DE2840566A1 - Sensor for rotary movement acceleration - has object with projections in case, so that when case is rotated, it lags behind and closes circuit through contacts - Google Patents

Abstract

The sensor has a case (1) with an inner space (2) through which a flowing medium flows and acts on an object (3) with radial projections (4), supported by a bearing at its centre of gravity. The object is controlled by a spiral spring device (5) which tends to hold it in a certain position w.r.t. the case. The object centre is connected to a circuit whose other end is connected to contacts (6) in the case wall, so that when the case is rotated by a certain angle, the object lags behind owing to its inertia, and its projections (4) touch the contact (6) and close the circuit.

Description

The invention relates to a rotational acceleration sensor,

which responds to relatively quick rotation at a large angle. The sensor is designed to emit a signal in which an electrical circuit q is closed if there is a risk of a vehicle tipping over. The sensor should neither be activated when the vehicle turns a small angle around its Longitudinal axis tilts, e.g. when repairing the chassis when the vehicle is inclined at an abnormally large angle. The invention is therefore the task based on creating a rotational acceleration sensor that prevents a vehicle from tipping over prevents, but normal inclinations of the vehicle as well as greater inclinations e.g. allowed during repair work.

This object is achieved according to the invention by the claims 1 specified features. Appropriate refinements of the invention emerge from the sub-speakers.

The invention is explained below with reference to FIGS. 1 to 5, for example explained. The figures show: FIG. 1 a cross section of the sensor and FIGS. 2 to 5 corresponding thereto Cross-sections of the sensor at different angles of rotation and different Angular velocity.

The rotational acceleration sensor consists of a housing 1 whose Inner space 2 is filled with a fluid. A body 3 is through bearings stored in its center of gravity and is subject to the influence of a device 5, which strives to keep the body in a certain position with respect to the housing. The body is provided with radial projections 4. The middle of the body is connected to an electrical circuit, the other end of which is connected to contacts 6 in the Wall of the housing is connected. These contacts are arranged so that after a rotation of the housing through a certain angle at which the body due to lags behind its inertia, the projections 4 of the body touch the contacts 6 and this closes the electrical circuit.

In an advantageous embodiment, the device 5, which strives to keep the body 3 in a certain position, a spring. At a In another embodiment, the resetting can be achieved by magnetic influence or in in another suitable manner.

The return spring connects in the advantageous embodiment the center of the body 3 with the electrical circuit.

All angles between the projections 4 amount to the advantageous Embodiment 1200, and the angles between the contacts 6 in the wall of the housing are also 1200. With a certain position of the body in relation to the housing are the projections 4 along the bisector of the angles between the contacts 6 aligned.

The sensor responds to the speed of rotation and the angle of rotation at. How it works is described below.

If the sensor is rotated through a small angle, the smaller than the angle between the projections 4 and the contacts 6, the electrical remains Circle open, as Fig. 2 shows. If the sensor maintains its new position, it reverses the body 3 returns to its rest position with respect to the housing after a short period, how Fig. 3 shows.

If the sensor is slowly rotated through a large angle, it works the spring force on the body 3 such that the return of the body 3 with respect to of the sensor housing 1 is faster than the rotation of the sensor housing. To this In this way, the electrical circuit remains open during the entire rotation of the sensor.

However, if the sensor rotates quickly through a large angle is subject, the spring 5 fails to move the body 3 with respect to the sensor housing reset so that the projections 4 touch the contacts 6 and the electrical Circuit is closed so that the sensor trips. This is shown in FIG. if the rotation continues, the body 3 is rotated together with the sensor housing 1, and the electrical circuit remains closed, as Fig. 5 shows.

Claims (5)

Rotational acceleration sensor claims 0 rotational acceleration sensor, g e k e n n n z ei c h -n e t by a housing (1), the interior (2) of which with a Fluid is guided in which a body (3) with radial projections (4) is supported by bearings in its center of gravity, whereby the body is subject to the influence of a Device (5) which strives to keep the body in a certain position with respect to the housing, and in that the core of the body with an electrical Circle is connected, the other end of which is connected to contacts (6) in the housing wall is, which are arranged such that after a rotation of the housing to a certain Angle at which the body (3) lags due to its inertia, the projections (4) of the body's contacts (6> touch and thereby the electrical circuit conclude. 2. Sensor according to claim 1, characterized in that g e k e n n -z e i c h n e t, that the device that strives to the body (3) in a certain position keep, is a feather. 3. Sensor according to claim 2, characterized in that g e k e n n -z e i c h n e t, that the spring (5) connects the center of the body (3) and the electrical circuit, 4. Sensor according to claim 1, characterized g e k e n n -z e i c h n e t e that the device (5) e that tries to keep the body (3) in a certain position, a magnet is. 5. Sensor according to one of the preceding claims, characterized in that g e k e n n z e i c h n e t that all angles between the projections (4) are 1200, that all angles between the contacts (6) in the wall of the housing are 1200, and that when the body is in a particular position, the projections of the body are directed along the bisector of the angle between the contacts (6).