storage section 15C of the control device 15 is selected by the central processing unit CPU 15D of the control device 15 by a machining start command from the lathe 1 and the lathe concerned. By moving the reciprocating table 8 and the lateral feed table 9 of FIG. 1 left and right and / or back and forth through their driving devices, the bite 10B attached to the tool rest 10 is held by the chuck 6 of the main spindle 5 and revolves. The work W is moved in the X and Y directions until it reaches a machining target value, and the required cutting work is automatically performed on the work W.

The controller 15 is detected by a wear amount detecting sensor 10F (only the installation position is schematically shown in FIG. 7) of the cutting tool 10B provided at an appropriate position of the tool rest 10 or the like. The wear amount detection signal of the cutting tool 10B is transmitted, and the central processing unit CPU 15D corrects the feed command signal of the transverse feeding table 9 to compensate the feeding amount of the transverse feeding table 9, and the required amount is calculated by the cutting tool 10B. A compensation circuit (not shown) is provided to enable turning of the.

Incidentally, as a special use of the conventional lathe 1, in place of the cutting tool 10B mounted on the tool rest 10 provided on the front side of the transverse feed base 9, a polishing body G with an air motor is used.
Is arranged as shown in the special use example of the conventional lathe of FIG. 6 (B), and tightened and fixed by the tightening lever 10A.
It has already been proposed that the inner surface of the outer race of the ball bearing as the work W can be polished.

Further, although not shown, in a conventional automatic lathe equipped with an automatic tool changer, a tool stand provided on an inclined lateral feed table is obliquely upward with respect to a horizontal center line of the spindle of the automatic lathe. After exchanging the bite, the turret is lowered to a turning position that is almost level with the spindle center line at the old position, and the required turning is continued on the work held by the chuck at the end of the spindle. What has been made possible has already been proposed.

[0009]

However, the conventional lathes described above, particularly automatic lathes, are usually constructed as dedicated machines for turning into round bars and other materials to be machined. It is suitable for automatic lathe turning to, for example, receiving the work W from the chuck of the automatic lathe and the same lathe between the automatic lathe and the automatic polishing machine provided adjacent to the automatic lathe. -By installing a so-called transfer device that automatically enables the transfer of the work and the attachment of the work to the holding device of the automatic polishing machine, the automatic lathe and the automatic polishing machine can be used as dedicated machines. However, the automatic lathe and the automatic lapping machine, which are specialized machines, can be used for small-quantity processing with a small number of processing, especially if a transfer device is installed side by side. Does not reach a large amount In the case of quantitative processing, and there are cases where continuous processing of automatic turning and automatic polishing is required, but the installation of the automatic lathe and the automatic polishing machine as a high-efficiency dedicated machine as described above However, since it causes an excessive capital investment for the actual processing amount, it was actually quite difficult to introduce the above-mentioned automatic lathe to so-called small and medium-sized enterprises.

In the case where the automatic lathe and the automatic lathe are separately processed, the work W is naturally attached to each of the automatic lathe and the automatic lathe, and the respective positioning is performed. Since it is necessary to carry out each processing afterwards, not only is it time-consuming to set up them, but also secure a space for installing the lathe and the polishing machine and their operating space. However, there is also a problem in that it is not easy to install them from this aspect.

Further, temporarily, as shown in FIG.
To the cutting tool 10B attached to the tool rest 10 provided on the front side of the lathe 1 of the lathe 1 (in the alternate long and short dash line 10B of FIG. 6B, the cutting tool 10B after being removed from the turret 10 is indicated by the alternate long and short dash line). Instead, even in the special use example of the conventional lathe in which the polishing body G with an air motor is attached to allow the inner diameter of the outer race of the bearing to be polished, the tightening lever can be used after the turning process by the cutting tool 10B is completed. Loosen 10A and once remove the cutting tool 10B from the tool rest 10, and then place the abrasive body G with air motor on the same tool rest 10 to position it, and tighten with the tightening lever 10A before grinding. Since it was necessary to start, in the special use example of such a lathe, the installation space and operation space of those lathes are narrower than those of the conventional example which requires an independent polishing machine in addition to the lathe 1. Although this can be achieved, this In place of the bite 10B attached to the tool rest 10, not only is it time-consuming to attach the abrasive body G with air motor, but also the size of the abrasive body G with air motor attached to the tool rest 10 The shape is limited, and moreover, the positioning of the polishing body G with an air motor attached to the tool rest 9 with respect to the work W must be performed each time prior to the polishing process. there were.

