FR2478301A1 - Tilt detector for e.g. cranes - has housing with oil filled concave interior containing ball, and proximity switch aligned over axis of concavity - Google Patents

Abstract

The device is fitted to a public works vehicle and indicates involuntary angular movement of the chassis in the longitudinal or transverse directions, to provide a warning when safety is jeopardised. The detector includes a body of circular section whose base is machined to provide a slightly conical profile. The cavity contains a steel ball and is filled with silicon oil and then closed by a cover with fixing screws and sealing gasket. An inductive proximity detector is mounted in the cover with its sensitive face close to the ball. The detector is connected to an audible or visible alarm and to a cut-out relay in the engine supply circuit. When the vehicle is tilted the ball moves and the alarm is operated.

Description

 The present invention relates to slope detectors intended to equip mobile public works vehicles such as hydraulic shovels, gondola lifts, mobile cranes, forklifts etc., in order to immediately reveal any transverse or longitudinal slope unwanted chassis, thus acting as a safety device.

 Slope detectors of this type known in practice use different principles. Thus, in particular, apparatus has been proposed in which the sensor element consists either of a pendulum or of a transparent ring filled with an opaque liquid. The precision obtained is remarkable, but on the other hand the detection of the angular deviation of the sensor element with respect to the normal orientation requires the intervention of optical and / or electronic devices, the complexity of which frequently affects the reliability of the whole device.

 The improvements which are the subject of the present invention are more particularly intended to remedy the drawbacks of conventional detectors and to allow the production of a simple and robust construction device, particularly well suited to the working conditions often severe treks of vehicles. public works mobiles.

 The level detector according to the invention is mainly remarkable in that it comprises in combination a box, the bottom of which is machined to present a substantially concave profile, a metal ball embedded in the oily damping product which fills said case, and a proximity detector of the inductive type oriented along the axis of the concavity of the aforementioned background.

 It will be understood that when the slope presented by the case fixed to the chassis of the mobile machine exceeds the angular value of the slope of the bottom, the ball moves outwards, thereby leaving the detection field of the inductive detector.

The appended drawing, given by way of example, will allow a better understanding of the invention, the characteristics which it presents and the advantages which it is capable of providing.
Fig. 1 is a schematic axial section of a tilt detector established in accordance with the invention.

 Fig. 2 reproduced fig. 1 in the event of a tilt of the machine on which the detector is fixed.

 Fig. 3 illustrates an alternative embodiment.

 Fig. 4 shows in axial section another embodiment of the slope detector.

 Fig. 5 is a plan view illustrating the arrangement of two devices according to FIG. 4 for the detection of the superelevation according to the two main orientations of the machine considered.

 In fig. 1 and 2 the reference 1 designates a horizontal part of the chassis of the mobile public works vehicle on which the tilt detector according to the invention is fixed. This detector comprises a case 2, advantageously established in a circular section; the bottom 2a of this case 2 has been machined to present a conical profile whose axis coincides with that of the side wall of said case, the angle of conicity being very small (in practice of the order of a few degrees). The cavity of the shoemaker 2 is filled with a silicone oil and also contains a steel ball 3 which obviously rests against the bottom 2a. The open upper part of the housing 2 is closed by a cover 4 fixed in place tightly using screws such as 5, some of these advantageously ensuring the assembly of the entire apparatus against the fixed horizontal part 1.

 The central part of the cover 4 is drilled and tapped axially to receive the body of a proximity detector 6 of the inductive type. The fixing is carried out so that the sensitive face 6a of this detector 6 is located a few millimeters from the ball 3 when that normally rests in the center of the conical bottom 2a. The detector 6 is connected to a safety relay which can activate an audible or light alarm and automatically cut off the power supply to the engine member of the vehicle in question, so that it comes to a standstill immediately.

 The operation of the apparatus described above follows from the foregoing explanations and is easily understood.

 If we assume that the angle of taper of the bottom is 30, we can imagine that when part 1 of the chassis of the machine presents with respect to the horizontal a slope greater than 30 in any direction, the ball 3 immediately moves towards the side wall of the boot 2 (fig.

2) and leaves the field of the detector 6, which has the effect of actuating the relay associated with the latter.

 The layout is very simple and therefore guarantees perfect reliability. The device works by all or nothing and it will be noted that it is positively safe since in the event of a break in the cable which connects it to the relay of the safety installation, it operates automatically.

It will also be noted that if the device is not adjustable, the operating threshold being fixed during the machining of the conical bottom 2a, this point can be considered as an advantage since in fact the detector is foolproof and its action does not depend in any way on the accuracy of the proximity sensor 6.

 Fig. 3 illustrates an alternative embodiment in which the case, here referenced 12, has a bottom 12a which is in the form of a spherical bowl or cap. In such a case, the position of the ball 3 varies as a function of the more or less pronounced tilt of the chassis of the machine in question, the triggering provided by the proximity detector 6 itself depending on the distance between said ball and the useful face 6a. of said detector. The device can therefore be adjusted on the machine by modifying the distance separating the ball 3 from the face 6a, that is to say by axially moving the body of the detector 6 relative to the cover 4 which supports the latter. .

 In the embodiment according to fig. 4, the cavity formed in the housing, referenced 22, can be considered as resulting from two bores with a horizontal axis and a conical profile, the large bases of the two profiles joining together by a rounded part whose radius is greater than that of the ball 3. Of course the cavity is closed in leaktight manner using lateral shutters 23. The positioning of the ball 3 on the bottom 22a thus obtained is detected by a detector 6 identical to that of fig. 1 to 3.

 In such a case it is quite obvious that the same device can only detect the possible superelevation in one direction, oriented along the axis of the cavity of the shoemaker 22. Under these conditions, for a permanent control of the superelevation in the two main directions we must use two detectors A and B (fig. 5) arranged perpendicular to each other on the chassis. The two detectors 6 can control a common relay or two separate relays. The assembly is foolproof and the detection of the slope in one direction is not influenced by the possible slope in the other direction.

 It goes without saying that, as a variant, it is possible to dig into the housing 22 a barrel-shaped cavity with a horizontal axis. We then return to a solution similar to that illustrated in FIG. 3, so that it is possible to adjust the sensitivity of the device by modifying the position of the detector 6.

 It should moreover be understood that the foregoing description has been given only by way of example and that it in no way limits the field of the invention from which one would not depart by replacing the details of execution described by all other equivalents.

Claims (4)

R E V E N D I C A T I O ~  1. Safety superelevation detector for mobile public works vehicles and similar applications, characterized in that it comprises in combination a housing whose bottom is machined to have a substantially concave profile, a ball embedded in the oily damping product which fills the cavity of said shoemaker, and a proximity detector of the inductive type oriented along the axis of the concavity of the aforementioned bottom.  2. Slope detector according to claim 1, characterized in that the bottom of the cavity has a conical profile.  3. Slope detector according to claim 1, characterized in that the bottom of the cavity is in the form of a spherical cap.  4. Slope detector according to claim 1, characterized in that the concavity has a substantially biconical profile with large bases facing one towards the other, the axis of this profile being oriented perpendicular to that of the proximity detector .