FR2841654A1 - Rattling sensor, for automobile, has housing with two parts, each with lateral walls having pillars extending parallel to axis of stack comprising electrodes and piezoelectric component, and into openings made in wall of other part - Google Patents

Abstract

The sensor (1) has a stack of electrodes (15a, 15b) and a piezoelectric component (13) mounted in an insulative housing (7). The housing includes two identical parts (9, 11), each with a lateral wall (9b, 11b) having pillars (29a, 29b, 31a, 31b) extending parallel to the axis of the stack. The pillars in one part are configured to extend closely into openings (39a, 39b, 41a, 41b) made in the wall of other part. An independent claim is also included for a rattling sensor fixing assembly.

Description

I The invention relates to a vibration sensor and an assembly

  comprising this sensor and means for fixing the sensor to a vibrating structure. The sensor of the invention is in particular intended to be installed in motor vehicles, in contact with the engine block, typically to constitute an accelerometric sensor and more particularly a sensor sensitive to the phenomenon of rattling which regularly affects operation.

internal combustion engines.

  In the past, vibration sensors have already been proposed, and

  especially knock sensors.

  Thus, sensors are already known comprising, along an axis, a stack of elements including an element made of piezoelectric material and electrodes in electrical connection with this element, the electrodes having connection pins so that the sensor can transmit data

relating to the vibrations received.

  In this context, the invention aims: - to promote cohesion between the stacked elements of the sensor, to limit what can disturb the homogeneity of the transmission of vibrations that the sensor is responsible for detecting, while promoting quality of the electrical signal which it delivers, - to constitute a unit which can be easily manipulated during assembly and to allow overmolding of the assembly without disturbing the sensitive elements of the sensor, since once the elements are stacked, their cohesion is reinforced by an overmolding of plastic which protects them, - reducing the general cost of the sensors, - promoting mechanical protection in particular of the sensitive elements of the sensor, in particular during the overmolding operation, or even when the sensor is fixed to the vibrating part for which it is responsible for detecting vibrations. To satisfy all or part of these requirements, it is provided, according to an important characteristic of the invention, that the element made of piezoelectric material and the electrodes of the sensor are housed in a housing comprising at least two separate parts each having a side wall. at the outer periphery, at least one of these side walls having, or comprising, pillars engaging in openings formed in the side wall of the other part, these pillars extending substantially parallel to the axis of stacking of elements. For effective retention of the housing parts therebetween, it is furthermore advised that the pillars engage relatively tightly in the openings, to ensure a rotational retention of one part of the housing relative to the other, around the axis of stacking of the elements, which axis also constitutes an axis of the housing in the direction of approximation or spacing

of both parties.

  To both promote the maintenance of parts of the housing between them, as above, and standardize the manufacture of this housing by limiting the costs, another characteristic advises: - that the two housing parts are identical, - and that the side wall of each part is cut in the manner of a toothing, these toothing being interengaged along the stacking axis of the elements. To hold the stacked elements inside the housing, the side wall of at least one, preferably two, part (s) of the housing has an interior surface with local protuberances to impose a forced engagement of the stacked elements in the corresponding housing part,

  the section of these elements being defined accordingly.

  In the past, it has already been proposed to fix the sensor to the vibrating structure using a bolt passing through an axial hole, the elements

  stacked in the sensor then typically consisting of washers.

  Whether the fixing is ensured by a bolt or by other equivalent means (rivets, etc.) adapted to pass through such an axial hole, another characteristic of the invention provides that: - each housing part has a bottom from which stands the outer peripheral side wall, - and at least one of these bottoms can be crossed by an axial orifice bounded radially by an inner side wall of the corresponding part of the housing, - the stacked elements then being annular, so as to be arranged

  between the inner and outer side walls of the housing parts.

  It will also be noted that, independently of the construction in teeth of the two parts of the housing, an identical production of these two parts is advantageous, all the more if the sensor has such an axial orifice, in particular for reasons of cost reduction. , interchangeability and complementarity. As already indicated, it is known to coat the stacked elements of a vibration sensor with a coating material injected under pressure.

around these elements.