Incidentally, a grinding body G with an air motor is attached in place of the cutting tool 10B attached to the tool rest 10 provided on the front side of the transverse feed base 9 of the lathe 1, and a work such as a round bar is provisionally provided. W
As is understood from the fact that when the outer surface of the work W is to be polished, the outer surfaces of the work W and the polishing body G move in the same direction in the contact portion, as understood from the direction of rotation of the work W. Since the polishing body G is likely to be caught and may cause a danger, in practice, the polishing body 25 with an air motor is attached to the tool rest 1 of the lathe 1 to polish the outer surface of a round bar or the like. Not not.

However, the problem with the rotation direction of the work W and the rotation direction of the polishing body G is that the work W is changed by switching the rotation direction of the main shaft 5 of the lathe 1 by the switching means 5A. While rotating in the opposite direction to the illustrated example, the polishing body G with air motor is positioned in front of the work W, or the rotation direction of the polishing body G with air motor is opposite to that described above. By selecting the polishing body G in the same direction, there is no room for solving the above-mentioned problems and improving the polishing efficiency. Not only it is necessary to select a polishing machine with a different rotation direction from the abrasive body G with air-motor, but also the load direction at the mounting portion of the work W is reversed, so it is necessary to take appropriate measures. was there.

In view of the above-mentioned problems in the conventional example, the present invention has a horizontal transverse feed table 9 on the carriage 8 of the lathe 1.
Attach the tool rest 10 to the front side of the
The polishing disc 21 provided with driving means such as 3 is mounted so that the axis 24 of the polishing disc 21 is parallel to the spindle 5 of the lathe 1 and has substantially the same height as the axis of the lathe 1, thereby chucking the end of the spindle 5. In addition to the normal turning process by the cutting tool 10B on the tool rest 10, the work W held between 6 and 6 is provided after the turning process.
With respect to the work, the same work W after turning is not removed from the chuck 6, and moreover, the grinding machine 2 is provided for the work W.
No need to position 1 every time, and immediately enables continuous polishing by the same polishing machine 21 to eliminate the above-mentioned problems and to attach a polishing machine to a lathe that can be expected to have high processing efficiency. Is to provide.

[0015]

In order to solve the above-mentioned problems of the conventional example, the present invention provides a transverse feed table 9 on the reciprocating table 7 on the bed 3 of the lathe 1, and the transverse feed table 9 is provided. The tool rest 10 is provided on the front side of the same, and the polishing table 21 having a horizontal bottomed substrate 22 driven by a driving means such as a motor 23 is provided on the side opposite to the feed table 9, and the polishing table 21 is provided. The shaft 24 cores are provided in parallel with the main shaft 5 cores of the lathe 1 and at substantially the same height.

(Operation) Since the present invention has the above-mentioned structure, it is held by the chuck 6 at the end of the main shaft 5,
The tool rest 1 for the work W rotated by the spindle 5.
In addition to the normal turning by the cutting tool 10B on 0, the work W after the turning is not removed from the chuck 6 without removing the work W from the transverse feed table 10. By the polishing body 25 of the polishing board 21 attached on the opposite side,
Each time, the polishing process is continuously performed without performing the positioning and other operations.

(Embodiment) An embodiment of an apparatus for mounting a lapping machine on a lathe according to the present invention will be described below with reference to FIGS. 1 to 6. The same names and reference numerals are used for the parts common to the conventional example shown in FIGS. 7 and 8.

(First Embodiment) FIG. 1 is a schematic plan view of an essential portion of a first embodiment of an apparatus for attaching a lapping machine to a lathe according to the present invention, and FIG. 2 is a schematic side view of the essential portion. FIG. 3 and FIG. 3 are schematic vertical cross-sectional explanatory views of essential parts along the line P-P in FIG. 6A and 6B show the operation of the present invention in comparison with a conventional special use example of a lathe, and FIGS. 6A and 6C are diagrams of a main part of the present invention and an explanatory view of the operation thereof. 6 (B) and 6 (D) is a work W in which a grinding body G with an air motor is attached to the attachment part of the cutting tool 10B of the tool rest 10 of the conventional lathe 1 and is attached to the chuck 6 at the end of the main spindle 5. FIG. 3 is a diagram and an operation explanatory view of a special use example of a conventional lathe that enables polishing processing to be performed.

1 to 3 and 6, 1 is a lathe, 2 is a base, 3 is a bed, 4 is a headstock, 5 is a spindle, 6
Is a chuck provided at the end of the main shaft 5, 7 is a tailstock provided at the end of the bed 3, 7A is a tailstock, and 8 is a reciprocating platform. This reciprocating platform 8 is rotated by the vertical feed handle 8A. Alternatively, it is reciprocally driven along the head 3 in the left-right direction (FIGS. 1 and 2) by a lead screw (not shown) that is rotationally driven based on a feed command signal stored in advance in the storage unit 15C of the control device 15.

