FR2772913A1 - Hall effect pressure sensor - Google Patents

Abstract

The main body (3) of the sensor contains a spring (19) loaded piston (18) which may move under pressure applied to it's lower surface. A magnet (22) is mounted on the piston and interacts with a Hall effect detector (23) which is fixed to a printed circuit card (24). The position of the card may be adjusted to calibrate the sensor and then set by a screw (34).

Description

DESCRIPTION
"Sensor for measuring a physical quantity"
The present invention relates to a sensor for measuring a physical quantity, and in particular but not limited to a pressure sensor.
there are many cases in which a measurement quantity which is mechanical in nature, such as displacement, force, pressure, etc., must be converted into a physical signal of a nature other than mechanical and in particular into a electrical signal.

 Many types of sensor are known, of course, providing such a conversion. Most are expensive to produce and present assembly, manufacturing and / or calibration difficulties.

 The object of the invention is to propose such a measurement sensor which is particularly simple and inexpensive to manufacture and to calibrate.

 According to the invention, the sensor for measuring a physical quantity, comprising a body, an influence member mounted to move in the body under the effect of variations in the quantity to be measured, and a component undergoing a variable influence. as a function of the movements of the influence member, is characterized in that the component is mounted on a plate supporting connections of the component, and in that the plate is fixed in the body in a position which can be adjusted for the sensor calibration.

 Thanks to the wafer, typically a printed circuit board, the component is particularly simple to mount in the sensor. At the same time, the plate carries at least part of the connections, such as electrical, with the outside of the sensor for the delivery of the measurement signal and / or, when necessary, the supply of the sensor.

 By adjusting the position of the plate in the body, it is very easy to calibrate the sensor.

 In general, the invention thus provides a very inexpensive sensor having, thanks to its calibration capacity, suitable accuracy. By its precision and cost, such a sensor is particularly suitable for "general public" applications, for example as a safety or regulating member in a central heating circuit or domestic hot water production.

 Other features and advantages of the invention will emerge from the following description, relating to a non-limiting example.

In the accompanying drawings:
- Figure 1 is an axial sectional view of a pressure sensor according to the invention;
- Figure 2 is a view of the dorsal face of the printed circuit board; and
- Figures 3 and 4 are sectional views along III-III and respectively IV-IV of Figure 1.

 In the example shown in the figures, the sensor comprises a body 1 of generally cylindrical shape comprising a base 2 and a main body 3.

The base 2 has a tubular configuration ending, on the side opposite to the main body 3, by an externally threaded endpiece 4, screwed in a sealed manner in a connector 6 of an enclosure 7 which is only shown in phantom. In the present example relating to a pressure sensor, the enclosure 7 contains the fluid whose pressure is to be measured. The enclosure 7 may for example be constituted by piping of a hot water circuit in a central heating installation.

 At its end adjacent to the main body 3, the base 2 is terminated by a crimping lip 8 having one end 9 folded against a rear face 11 of a crimping flange 12 of the main body 3. A sealing membrane 13 is pinched tightly, on its entire periphery, between the front face 14 of the flange 12 and an internal shoulder 16 of the base 2.

 The sage crimp lip 8 is connected to the radially outer edge of the shoulder 16. The liquid present in the enclosure 7 can thus penetrate into the base 2 without exceeding the limit formed by the sealing membrane 13.

 The main body 3 has an axial cavity of generally cylindrical shape 17. On the side of the base 2, the axial cavity 17 is closed by the membrane 13.

A sliding member 18 similar to a piston is slidably mounted in the cavity 17. The sliding member 18 is fixed in a manner not shown, for example by gluing, to the face of the membrane 13 facing the main body 3 and therefore opposite the face in contact with the fluid. A compression spring 19 is inserted axially between the sliding member 18 and a bottom 21 of the cavity 17, opposite the membrane 13.

 Thus, the pressure exerted by the fluid on the membrane 13 tends to move the sliding member 18 towards the bottom 21 of the cavity 17 against the return action of the compression spring 19.

 On its face facing the bottom 21 of the cavity 17, the sliding member 18 rigidly carries an influence member 22 constituted by a permanent magnet.

 Furthermore, the sensor comprises a component 23 which is mounted in the cavity 17 facing the permanent magnet 22. The magnet 22 is in a central position on the face of the sliding member 18 facing the bottom 21 of the cavity . In the example described where the influence member 22 is a permanent magnet, the component 23 is typically a Hall effect detector.

 According to the invention, the component 23 is mounted on a plate 24 fixed in the main body 3 in a position which can be adjusted for the calibration of the sensor. In the case of an electrical component 23 in the example described, the wafer is a printed circuit board.

 More specifically, the printed circuit board 24 is mounted in a plane substantially parallel to the axis 26 of the cavity 17, which corresponds to the direction of movement of the influence member 22 with the sliding member 18 under the action of pressure variations.

 The printed circuit board 24 has an elongated shape parallel to the axis 26 and has one end 27 directed towards the sliding member 18 and more particularly towards the influence member 22. The component 23 is fixed on the circuit board printed 24 in the vicinity of the end 27 and on the face 28 of the plate which is turned towards the axis 26.

Thus, the axis 26 passes through the component 23, as shown more particularly in FIG. 4.

 For its mounting in the body 1, the printed circuit board 24 is engaged in a slot 29 (see also FIG. 3) having a generally flattened rectangular shape corresponding to the profile of the board 24. The slot 29 is formed in a closing wall 31 of the main body 3. The wall 31 closes the cavity 17 on the side opposite to the sliding member 18 and in particular carries the bottom face 21 mentioned above.

