SU1313647A1 - Lathe chuck - Google Patents

Abstract

The invention relates to a machine tool industry, in particular, to devices for controlling the position of a part in lathe chucks. The purpose of the invention is to improve the reliability and speed of the device to control the correctness of the workpiece base in the lathe chuck. When the cartridge power is turned on, the compressed air jet enters one of the receiving nozzles 2, under which the membrane 6 opens, under the action of air pressure, the other nozzles are closed by the membrane. Next, the air enters the ejector 3, from the side channel 10 of which, with the open remote nozzles 4 connected to the outlet 9 of the ejector 3, air is ejected. After installation in the workpiece cartridge, if it occupies the correct position, outflow of air under pressure at the side channel 10 begins, corresponding to the response pressure of the secondary transducer 12, which causes the command to secure the workpiece and its subsequent processing. 2 Il. (L vt jaio / noSar

Description

The invention relates to a machine-building and can be used to indicate the correctness of the positioning of parts in rotating devices.

The purpose of the invention is to increase the reliability and speed of the device controlling the correctness of the workpiece in the lathe chuck.

FIG. 1 shows a lathe chuck; in fig. 2 is a view A of FIG. one.

The lathe chuck includes a housing 1 in which a device for controlling the correctness of the workpiece base is placed, including receiving nozzles 2, ejector 3, remote nozzles A, an annular sector chamber or ring 5, a membrane 6, an annular groove 7 and flexible spiral hoses 8. Receiving nozzles 2 are associated with the chamber 5 in the form of an annular sector or a ring comprising a plate non-return valve made in the form of a free membrane 6 clamped at an average diameter. The input part of the receiving nozzles 2 is located on the same arc with schagom, smaller in diameter, and the output part lying in the plane of the membrane is arranged in a checkerboard pattern. The remote nozzles 4 are connected by flexible spiral hoses 8 with an annular groove 7 in the housing 1 connected to the outlet 9 of the ejector 3, and the side channel 10 is connected to the sensitive element 11 of the secondary transducer 12, the receiving nozzles 2 are connected to the chamber 5 in the form of an annular sector or rings containing a plate check valve, made in the form of a free membrane 6, clamped by the average diameter, with the output part of the receiving nozzles located on the same arc with a step smaller than their diameter, and the output part lying in the plane of the membrane is located in chess order. Outside the chuck, nozzle G is installed on the machine body, to which compressed air is supplied. Performing the input part of the receiving nozzles on one arc with a step smaller than their diameter allows to bring the error in the change in pressure of the power supplied to the ejector 3, caused by the mismatch of the axis of the supply nozzle with the axis of each receiving nozzle, up to 4-6%, which is enough to ensure the error basing

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Product no more than 0.01-0.015 mm. Performing the output part of the receiving nozzles in staggered order ensures reliable closure by the diaphragm of the rest, which lie away from the receiving nozzle of the receiving nozzles.

The external nozzles 4 are connected by flexible spiral hoses 8 with an annular groove 7 in the housing connected to the outlet 9 of the ejector, with the cross-sectional area of the annular groove equal to the total cross-sectional area of the hoses and 8-12% more than the total cross-sectional area of the external nozzles.

An increase in the cross-sectional area of the annular groove larger than the total cross-sectional area of the hoses leads to an increase in its volume and an increase in the response time of the device, and a decrease to a decrease in the sensitivity. device. A decrease in the ratio of the cross-sectional area of the annular groove and the total cross-sectional area of the external nozzles less than the specified one leads to an increase in the resistance to air flow, which reduces the speed, and an increase above the specified limit reduces the sensitivity.

f5

20

25

Lathe chuck works as follows.

When powering up the cartridge

35 with compressed air from the nozzle 13 a stream of air flows to one of the receiving nozzles 2, under which the membrane 6 opens; under the action of the pressure of the air filling the chamber 5, the nozzles 2 are closed by the membrane 6. From the chamber 5, the air enters the ejector 3, from the side channel 10 of which, with the remote nozzles 4 open (when the cups 14 under the effect of the jets flowing out of the nozzles) extreme right positions) air is being ejected. After installation in the cartridge, the billet, if it takes the correct position determined by the gaps between nozzles 4 and cups 14, smaller than guaranteed - 0.002-0.004 mm - from the side channel 10 of the ejector 3 starts the outflow of air under pressure, corresponding to the response pressure of the secondary converter, which issues a command to secure the workpiece and subsequent processing of the part.

Formula

3

3 o

bratis

A lathe chuck comprising a housing in which a device for controlling the base of the workpiece is placed, including receiving nozzles connected to an ejector supply channel, the output of which is connected to external nozzles, and a side channel connected to a sensitive element of the secondary transducer, characterized in that ensure the reliability and speed of the validation device

the billet base between the receiving f5 is larger than the total cross-sectional area of the sockets and the feeding channel of the ejector; in the housing there is an annular chamber in which a check valve is installed, made in the form of an annular membrane clamped to the middle

1313647

diameter, the input parts of the receiving nozzles are located on the same arc with a step smaller than their diameter, and the output parts lie in the plane of the membrane and are alternately arranged at different diameters on both sides of the average diameter of the membrane, in addition the remote nozzles are connected to the output of the ejector through the flexible spiral pshangs introduced into the device and an annular groove made in the housing, the annular groove cross-sectional area being equal to the total cross-sectional area of the hoses and by 8-12%

nozzles, and the side channel of the ejector is made in the form of a nozzle, contactlessly connected with the sensitive element of the secondary transducer removed from the body of the cartridge.

Ft 2

Claims (1)

Claim A turning chuck comprising a housing in which a workpiece basing device is located, including receiving nozzles connected to an ejector feed channel, the output of which is connected to remote nozzles, and the side channel is connected to a sensitive element of the secondary converter, characterized in that, in order to increase reliability and speed of the correctness control device. based on the workpiece between the receiving nozzles and the feed channel of the ejector, an annular chamber is made in the housing, in which a check valve is installed, made in the form of an annular membrane clamped to an average diameter of 20> 47 4, and the input parts of the receiving nozzles are located on the same arc with a step smaller their diameter, and the output parts lie in the plane of the membrane and are located alternately on different diameters on both sides of the average diameter of the membrane, in addition, the remote nozzles are connected to the ejector exit through the entered in 10 devices flexible spiral hoses and an annular groove made in the housing, and the cross-sectional area of the annular groove is equal to the total cross-sectional area of the hoses and is 8-12% 15 larger than the total cross-sectional area of the remote nozzles, and the side channel of the ejector is made in the form of a nozzle contactlessly connected to the cartridge sensitive element of the secondary converter. Type A FIG. 2