The reference numeral 9 indicates a bed 8 of the lathe 1 on the carriage 8.
Is a lateral feed table extending beyond the center of the main shaft 5 so as to form a front-back direction (vertical direction in FIG. 1). This lateral feed table is fed laterally from the lateral baking handle 9A or the control device 15 (cutting). ) It is sent in the required direction via the traverse shaft by the command signal. 9C is a horizontal top surface of the horizontal feed table 9, 10 is a tool rest provided on the front side of the horizontal feed table 9 (lower side in FIG. 1), 1
Reference numeral 0A denotes a tightening lever of the tool rest 10, and 10B denotes a cutting tool. The cutting tool 10B is detachably fixed to the tool rest 10 by the tightening lever 10A.

Reference numeral 11 is a cooling water pipe for supplying cooling water, and an end portion of the cooling water pipe 11 is formed of a flexible pipe material so that the end portion of the cooling water pipe 11 can be deformed in an arbitrary direction and the state after the deformation can be secured. The tip of the cooling water pipe 11 faces a cutting portion or a grinding portion where the cutting tool 10B or a polishing body 25, which will be described later, and a work W are in contact with each other, and cooling water can be injected into the cutting portion. However, the structure itself of the cooling water pipe 11 is similar to the existing cooling water pipe of the same type.

The control device 15 turns the work W with the cutting tool 10B attached to the tool rest 10 by the tightening lever 10A. By inputting a feed command signal for feeding from the input means 15A or an appropriate input means such as a keyboard (not shown), the central processing unit CPU1
The processing signal is stored in the storage unit 15C via the 5D, while the machining start signal from the lathe 1 is input via the control unit 15 so that the command signal stored in the storage unit 15C is stored in the central processing unit CPU 15D. And a drive device for the carriage 8 and the lateral feed table 9 is operated to feed the bite 10B to enable the required turning.

Further, the control unit 15 includes the turret 1
The bit 10B provided at a proper position of 0 (or the horizontal feed table 9)
Tool 1 detected by the wear sensor 10F
A wear amount detection signal of 0B is input, and a compensation circuit (not shown) for compensating the feed amount of the transverse feed base 9 by the wear amount detection signal of the bite 10B is provided, but the control device 15 having such a function is provided. The device itself is almost the same as the control device of an existing automatic lathe equipped with an electronic control device.

Reference numeral 21 is a polishing disk, and 22 is a substrate 2 of the polishing disk 21.
In step 2, the bottom surface of the substrate 22 has a horizontal shape and is placed on the horizontal top surface 10C of the transverse feed table 9. Reference numeral 23 is a motor for the polishing board 21, 24 is an axis thereof, 25 is a polishing body, and 28 is a bolt for detachably fixing the substrate 22 to the lateral feed table 9.

The control unit 15 is provided with a work W of the polishing body 25 of the polishing table 21 by its input unit 15A or an appropriate input means such as a keyboard or a card (not shown).
, The feed command signal for feeding the reciprocating table 8 and the lateral feed table 9 in a direction opposite to the feeding direction at the time of the outer diameter turning to the work W by the cutting tool 10B. The central processing unit CPU is stored in the storage unit 15C.
By inputting in the same manner as above via 15D, it becomes possible for the polishing body 25 to automatically polish the work W to the outer diameter.

Reference numeral 10G is a sensor for detecting the amount of wear of the polishing body 25 provided at a proper position on the opposite side of the lateral feed table 9. The wear amount detection signal of the polishing body 25 detected by the wear amount detecting sensor 10G is the above-mentioned signal. Tool 10B wear amount protrusion sensor 10F
Is transmitted to the control unit 15 in the same manner as the wear amount detection signal detected by the central processing unit CPU 15D.
By modifying the feed command signal of the transverse feed table 19,
It is configured to compensate the target feed amount. The wear amount detecting sensor 10G of the polishing body 25 may be replaced by the wear amount detecting sensor 10F of the cutting tool 10B as long as the wear amount of the polishing body 25 can be detected.

H ₁ is the distance between the horizontal top surface 9C of the horizontal feed table 9 and the spindle 5 of the lathe 1, that is, the height of the axis of the spindle 5 from the horizontal top surface 9C, and H ₂ is the polishing machine 21. The distance between the horizontal lower surface of the substrate 22 and the axis 24 of the polishing body 25, that is,
It is the height of the shaft 24 center of the polishing body 25, and H ₁ and H ₂ coincide with each other.

