DE3620131A1 - Depth measuring instrument - Google Patents

Abstract

The invention relates to a device for measuring depths. The measurement is performed using an automatically extending feeler. The feeler is driven by a spring element via a drag lever. An eccentric element acts under rotation on the drag lever and thus controls the measuring stroke and the return stroke of the feeler. In order to provide the feeler with a dosed, adjustable measuring force, the feeler is arranged displaceably in a driving link, and its circumference is acted upon by adjustably spring-loaded braking elements. The eccentric element is preferably motor-driven and has switching elements which stop it respectively at the lower and upper vertices. The value of the depth determined by the feeler is transmitted via a transmission element to a preferably electronic measuring device, and can be further processed from there. It is preferable to provide a digital display device. In one possible embodiment, the measuring instrument is surrounded by a housing which permits it to be used as a hand-guided instrument. The feeler is sealed in the base plate against contamination.

Description

The invention relates to a measuring device for measuring Depths using a stylus over a lever system controlled by an eccentric element and is moved by a spring element, extends.

Depth gauges are known in which the key pin by springs or by hand to the measuring point is pressed. These systems have the disadvantage that Measurement result of qualification and skill depending on the operator.

The invention is therefore based on the object Depth gauge to develop that regardless of the Operation consistently reproducible measurement results brings.

According to the invention, the object is achieved as follows:

A stylus is stored in a guide cylinder by a spring-loaded rocker arm in its axle direction shifted.

The carrier carries the stylus backdrop, the two laterally arranged trunnions points. The zylin forms the core of the driver set drische guide piston, which in its axial direction Guide of the stylus is pierced centrally. Across the trunnions each have a continuous center Hole on both ends of the trunnion with internal winches are provided. Be in these two holes Brake elements, preferably made of plastic, introduced, by means of adjustable spring elements on the circumference of the stylus. The setting of the compression springs takes place via the threads in the internal thread pencils. By means of this setting option, a  any pressing force of the braking elements, preferably made of plastic, on the stylus. Thereby it is possible for the stylus the desired measuring preselect by force.

The stylus is centered and in the driver link axially displaceable. The takeaway backdrop is in turn centered in the guide cylinder fitted axially displaceable. The guide cylinder be sits opposite on its circumference in the longitudinal axis openings arranged horizontally, in the form of elongated holes, which are open on one side for assembly. Furthermore points the guide cylinder one arranged in the longitudinal axis Slit on. This moves the movement of the Stylus transmitting element. The guide cylinder has a flange at its lower end to it Fastening on the base plate. Is in this flange the space for a sealing lip to seal the probe pen incorporated. The bottom floor of the Zylin serves as a fixed stop for the driver link, this ensures the reproducibility of the measurements accomplishes. On the top face of the cylinder a lid attached as an upper stop. That attack results in the zero position of the stylus.

To the movement of the rocker arm on the driver link to transfer, there is one on each trunnion movable bell that is transverse to its axial direction, however outside the hole for the trunnion, another Bore for the flexible mounting of the rocker arm owns.

The fork-shaped rocker arm can be rotated in a bearing attached to the base plate. Rolls in the preferred place during the measuring process, preferably motor-driven Eccentric element, by means of a rotatably mounted roller, on the rocker arm.  

It is possible to use the eccentric element as a crank training poor, then the role is on the Crank pin. Another possible embodiment sees before using a disc-shaped eccentric element the preferred location of the Rocker arm a rotatably mounted roller.

Act on the rocker arm at a preferred location of the spring element constantly presses the rocker arm against that Eccentric element. The preferably motor-driven Eccentric element has a switching element, which over an electrical switch on the eccentric element desired position stops. In one possible execution the upper and lower vertices are shaped for this point of the eccentric movement selected.

The measuring process of this depth measuring device runs as follows from:

After placing the device over the measuring point the preferably motorized drive of the eccentric element, which is in the starting position, via an elec trical switch turned on. The eccentric element be begins to turn and continuously tows lever in the direction of force of the spring element that the key pin drives, free. Thereby, through the force suspension of the spring element via rocker arm, movable Bells and driver backdrop of the stylus in the measuring direction extended.

After reaching the measuring point, the stylus remains underneath Delivery of his preselected measuring force. Because too the eccentric element rotates further at this point in time, can the spring element the rocker arm and thus the Mit Continue pushing the subscriber backdrop until it comes to the system the stop surface comes.

This process of pushing forward is made possible light that the two adjustable spring-loaded  preferably made of plastic brake elements press the stylus with braking effect. After this Striking the driver link on the bottom of the guide cylinder continues to act the force of the spring element on the rocker arm and thus on the driver link. The eccentric element is at rest at this time. A special embodiment sees in this position of Eccentric element a gap between the pressure roller of the eccentric element and the rocker arm. By the transmission element arranged on the stylus can the measured depth value in a special version form on an electronic measuring device preferably digital display can be transmitted. To Acquisition of the measured value displayed in this way by the operator nungsperson can now be the return stroke of the stylus. This is done by switching on the preference again as electric drive of the eccentric element. The Eccentric element begins to rotate again and presses over the roller the rocker arm back into the exit position. The stylus has a collar on the Driver link strikes on the return stroke, so the Stylus in the guide cylinder up to the zero position withdrawn. The device is now ready for the next measurement operation ready.

The drawings show a possible embodiment in a schematic representation.

On well-known components such as housing, drive motor and Switch, as well as the electrical wiring was in the drawings consciously for reasons of clarity waived. It shows

Fig. 1 measuring system in sectional view and plan view,

Fig. 2 side sectional view of the Meßsystemes- stylus in the initial position,

Fig. 3 side sectional view of the measuring system stylus in the extended position.

