CH680089A5 - Holder for measurement probe - comprises axially displaceable protective tube retained by cylindrical spiral spring - Google Patents

Abstract

The measurement probe (1) is arranged in a basic body (3,13). Coaxial with this a protective tube (7) is displaceably located in the direction of the probe. The protective tube has two widened formations, the first (a) acting as a stop for the basic body, whilst the second (11) forms an annular pressure surface of a pressure chamber. A second annular surface represents a stop for an opposing part of the basic body (13). An inner annular surface of the second widened formation forms a surface movable in relation to the basic body. The protective tube is loaded in the pressure chamber (10) direction by a pressure-activated cylindrical spiral sping (15). The pressure chamber is connected by a channel (21) to a connection (19) for a pressurised coolant. USE - Probe as used in CNC machine tools.

Description

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CH 680 089 A5

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description

The present invention relates to a holder for a measuring probe, in particular for use in CNC-controlled machine tools with a disk turret.

Such controls are well known and proven (see Knaurs Lexikon der Technik, Munich 1988, Vol. 1, p. 174).

The probes required for this, also called sensors, work according to different methods. For example, a probe is described and illustrated in LUEGER, Lexikon der Technik, Stuttgart 1960, Vol. 2, p. 514.

In the case of metal-cutting machine tools, such probes are endangered by chips, tools and other mechanical influences which cause the risk of incorrect measurement results or information. Downtimes with corresponding interruptions in operation can also result from damaged measuring devices.

The present invention therefore has the object to provide a holder for a probe, which does not have the disadvantages mentioned above, which in particular protects the probe against damage from the chips and which before and during the measurement process the probe with simple, safe and economic means exposed. After measuring, the protection of the probe should be restored under the same conditions.

The aforementioned object is achieved according to the patent claim in that a protective tube is arranged coaxially with the measuring probe arranged in a base body and that this protective tube is mounted so as to be displaceable coaxially to the direction of the measuring probe.

The advantage of the invention can be seen in the fact that the protective tube adequately protects the measuring probe with its probe against damage from the chips or another type and that the displaceable mounting of the protective tube enables simple control of the position.

According to claim 2, the protective tube expediently has a first and a second extension. These extensions primarily serve to limit the stroke of the protective tube, but they can also be used at least partially for the axial movement of the protective tube.

According to claim 3, the first extension is advantageously designed as a stop to the base body and the second extension forms an annular pressure surface of a pressure chamber, the other annular surface representing a stop to the opposite part of the base body. The extensions have the function of the stops of the protective tube for both sliding directions.

The claim 4 shows an expedient embodiment, wherein the inner annular surface of the second extension forms a movable surface of the pressure chamber with respect to the base body. The protective tube is pushed in one direction by increasing the pressure in the pressure chamber.

According to claim 5, the protective tube is loaded with a compression spring, preferably with a cylindrical coil spring, in the direction towards the pressure chamber.

This spring is used to hold the protective tube in one end position, expediently in the protective position, and to return it to this protective position after it has been brought into the other end position by other means, which exposes the probe with its probe.

Claim 6 specifies that the pressure chamber is connected to a channel for a pressurized cooling liquid by means of a connecting channel. Because a coolant line is practically always installed in machine tools, no new source for the pressure medium has to be provided. This is another very important advantage of the invention.

According to claim 7, the protective tube is provided with a lid. This cover protects the opening of the protective tube against the ingress of chips.

The cover can be disc-shaped or star-shaped. The shape is expediently dependent on the choice of material.

According to a development according to claim 9, the cover of the protective tube is provided with a central hole which is larger than the radial diameter of the probe and the probe. This solution enables the probe to be exposed even when the lid is on.

The invention is explained in more detail with reference to drawings. The same parts are provided with the same reference numbers in both drawings. The parts which are not necessary for the explanation of the invention have been omitted for the sake of clarity. Parts that are composed of several components for construction or assembly reasons are also drawn in one piece.

It shows:

Fig. 1 shows an example embodiment of the invention in longitudinal section, wherein the connector body for the cooling liquid is axially connected, and

Fig. 2 shows another example embodiment of the subject matter of the invention with a radial arrangement of the connector body for the cooling liquid.