(Operation of the First Embodiment) The work W held by the chuck 6 at the end of the main spindle 5 of the lathe 1 and supported between the tailstock 7 and the tailstock shaft 7A is supported by the main shaft 5. While the chuck 6 engages and drives to rotate, the tool rest 10 provided on the front side of the lateral feed stand 9 on the carriage 8 is stored in the storage unit 15C of the controller 15 by the tool 10B attached by the tightening lever 10A. The input section 15A or the word stored in advance by an appropriate input means such as a keyboard or a card (not shown).
The command signal for processing W is the central processing unit CPU
15D sequentially to move the reciprocating table 8 and the lateral feed table 9 through its driving device, or if necessary, the wear amount of the cutting tool 10B can reduce the wear amount of the tool rest 1.
0 (or transverse feed table 9), the same byte 10B
The wear amount detection signal detected by the wear amount detection sensor 10F of the CPU is sent to the control device 15 by the central processing unit CPU1.
The byte 10B by being input via 5D.
The control unit 15 is provided in that the feed amount of the transverse feed table 9 corresponding to the wear amount of the work is corrected by the central processing unit CPU 15D to automatically perform the required turning process on the work W. It is almost the same as the conventional lathe 1.

However, in the first embodiment, the side of the horizontal top surface 9C of the transverse feed table 9 which faces the main axis 5 (the upper side in FIG. 1).
In addition, since the polishing table 21 is provided substantially at the same position as the axis 24 of the polishing body 25 is parallel to the axis of the main shaft 5 of the lathe 1, the shuttle 8 and the lateral feed table 9 to the controller 15 are provided. In addition to the input of the feed command signal, the horizontal feed table 9 is retracted so that the polishing body 25 of the polishing table 21 is brought into contact with the work W after the turning, and then the horizontal feed table is received. A command signal for retreating the polishing stock by the polishing body 25 by 9 is input in advance by an appropriate input means such as the input unit 15A or a card.

As a result, without removing the work W after turning by the cutting tool 10B from the chuck 6, the transverse feed base 9 is located on the front side of the work W (lower side in FIG. 1). , Left side in FIG. 6 (A)}, and the polishing table 2 is provided on the side of the transverse feed table 9 beyond the spindle 5.
By bringing the polishing body 25 of No. 1 into contact with the outer surface of the work W, the outer diameter polishing of the work W is immediately started, and thereafter, it is preliminarily input to the storage unit 15C of the control device 15. Feed command signals of the carriage 8 and the lateral feed table 9,
The polishing body 2 to the work W is moved by reciprocating the reciprocating table 8 and laterally feeding the lateral feeding table 9 based on the polishing command signal.
The polishing process of No. 5 is performed after the turning process.

The amount of wear of the polishing body 25 is detected by the detection sensor 10G provided at the end portion of the transverse feed table 9 on the opposite side,
The wear amount detection signal is transmitted to the control unit 15, and the central processing unit CPU 15D causes the storage unit 15 to store the wear amount.
A feed signal corresponding to the feed amount of the transverse feed table 9 stored in C in advance is used as a detection signal for the wear amount detection sensor 1 of the cutting tool 10B.
In almost the same manner as the correction of the feed amount by the detection signal by 0F, the feed amount of the transverse feed table 9 is corrected and the compensation is performed.

Further, in this first example, the polishing body 25
And the work W rotate in the same direction as shown by arrows in FIGS. 6A and 6C, and both are abraded while moving in opposite directions at their abutting portions, so that the relative polishing rate. Is polishing body 2
The linear velocity having a large sum of the linear velocity S of 5 and the linear velocity V of the work W is S + V, which is long as shown by the thick line in FIG. 6C, and hence the polishing efficiency can be expected to be improved. .

(Second Embodiment) FIG. 4 shows the essential parts of the second embodiment of the device for mounting a lapping machine on a lathe according to the present invention, similarly to FIG. 3 showing the essential parts of the first embodiment. The PP of FIG.
It is a model longitudinal cross-section explanatory drawing which shows the horizontal feed stand 10 longitudinally in a line area. In addition, the same names and reference numerals are used for parts common to the first embodiment shown in FIGS.