  In the context of the invention, it is advisable in this respect that the bottom of one (preferably of the two) housing part (s) crossed by the aforementioned axial orifice has (are) grooves for promote the circulation of such matter

to the center of the sensor.

  An advantage of realizing the sensor in this way by housing its elements stacked inside a box is that it can be avoided that this box, which holds the elements, constitutes an electrical mass and, consequently, the addition of parts

  insulation does not appear as a strict requirement.

  Under these conditions, it is advantageously provided that: - the housing is made of an electrically insulating material, advantageously plastic, - the element made of piezoelectric material and the electrodes are in direct contact with at least one parts of this housing, without interposition

  electrically insulating element.

  the stacked elements comprise an additional element constituting a seismic mass, and one of the electrodes is interposed between this seismic mass and

  the element made of piezoelectric material, being in direct contact with them.

  As regards the mounting of the sensor on its vibrating structure (typically therefore the engine block of a vehicle), the invention recommends that the assembly made up comprises: - the sensor with all or part of the above characteristics, - as well as fixing means engaged on the sensor and on the vibrating structure, these fixing means comprising a clamping means for clamping the sensor against the vibrating structure, along the axis of the sensor, favoring engagement of the pillars of the '' one of the parts of the housing in the

other party's openings.

  A more complete description of the invention will now be provided in

  reference to the appended drawings in which: FIGS. 1 and 2 are perspective views of an embodiment of the sensor of the invention, respectively in a state dissociated from its elements and from the housing, and in a combined state ready for overmolding, FIG. 3 is a sectional view of the sensor in FIG. 2, along the section line 111-111, FIG. 4 is a sectional view along the line IV-IV of FIG. 3, with addition taking account of the view of Figure 2, and Figure 5 is a schematic sectional view of a method of fixing the

  sensor to a support capable of transmitting vibrations.

  The sensor marked 1 in the figures is a vibration sensor and more particularly a knock sensor responsible for detecting vibrations.

  transmitted by the engine block 3 (see Figure 5) of a motor vehicle.

  The sensor 1 comprises a series of stacked elements 5 whose role is to capture the acoustic vibrations and transform them into an electrical signal, which is transmitted to a computer 6 designed to process this information and to make, if necessary, a correction during engine operation (see

figure 2).

  The stacked elements 5 are housed inside a housing 7 comprising two complementary parts 9, 11, in the sense that once the parts are assembled, the housing constitutes a globally closed assembly protecting and bringing together

  together the stacked elements 5 hereinafter called "sensitive elements".

  These sensitive elements include in particular a piezoelectric element 13 interposed between two electrodes 1 5a, 1 5b.

  The electrodes 15a, 15b are each attached to one of the two opposite faces of the element 13 and are therefore separated from each other. Each electrode has a pin 17a, 17b by which the electrical data supplied by the element made of piezoelectric material 13 will be transmitted to the computer. As can be seen in FIG. 1, starting from the bottom of the stack, there is first in the illustrated embodiment and along the stacking axis 19, the first electrode 15a, the element 13 made of piezo material electric, the second electrode 15b, then a block 21 constituting a seismic mass. Typically, it

it is a metal block.

  Such a stack can be directly housed, thus stacked axially, inside the housing 7, when its two parts 9, 11 are axially brought together,

as shown in figure 2.

  For effective protection and maintenance of the elements 5, each housing part comprises a bottom 9a, 1 la from which stands a side wall

exterior 9b, 11b.

  In the assembled state, the outer side walls 9b, 11b extend

  substantially parallel to the stacking axis 19.

  For effective retention of the sensitive elements 5 inside the housing, the internal surface of the external lateral wall of each housing part has projecting protrusions marked 23 in FIG. 4, and the section of the stacked elements is adapted so that these elements are forcibly committed to

  inside the housing parts, in close contact with the protuberances 23.

  In Figure 4, the section shows the housing part 9 and we can see the second electrode I5b clamped at the outer periphery against protuberances

  23, the figure making it possible to see the pin 17a of the first electrode.