A probe 1 with solenoid V has a probe 2. The measuring probe 1 is mounted coaxially in a tubular part 3 of the base body by means of disk-shaped holders 4. The round plate 5 is attached to the lower disk-like holder 4 with a spacer ring 6. A protective tube 7 is slidably disposed on the outer surface of the tubular part 3. It is partially covered with a lid 8. In Fig. 1, the cover 8 is star-shaped and provided with a central opening. The protective tube has a first extension 9 and a second extension 11. Between the second extension 11, an outer hollow body 12, an upper part of the base body 13 and the protective tube 7, an annular pressure chamber 10 is formed and sealed with annular seals 14. Between the first extension 9 of the protection5

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Pipe 7 and the lower part of the base body 13 is a compressive cylindrical coil spring which is mounted in a cylindrical space 16 for insertion. Parts belonging to the measuring probe 1 are arranged in the central room 17. In Fig. 1, a support body 18 is arranged axially and provided with a connection 19 for the cooling liquid. The connection 19 is connected in the axial direction to a channel 21 and in the radial direction to transverse bores 21 ′ with locking pins on the outside. A connection channel 21 is provided between the connection 19 and the pressure chamber 10. The offset of the connection 19 to the connecting channel 21 and to the pressure chamber 10 is realized by the transverse bores 21 '. Accordingly, the connection 19 is located behind the cut surface of the drawing,

Fig. 1.

The stroke 22 of the protective tube 7 shows the length by which the protective tube 7 is pushed in order to expose the measuring probe 1. The stroke 22 of the protective tube 7 shows the sufficient possibility to clear the protective tube 7 during the measuring process.

FIG. 2 essentially corresponds to FIG. 1. The difference is that the support body 18 is connected radially to the axis of the protective tube 7 in contact with the outer hollow body 12. The base body 13 and the outer hollow body 12 are square in their outer profile, but the space 16 for inserting the protective tube 7 is cylindrical. The consequence of this is that the walls of the square profiles of the base body 13 and of the outer hollow body 12 are thicker in the corners, so that the connecting channel 35 21 has sufficient space for connecting the cooling liquid. This position of the connecting channel 21 is clearly visible in FIG. 1. The cover 8 in FIG. 2 is disc-like. It is either full and then removed before measurement, or it has a central opening.

The operation of the present invention can be seen from the description of the drawings. If the probe 2 is not used for measurement, the entire probe 1 is protected with the protective tube 7 and possibly also with the cover 8 of the protective tube 7. The protective tube 7 is in this rest position in the upper position shown in the drawings, in which it is held with the cylindrical coil spring 15. 50 The probe is exposed before and during the measurement. The pressure of the cooling liquid in the pressure chamber 10 is increased to the normal value, and the protective tube 7 moves downward against the force of the cylindrical coil spring 15. 55 The normal pressure of the coolant of machine tools is sufficient because the cylindrical coil spring 15 is also of poor dimensions. The protective tube 7 moves until the second extension 11 strikes the lower part of the base body 60 13. After the measurement has ended, the supply of the cooling liquid into the pressure chamber 10 is interrupted and outflow from this pressure chamber 10 is made possible. This process is part of the CNC-controlled machine tool 65

feasible. With the falling pressure in the pressure chamber 10, the protective tube 7 is again moved with the help of the cylindrical coil spring 15 over the probe 1.

It goes without saying that the subject matter of the invention is not restricted to the two examples shown. For example, the support body 18 can also be connected at an acute angle to the base body 13 or to the outer hollow body 12, the connection 19 and the channel 21 can be replaced by a tube, and the measuring probe 1 can also be fastened with resilient elements.

The interface labeled M in both versions is designed as a standard connector in conjunction with inductive or capacitive probes; in the case of wireless measurement signal transmission, it can be omitted.

Claims (10)

Claims 1. Holder for measuring probe, in particular for use in CNC-controlled machine tools with a disk turret, characterized in that a protective tube (7) is arranged along the measuring probe (1) arranged in a base body (3, 13) and that this protective tube (7) is slidably mounted coaxially to the direction of the probe (1). 2. Holder according to claim 1, characterized in that the protective tube (7) has a first extension (9) and a second extension (11). 3. Holder according to claim 2, characterized in that the first extension (9) is designed as a stop to the base body (13) and that the second extension (11) forms an annular pressure surface of a pressure chamber (10) and that the other annular surface represents a stop to the opposite part of the base body (13). 4. Holder according to claim 3, characterized in that an inner annular surface of the second extension (11) forms a movable surface with respect to the base body (13). 5. Holder according to claim 3, characterized in that the protective tube (7) with a compression spring, preferably with a cylindrical coil spring (15), is loaded in the direction against the pressure chamber (10). 6. Holder according to claim 4, characterized in that the pressure chamber (10) is connected by means of a connecting channel (21) to a connection (19) for a pressurized cooling liquid. 7. Holder according to claim 1, characterized in that the protective tube (7) is provided with a cover (8). 8. Holder according to claim 7, characterized in that the cover (8) of the protective tube (7) is disc-shaped or star-shaped. 9. Holder according to claim 7, characterized in that the cover (8) of the protective tube (7) is provided with a central hole which is larger than the radial diameter of the probe (1) and the probe (2). 3rd 5 CH 680 089 A5 10. Holder according to claim 6, characterized in that the connection (19) for the cooling liquid is provided with a control device for the flow of the cooling liquid. 5 10th 15 20th 25th 30th 35 40 45 50 55 4th