In FIG. 4, reference numeral 21 denotes the polishing plate of the second embodiment. The distance H ₃ between the lower surface of the substrate 22 of the polishing plate 21 and its shaft 24 core is such that the horizontal top surface 9C of the transverse feed 9 is 9C. It is configured to be narrower than the distance H ₁ between the main shaft of the lathe 1 and the five cores. Three
0 is a tightening bolt for mounting and mounting the substrate 22 having the horizontal bottom surface of the polishing table 21 on the horizontal top surface 9C of the lateral feed table 9.
32 and 33 are spacers, and H ₄ and H ₅ are spacers 32 and 33.
The spacers 32 and 33 are inserted between the horizontal top surface 9C of the lateral feed table 9 and the horizontal bottom surface of the substrate 22 of the polishing table 21, and the bolts 30 move the substrate 22 horizontally. By being fixed to the feed table 9, the shaft 24 of the polishing plate 21 and the main shaft 5 are parallel to each other and are supported so that the axes of both shafts are substantially even.

According to the second embodiment, the polishing machine 2 having a low height is used.
1, that is, the height H ₃ between the horizontal bottom surface of the substrate 22 of the polishing table 21 and its shaft 24 core is greater than the height H ₁ between the horizontal top surface 9C of the transverse feed base 9 and the main spindle 5 core. Low polishing table 21
By disposing spacers 32 and 33 having thicknesses (height) of H ₄ and H ₅ below the horizontal bottom surface of the substrate 22,
The shaft 24 center of the polishing body 25 and the shaft center of the work W are made substantially equal in height, and the polishing positions where they abut each other are made substantially equal in height to the shaft center of the main shaft 5, and the same polishing procedure as described above is performed. With high polishing efficiency.

Therefore, so-called lathes 1 having different swings
On the other hand, by preparing several kinds of spacers 32 and 33 having different thicknesses, the polishing plate 21 having the same structure can be attached and used as it is, and by extension, the lathe 1 having the different structure can have the same structure. When attaching and mounting the polishing table 21, it is possible to achieve the advantage of mass production of the polishing table 21 having the same structure.

The thickness H ₄ of the spacers 32 and 33 is
If H and H ₅ are selected to have a thickness corresponding to the swing difference on the lathe 1 of different lathes 1, the lapping machine 21 of the same structure including the height and the lathe 1 of the lathes 1 of different types are selected. The second embodiment of the present invention can be implemented at a lower cost by preparing a plurality of types of spacers 32 and 33 having a thickness corresponding to the difference in the height of vibration on the shaft 9. The other structures and operations are almost the same as those of the first embodiment.

(Third Embodiment) FIG. 5 is a region similar to FIG. 3 showing the essential parts of the third embodiment of the device for mounting a lapping machine on a lathe according to the present invention, and the essential parts of the first embodiment. That is, FIG. 3 is a schematic vertical cross-sectional explanatory view of a main part of the horizontal feed table 9 which is shown by vertically cutting in the same area as the line P-P in FIG. 2. Note that FIG.
The same names and reference numerals are used for the portions common to the first embodiment shown in FIGS.

In FIG. 5, 9B and 9B are horizontal concave grooves provided on both side surfaces of the lateral feed base 9, 40 is a U-shaped locking tool, 4
Reference numerals 1 and 42 are lower locking pieces and upper locking pieces of the U-shaped locking tool 40, and 44 is a tightening bolt 44 screwed into the upper locking piece 42.
The lower end of the tightening bolt 44 contacts the upper surface of the substrate 22 of the polishing board 21.

Although not shown, the tightening bolt 44 is pivotally attached to the upper locking piece 42 and is pivotally operated so that a part of the cam surface projects from the lower surface of the locking piece 42 or is retractable. It can be replaced with a tightening mechanism using a tightening cam.

H ₆ is the lower surface of the substrate 22 of the polishing table 21 and the shaft 2
4, H ₇ is the thickness of the spacer 43, H ₁ is the distance between the axis 24 of the polishing table 21 and the top surface of the transverse feed table 9, that is, the axis 24 of the polishing table 21. It is the height of the core, and H ₆ + H ₇ = H ₁ spacer 43 is placed on the horizontal top surface 9 C of the transverse feed table 9 and the substrate 22.
The same as the polishing plate 21 of the second embodiment, the height of the shaft 24 of the polishing plate 21 is adjusted to the height of the shaft center of the main shaft 5 so that the polishing efficiency is the same as that of the polishing plate 21 of the second embodiment. In addition, if the spacer 43 and the U-shaped locking tool 40 are prepared for the horizontal feed table 9 of the existing lathe 1 having different swings on the horizontal feed table 9, the height thereof can be increased. The polishing plate 21 having the same structure including the above can be mounted in the same manner as in the second embodiment.