The individual figures are described in more detail below described.

Fig. 1 shows the measuring system in sectional view and top view, the stylus ( 1 ) is shown in the extending movement in the measuring direction ( 10 ). The driver link ( 2 ) runs in the longitudinal direction in the guide cylinder ( 3 ) and houses the two brake elements ( 4 ), the spring elements ( 5 ) and the screws ( 6 ) acting on them in the bores of their support pins. The end of the two braking elements ( 4 ) act on the circumference of the stylus ( 1 ). Using the screws ( 6 ), the force of the spring elements ( 5 ) can be set on the stylus ( 1 ). The stylus ( 1 ) has a collar for guidance in the cylinder ( 3 ), which is fitted into the bore of the cylinder ( 3 ). The trunnions are enclosed by the bells ( 7 ). The bells ( 7 ) have a transverse bore, which allow the drag lever ( 8 ) to be displaced in the longitudinal direction. The rocker arm ( 8 ) is pressed during the measuring stroke ( 10 ) by a spring element ( 17 , Fig. 2) against the lower stop surface in the guide cylinder ( 3 ). The speed at which the stylus ( 1 ) or the driving link ( 2 ) moves is determined by the speed of the eccentric element ( 9 ). During the return stroke, the rocker arm ( 8 ) is raised by the eccentric element ( 9 ). The sealing of the measuring system against dirt and moisture, which is preferably accommodated with its drive and its switching and control elements in a housing, is accomplished with the sealing element ( 12 ), which can be arranged between the base plate ( 13 ) and guide cylinder ( 3 ) . The upper stop for the stylus ( 1 ) in its zero position is formed by the cover ( 14 ) connected to the guide cylinder ( 3 ). The depth value measured at the measuring point ( 11 ) is brought to a preferably electronic measuring device ( 16 ) by means of the transmission element ( 15 ) on the stylus ( 1 ). Since the stylus ( 1 ) and the transmission element ( 15 ) form a rigid unit, the measurement error is limited to the accuracy of the electronic measuring unit ( 16 ) and the play of the braking elements ( 4 ) in their receiving bore.

Fig. 2 and 3 show the measurement system in the side view. In Fig. 2, the stylus ( 1 ) is in the starting position, this position corresponds to the depth measurement value assigned, the zero position. Furthermore, the arrangement of the spring element ( 17 ), the eccentric element ( 9 ) with its rotatably mounted roller ( 18 ) and the bearing ( 19 ) for the rocker arm ( 8 ) is shown as an example of a possible embodiment. In Fig. 3 the remaining gap ( 20 ) between the drag lever ( 8 ) and the rotatably mounted roller ( 18 ) of the eccentric element ( 9 ) can be seen. This gap ( 20 ) is required to ensure that the driver link ( 2 ) lies perfectly on the lower stop surface of the guide cylinder ( 3 ) during the measuring process.

Claims (9)

1. Measuring device for measuring depths, characterized in that a in a guide cylinder ( 3 ) and in a slave link ( 2 ) guided stylus ( 1 ), on the circumference preferably press two brake elements ( 4 ) by a spring-loaded rocker arm ( 8 ), which acts on the driver link ( 2 ), controlled by the eccentric element ( 9 ), extends. 2. Depth measuring device according to claim 1, characterized in that the guided within the driver pin ( 1 ) by two braking elements ( 4 ) acting on the order of the same by two adjustable spring elements ( 5 ) during the measuring stroke ( 10 ) to to reach the preselected measuring force, when it is in contact with the measuring surface ( 11 ), is transported by the rocker arm ( 8 ). 3. Depth measuring device according to claim 1 and 2, characterized in that the driver link ( 2 ) after the stylus ( 1 ) with the preselected measuring force presses on the measuring surface ( 11 ) by the spring-loaded rocker arm ( 8 ) is pushed until the same releasing the spring force of the spring element ( 17 ) onto the stop surface of the guide cylinder ( 3 ). 4. Depth gauge according to claim 1 to 3, characterized in that the spring-loaded rocker arm ( 8 ), which transports the stylus ( 1 ), by the rotation of the position-dependent eccentric element ( 9 ) controls ge, under the action of the spring element ( 17 ), executes the measuring stroke ( 10 ). 5. Depth measuring device according to claim 1 to 4, characterized in that the rocker arm ( 8 ), driven by the further rotation of the eccentric element ( 9 ), overcoming the spring force of the spring element ( 17 ), executes the return stroke. 6. Depth measuring device according to claim 1 to 5, characterized in that the spring-loaded rocker arm ( 8 ) for a further possible embodiment, one, depending on the desired transmission ratio, has a differently arranged bearing point ( 19 ). 7. Depth gauge according to claim 1 to 6, characterized in that the spring-loaded rocker arm ( 8 ) is replaced in a further possible embodiment by a spring-loaded rocker arm, which rocker arm can have different lever arm lengths and different offset angles depending on the selected embodiment. 8. Depth measuring device according to claim 1 to 7, characterized in that the preferably motor-driven eccentric element ( 9 ), which controls the spring-loaded rocker arm or rocker arm ( 8 ), as a rotating eccentric disc rolling on a rotatably mounted roller, which is in a preferred location of the rocker arm or rocker arm, be fastened, is executed, a further possible embodiment provides that the eccentric element as a rotating crank arm ( 9 ), which has a rotatable roller ( 18 ) on the crank pin, unrolling on before tensioned and specially machined Location of the rocker arm or rocker arm ( 8 ). 9. Depth measuring device according to claim 1 to 8, characterized in that in one possible embodiment, the measured depth value is transmitted by a transmission element ( 15 ) to a preferably electronic measuring device ( 16 ) and from there, for example, to a digital display device.