  In view of FIGS. 1, 2 and 4, it can also be seen that the side walls 9b, 11b extend along angular sectors and are therefore not continuous

according to the perimeter.

  In the illustrated embodiment, these side walls somehow each define a toothing oriented parallel to the axis 19, with its pillars such as 29a, 29b; 31a, 31b, and its openings, such as 39a, 39b; 41a, 41b. Such a crenellated shape allows (by relative displacement along the axis 19) to the pillar of one of the parts to engage in the openings of the other part of the

housing 7.

  Advantageously, the angular sector along which the pillars of one of the parts develop advantageously corresponds, in a relative angular position determined with respect to the axis 19 of one part with respect to the other, to the sector of the openings of the other part, so that in the engaged or nested state of FIG. 2, an angular blocking of a part is obtained

of housing relative to each other.

  In this position, it can be seen that the pins 17a, 17b pass in turn through two openings 33a, 33b, of identical cord It barely greater than the width 12 of each pin 17a, 17b. These openings are

  separated by a narrow wall 35.

  Since, preferably, the two parts 9, 11 of the housing are identical, the other part 9 is HERE provided with the same two cutouts of rope II close to one another. However, in FIGS. 1 and 2, these two narrow cutouts are invisible and it is the large opening 39a that we see, in FIG. 2, receiving

  the area where the pins 17a, 17b are arranged.

  In FIG. 5, the sensor 5 has therefore been illustrated with its sensitive elements protected in their casing and kept tight together and against the vibrating structure 3 by means of a clamping means 37 ensuring a pressure

along axis 19.

  The clamping means 37 is a bolt tightened in a thread 43 that

  has an orifice 45 of the vibrating structure 3.

  To control the pressure exerted on the sensor 1 (and in particular on its sensitive elements), while ensuring flawless retention of this sensor with respect to the vibrating structure 3, an intermediate tubular part 47 is provided. This intermediate piece 47 comprises a tubular ft 49 defining a spacer extending between the bearing surface 3a of the structure 3 and the head 37a of the bolt. On the side of the head 37a, the tubular ft 49 is extended by an external flange 51 having a wall that is substantially frustoconical or at least formed at an angle relative to the axis 19, so that the head 37a of the bolt comes to bear against the location of the convex connection between the ft 49 and the collar 51, which bears on the bottom 9a of the sensor housing by its edge

external device 51a.

  Such an assembly, with an elastically deformable flange 51, ensures a tightening force of the bolt of the order of several tons, while the axial pressure stress exerted on the housing and the sensitive elements 5, along the axis 19, can be reduced to a few tens or a few hundred kilograms. This promotes proper operation of the sensor, while allowing

  manufacture of the plastic housing 7.

  Note that such plastic manufacturing of the housing can make it possible to be exempt from the presence of insulating plates under the first electrode I 5a, as well as between the second electrode 15b and the block forming the seismic mass 21. In this regard , it will be seen in FIG. 1 that there is precisely no electrically insulating plate between the first electrode I5a and the bottom Ila of the lower part of the housing, but that on the other hand, in the example, we have maintained a

  electrically insulating plate 53 between the electrode 15b and the seismic mass 21.

  It will also be noted that, taking into account the attachment of the sensor 1 by a clamping means which engages along the axis 19, for attachment "from the center", the sensor 1 is generally presented, in this embodiment, as a annular assembly, with a series of elements 5 themselves individually annular, stacked along the axis of revolution 19, the two housing parts 9, 11

  also being annular, each with a central opening 9c, 1 1 c.

  In FIG. 1, it can be seen that the housing part 9 is such that its central orifice 9c is bordered by a continuous inner side wall 59 extending parallel to the axis 19 and of height, along this axis, less than the

  height of the pillars such as 29a, 29b, if the two housing parts are identical.

  Preferably, and as can be seen in FIG. 4, the external diameter d of the (each) internal wall 59 of the corresponding housing part will be substantially equal (barely smaller) than the internal diameter of each ring constituting a sensitive elements 5, so that the game

  rings in the housing is, at this location, limited.