The lower locking piece 41 of the U-shaped locking tool 40 is inserted into the concave groove 9B on the side surface of the lateral feed base 9, and the upper locking piece 4 of the same locking piece 40 is inserted.
After 2 is hung on the upper surface of the substrate 22 of the polishing board 21, the substrate 22 is clamped and fixed to the transverse feed table 9 by the tightening bolts 44.

The cutting tool 10B attached to the tool rest 10 (see FIG.
Other structures and operations of the third embodiment, including the turning procedure of the work W according to the reference), are almost the same as the structures and operations of the first embodiment.

The concave grooves 9B, 9B formed on the side surface of the transverse feed base 9 may be formed in a dovetail shape or a dovetail groove shape, or in a step shape. In this case, it is preferable that the lower locking piece 41 of the U-shaped locking tool 40 is formed in a shape whose cross-section is adapted to a dovetail shape or a dovetail shape. In addition, the concave grooves 9B, 9B are formed over the entire length of the side surface of the transverse feed table 9, on the opposite side thereof, that is,
It can also be formed on both sides of only the upper half of FIG.

(Effects of the Invention) Since the present invention has the above-mentioned structure and operates, the following unique effects can be obtained.

(1) Traverse table 9 on the carriage 8 of the lathe 1
The tool rest 10 is mounted on the front side of the lathe, and the grinder 21 is mounted on the opposite side thereof, and the shaft 24 cores of the grinder 21 are arranged in parallel with the main shaft 5 cores of the lathe 1 at substantially the same height. After the turning process of the work W by the cutting tool 10B on the tool rest 10 is completed, the work W clinging to the same chuck 6 is not removed from the same chuck 6 and is also ground to the same work W. Without positioning the polishing body 25 of the board 21,
Immediate polishing is possible.

(2) The tool rest 10 is attached to the front side of the transverse feed base 9 having the horizontal top surface 9C of the existing lathe 1 and the polishing disc 21 is attached to the opposite side thereof, and the chuck 6 of the same lathe 1 is attached.
Turning and polishing for the work W clinging to the workpiece is input to the control device 15 of the existing lathe 1 simultaneously with the turning and polishing feed command signals prior to the turning and polishing. As a result, with respect to the work W after the turning, the positioning of the polishing table 21 and the setting of the feed amount thereof can be continuously performed without the need for each case.

(3) Since the cutting tool 10B is attached to the tool rest 10 on the front side of the horizontal top surface 9C of the transverse feed base 9 and the polishing disc 21 is attached on the opposite side thereof, it is necessary to adjust the rotation direction of the spindle 5 and the like. Without this, a high relative polishing rate by the polishing body 25 of the polishing plate 21 can be easily obtained, and a device for attaching the polishing plate to the lathe can be obtained which can be expected to have high polishing efficiency.

(3) By installing the tool rest on the front side of the horizontal top surface of the transverse feed table 9 of the lathe 1 and the polishing board 21 on the opposite side thereof, the front side on the same transverse feed table 9 is provided. Since the turning process and the polishing process of the work W held by the chuck 6 on the spindle 5 of the lathe 1 can be continuously performed by the cutting tool 10B on the tool rest 10, the lathe 1 and the polishing machine 21 It is not necessary to secure a separate installation space and a separate operation space for them, and furthermore, the carriage 8 of the existing lathe 1
Since the feed control device 15 of the horizontal feed table 9 can be used as it is as the feed control device of the polishing plate 21, it is wider than the conventional example in which the feed control devices for the lathe 1 and the polishing plate 21 are separately required. The cost can be reduced.

(5) The height H ₂ from the horizontal bottom surface of the substrate 22 of the polishing plate 21 to the axis 24 of the polishing plate 21, the horizontal top surface 9C of the transverse feed table 9 and the five axes of the lathe 1. When the height H ₁ is equal to the height H ₁ , the same substrate 22 is fixed to the transverse feed table 9 by the bolts 28, and the height from the bottom surface of the substrate 22 to the axis 24 of the polishing plate 21 is increased. H
₃ and H ₆ are lower than the height H ₁ between the horizontal top surface 9C of the transverse feed table 9 of the lathe 1 and the five cores of the lathe 1, the thicknesses of H ₄ , H ₅ , and H ₇ are appropriately set. -By interposing the blades 32, 33, 43, therefore the height H ₃ of the polishing table 21,
H ₆ is the height H ₁ from the top surface 9C of the transverse feed table 9 to the five spindles
Even if it is lower, the height of the horizontal top surface 9C of the transverse feed 9 and the center of the main shaft 5 can be increased by appropriately using the spacers 32, 33, 43 having the thicknesses H ₄ , H ₅ , and H _7. The lathe 1 of the different types of lathes with different heights can be attached to the lathe 21 having a single structure including the height of the lathe 1, so that the lathe can be easily modified to a highly efficient lathe. 21 There is a cost advantage based on the common structure.

(6) Reciprocating motion (longitudinal feed) and cutting (horizontal feed) of the cutting tool 10B of the existing lathe 1 and the cutting tool 10B
While maintaining the function of the control device 15 in the existing lathe 1 having the function of compensating for the wear amount of the same, the control device 15 is provided with a tool after the turning by the polishing body 25 of the polishing plate 21.
Send a command signal for polishing W to the input section 15A, key
A transverse feed table 9 of the lathe 1 is preliminarily input together with a feed command signal for turning of the lathe 1 by an appropriate input means such as a board or a card, and prior to the turning.
The control function originally possessed by the control device 15 of the existing lathe 1 is almost the same as that of the control device 15 of the existing lathe 1, and the feed control function in the polishing process by the polishing body 25 of the polishing plate 21 is substantially unchanged. Available as

(7) Reciprocating table 8 and traverse table 9 of lathe 1
Since the control device 15 can be used as the feed control device 15 for the carriage 8 and the transverse feed 9 to which the normal polishing plate 21 is attached, the automatic feed controller 15 for the carriage 8 and the transverse feed 9 is provided. With the lathe 1 and the cost of the normal lapping machine 21 added to the cost, in other words, with the lathe that can be automatically polished continuously from the automatic lathe at a cost that is not much different from the cost of the existing lathe 1. It is possible to provide a lathe, which in turn facilitates the installation of a lathe with a controller equipped with an automatic polishing function in a small factory.

[Brief description of drawings]

FIG. 1 is a schematic vertical cross-sectional explanatory view of the essential parts of a first embodiment of an apparatus for attaching a lapping machine to a lathe according to the present invention.

FIG. 2 is a schematic front view of the first embodiment of the present invention.

FIG. 3 is a schematic vertical cross sectional explanatory view showing the first embodiment in a vertical cross section along the line P-P in FIG.

FIG. 4 is a schematic vertical cross-sectional explanatory view showing a cross-section of the transverse feed table in the same region as the line P-P in FIG. 1 of the essential part of the second embodiment of the device for attaching a lapping machine to a lathe according to the present invention. Is.

5 is a schematic longitudinal cross-sectional explanatory view of essential parts of the third embodiment of the present invention in which the transverse feed table is vertically cut in the same region as the line P-P in FIG. 1. FIG.

FIG. 6 shows an air mower mounted on the tool rest in place of the bite as a special use example of the lathe according to the first embodiment of the present invention.
FIG. 7 is a schematic explanatory view showing an action in comparison with an object in which a polishing body with a blade is attached to enable polishing of the inner diameter of the body to be polished.

FIG. 7 is a schematic plan view of a main part of a conventional lathe.

FIG. 8 is a schematic front explanatory view of a main part of a conventional lathe. (Description of symbols) 1 ... Lathe 3 ... Bed 4 ... Spindle base 5 ... Spindle 5A ... Rotation direction switching means 6 ... Chuck 7 ... Tailstock 8 ... Reciprocating carriage 8A ... Vertical feed handle 9 ... Side feed base 9A ... Side feed handle 9B ... Groove on the side of side feed base 9C ... Top face of side feed base 9 ... Tool rest 10A ... Tightening lever 10B ... Bit 10F ...... Tool 10B Wear amount detection sensor 10G ...... Polishing body 25 Wear amount detection sensor 15 ...... Control device 15A ...... Input unit 15C ...... Storage unit 15D ...... Central processing unit CPU 21 ...... Grinding machine 22 ... ... substrate 23 ... motor 25 ... polishing body 28, 30, 44 ... bolts 32, 33, 43 ... spacer 40 ... U-shaped locking tool 41 ... lower locking piece 42 ... upper locking piece H ₁ ...... cross-slides 9 top and the main shaft 5 distance between the heart H _2, H ₃ Substrate 22 lower surface of the H ₆ ...... grinder 21 and the shaft 24
Distance from the center H ₄ , H ₅ , H ₇ ... Thickness of spacers 32, 33, 43 G ... Abrasive body with air motor S ... Peripheral velocity of abrasive body G with air motor (linear velocity ) V: Work W circumference (linear velocity) W: Work

Claims (5)