  It should be noted that the transfer of the protuberances 23 to the inner face of the outer lateral walls of the housing allows better centering and a more efficient tight retention of these elements than if these protrusions had been produced in

  projection on the inner side wall 59.

  A gap 61 can however be held axially between the interior walls 59, 63 of the two housing parts, as shown in FIG. 3 where one can also see the appearance of the sensor 1 once the housing 7 is closed around of its sensitive elements, and after the plastic coating material 65

  has been injected around the casing thus closed, in a mold suitable for this purpose.

  It should be noted in this regard that radial grooves 67 will advantageously be provided in the bottom of each housing part to promote the distribution of the coating material, these grooves being able to be connected radially to circular channels respectively inside 69 and outside 71 limited by edges 73 and 75 respectively arranged in line with the inner side wall and the

  outer side wall, respectively.

Claims (10)

  1. Vibration sensor comprising, along an axis (19), a stack (5) of elements including an element (13) made of piezoelectric material and electrodes (15a, 15b) in electrical connection with this element, the electrodes having connection pins so that the sensor can transmit data relating to the vibrations received, characterized in that the element made of piezoelectric material and the electrodes are housed in a housing (7) comprising at least two parts (9, 11 ) separated each having a side wall (9b, 11b) at the outer periphery, at least one of these side walls having, or comprising, pillars (29a, 31a) engaging in openings (39a, 39b; 41a , 41b) formed in the side wall of the other part, these pillars extending substantially parallel to the axis (19) of stacking of the elements. 2. Sensor according to claim 1, characterized in that the pillars engage relatively tightly in the openings, to ensure a retention in rotation of a part (9) of the housing (7) relative to the other (11) , around the stacking axis of the elements, which axis also constitutes an axis of the   housing in the direction of bringing together or spacing the two parts.   3. Sensor according to claim 1 or claim 2, characterized in that the pillars (29a, 31a) and openings (39a, 39b; 41a, 41b) of the side wall of each part define a toothing, the two toothing being inter engaged   along the stacking axis of the elements.   4. Sensor according to any one of the preceding claims,   characterized in that the pillars of the side wall have an inner surface with protruding protrusions (23), and the protrusion of these protrusions as well as the section of the stacked elements (5) perpendicular to their stacking axis (19) are such that said stacked elements are   forcibly engaged in the corresponding part of the housing.   5. Sensor according to any one of the preceding claims,   characterized in that: - each part has a bottom (9a, 1 la) from which stands the outer peripheral side wall (9b, 1 1 b), - at least one of these bottoms is crossed by a axial orifice (9c, 1 1c) limited radially to this axis, by an inner side wall, - and the stacked elements (5) are annular, so as to be arranged   between the inner and outer side walls of the parts (9, 11) of the housing.   6. Sensor according to claim 5, characterized in that the bottom of at least one of the housing parts through which the axial orifice has radial grooves (67) opening into this orifice.   7. Sensor according to any one of the preceding claims,   characterized in that the two housing parts are identical.   8. Sensor according to any one of the preceding claims,   characterized in that: - the housing (7) is made of an electrically insulating material, advantageously made of plastic, - and the element (13) is made of piezoelectric material and the electrodes are in direct contact with one at less parts of this case, without interposition   electrically insulating element.   9. Sensor according to any one of the preceding claims,   characterized in that: - the housing is made of an electrically insulating material, - the stacked elements (5) comprise a complementary element (21) constituting a seismic mass - and one of the electrodes (15b) is interposed between this seismic mass   and the element made of piezoelectric material by being in direct contact with them. 10. Assembly comprising:   - the sensor (1) according to any one of the preceding claims,   - And means for fixing the sensor to a vibrating structure (3), the fixing means comprising a clamping means (47) engaged on the sensor and on the vibrating structure, to clamp the sensor against the vibrating structure, according to the axis (19) of the sensor, by promoting engagement of the pillars of a part   in the openings of the other party.