[Claims] 1. A reciprocating table 7 on a bed 3 of a lathe 1 is provided with a lateral feed table 9, and a tool rest 10 is provided in front of the lateral feed table 9.
A polishing table 21 having a horizontal bottomed substrate 22 driven by a driving means such as a motor 23 is provided on the opposite side of the feed table 9, and a shaft 24 of the polishing table 21 has a shaft 24 core as a main shaft of the lathe 1. An apparatus for mounting a lapping machine to a lathe, which is parallel to the five cores and provided at substantially the same height. 2. A reciprocating table 7 on the bed 3 of the lathe 1 is provided with a lateral feed table 9, and a horizontal tool top 9 is provided with a mounting tool rest 10 for a cutting tool 10B on the front side thereof. Feeding stand 9
Of the polishing platen 21 having a horizontal bottomed substrate 22 driven by a driving means such as a motor 23 on the side opposite to the horizontal top surface 9C.
Is provided between the horizontal bottom surface of the substrate 22 and the horizontal top surface 9C of the transverse feed table 9 via spacers 32, 33 and 43, and the axis 24 of the polishing machine 21 is the lathe. 1. A mounting means 28 which is arranged parallel to the five main axes of the first spindle 1 at substantially the same height and which is capable of releasing the substrate 22 of the polishing board 21 and the transverse feed table 9 from each other.
A device for mounting a lapping machine on a lathe, characterized by being mounted by 30, 40, 44. 3. A tailstock 7 is provided at an end of a bed 3 extending laterally from a headstock 4 of a lathe 1, and a reciprocating table 7 is provided at the center of the bed 3, and the reciprocating table 7 is provided with a side surface. A lateral feed groove 9 having laterally long concave grooves 9B, 9B or an engaging step portion and having a horizontal top surface 9C is provided, and a tool rest 10 is provided on the front side of the horizontal top surface 9C of the horizontal feed pad 9. A horizontal bottomed substrate 22 is provided on the side of the horizontal top surface 9C of the transverse feed base 9,
A polishing platen 21 driven by a driving means such as a cutter 23, and the U-shaped engagement is made between the concave grooves 9B, 9B or the engaging stepped portion on the side surface of the transverse feed table 9 and the upper surface of the substrate 22 of the polishing platen 21. Ingredient 4
The lower locking piece 41 and the upper locking piece 42 of 0 are engaged with each other, and the upper locking piece 42 of the U-shaped locking tool 40 and the polishing plate 21
An apparatus for attaching a lapping machine to a lathe, characterized in that the upper surface of the base plate (22) is fastened with a fastening means such as a bolt (44) or a cam. 4. A reciprocating table 7 on the bed 3 of the lathe 1 is provided with a lateral feed table 9, and a bite 10B attached to a tool rest 10 is provided on the front side of the horizontal top surface 9C of the lateral feed table 9. By reciprocating the reciprocating table 8 and the lateral feeding table 9 and the lateral feeding command signal reciprocally input to the storage section 15C of the control device 15 provided at a proper place around the lathe 1 by the input means 15A. In the lathe 1 for automatically turning the work W attached to the chuck 6 at the end of the main spindle 5 of the lathe 1, the motor 23 and the like are driven toward the horizontal top surface 9C of the transverse feed base 9. Substrate 2 with horizontal bottom driven by means
2 is arranged, and a shaft 24 of the polishing plate 21 is provided.
The core is provided in parallel with the five main axes of the lathe 1 at substantially the same height, and the polishing body 125 is stored in the storage unit 15C of the controller 15 based on the polishing command signal previously input by the input unit 15A. After the transverse feed base 9 is retracted so as to come into contact with the peripheral surface of the turned work W, the reciprocating base 8 and the transverse feed base 9 are reciprocally moved and laterally fed, and the polishing body 25 is used. A device for attaching a lapping machine to a lathe, which is characterized in that the lapping is carried out. 5. The cutting tool 10B and the polishing body are provided at appropriate positions of the tool rest 9 and the polishing machine 21 provided on the front side and the opposite side of the horizontal top surface 9C of the horizontal feed platform 9 on the carriage 8 of the lathe 1. 25
Wear amount detection sensors 10F, 10G are provided, and the cutting tool 10B or the polishing body 25 by the sensors 10F, 10G is provided.
The control device 15 is provided with a compensating circuit for compensating for the shortage of the feed amount of the lateral feed base 9 due to the wear of the cutting tool 10B and the polishing body 25 by inputting the detection signal of the wear amount of the above into the control device 15. As a result, the abrasion amounts of the cutting tool 10B and the polishing body 25 are corrected based on the turning command of the cutting tool 10B and the polishing processing command signal of the polishing body 25, which are input in advance in the storage unit of the control device 15, 5. The apparatus for mounting a lapping machine on a lathe according to claim 4, wherein continuous working of turning and polishing of the work W is enabled by automatic feeding.