The plate 24 thus comprises a region 241 engaged in the slot 29, a region 242 projecting into the cavity 17 and carrying the component 23, and a region 243 protruding from the wall 31 on the side opposite the cavity 17 in a recess 32 formed in the end of the main body 3 on the side opposite to the base 2. The main body 3 further comprises in the wall 31 a threaded bore 33 which extends perpendicular to the plane of the plate 24 from outside the main body 3 up through one face of the slot 29.

A clamping screw 34 screwed into the bore 33 has a head 36 accessible from the outside of the main body 3, and a clamping end 37 which bears against the face 28 of the wafer 24. The screw 34 thus immobilizes the plate 24 in the slot 29 in a position chosen at will along a sliding direction parallel to the axis 26 and to the direction of movement of the sliding member 18 and the influencing member 22.

 During manufacture, after assembly of the various elements of the sensor but before tightening of the screw 34, the membrane 13 is subjected to a determined pressure and the position of the plate 24 is adjusted by sliding in the slot 29 parallel to the axis 26 so as to obtain a predetermined electrical signal in response to the predetermined pressure. The screw 34 is then tightened to immobilize the wafer 24 in the position resulting from this calibration operation.

 In a manner which is conventional in itself, the component 23 comprises pins 38 which pass through corresponding holes formed in the plate 24 and are connected by welds 39 to conductive pads 41 formed on the face 42 of the plate 24 opposite to the face 28 carrying the component 23. In the example shown where the detector 23 is a Hall effect detector, the latter has three pins 38, namely two for its power supply and one for the signal supplied. There are thus three areas 41 (FIG. 2) which consist of three conductive lines isolated from one another and each extending from the corresponding pin located in the area 242 of the wafer 24 to the area 243 located in the recess 32 by traversing the entire length of the zone 241 situated in the slot 29. The recess 32 is intended to receive an electrical connector (not shown) comprising three individual contacts each connected to one of the pads 41. Consequently , in the preferred example which is shown, the printed circuit board 24 is only used to support the component 23 in an adjustable position in the body 1 and to electrically connect the component 23 with the outside.

 The bottom 21 of the cavity 17 carries an axial skirt 44 which surrounds the region 242 of the wafer 24.

The free end 27 of the plate 24 is axially set back relative to the free end 46 of the skirt 44. The free end 46 forms a stop for an annular region 47 of the sliding member 18 which surrounds the magnet 22 When the pressure prevailing in the fluid reaches or exceeds the maximum for which the sensor is operational, the annular region 47 of the sliding member 18 comes to bear against the free end 46 of the skirt 44. This prevents the member sliding 18 or any element that it carries, such as the influence member 22, even coming indirectly into contact with the printed circuit board 24 or any element that it carries and in particular with the component 23.

 In addition, the skirt 44 is surrounded by a part of the helical spring 19 and contributes to the centering of the spring 19. The skirt 44 prevents any mechanical interference between the turns of the spring 19 and the region 242 of the printed circuit board 24 as well as with component 23.

 The annular region 47 of the sliding member 18 constitutes the top of a boss 48 serving for centering the adjacent end of the spring 19.

 Preferably, the main body 3 is made of an insulating material such as a hard plastic material to avoid any risk that the pads 41 of the wafer 24 are short-circuited by the adjacent face of the slot 29. As shown in FIG. 3, this face may however have, to receive each pad 41, a groove 49 protecting the pads 41 from the mechanical pressure exerted indirectly by the immobilizing screw 34, and from friction during the mounting and calibration operations.

 The base 2 can be made of metal suitable for the deformation of the lip 8 for crimping on the flange 12 of the main body 3. It is preferable that the base 2, the main body 3 and the sliding member 18 are made made of non-magnetic materials to avoid any unwanted interaction with the magnet 22.

 In operation, the sliding member 18 takes along the axis 26 a position which is a function of the pressure prevailing in the fluid occupying the enclosure 7.

The sealing membrane 13 deforms correspondingly. The Hall effect detector 23 provides, on one of the ranges 41, a signal which depends on the distance between the influence member 22 and the detector 23, and which therefore depends on the pressure prevailing in the fluid.

 Of course, the invention is not limited to the example described and shown.

 The plate could carry connections other than electrical, for example optical.

 The invention is applicable to many devices comprising a function for converting a displacement into a static signal.

Claims (13)

 1- Sensor for measuring a physical quantity, comprising a body (1), an influence member (22) mounted to move in the body (1) under the effect of variations in the quantity to be measured, and a component (23) undergoing a variable influence as a function of the movements of the influence member (22), characterized in that the component (23) is mounted on a plate (24) supporting the connections of the component, and in that the plate (24) is fixed in the body in a position which can be adjusted for the calibration of the sensor.  2- A sensor according to claim 1, characterized in that the component (23) is mounted in the vicinity of one end (27) of the plate (24) directed towards the influence member (22).  3- Sensor according to claim 1 or 2, characterized in that the plate (23) is mounted in a slot (29) of the body (1), and can slide there for the calibration of the sensor.  4- A sensor according to claim 3, characterized in that one (28) of the faces (28, 42) of the plate (24) receives the support of one end (37) of a locking screw ( 34) through one of the faces of the slot (29).  5- Sensor according to one of claims 1 to 4, characterized in that the plate (24) is mounted in a plane substantially parallel to the direction (26) of movement of the influence member (22).  6- sensor according to claim 5, characterized in that the plate (24) is laterally offset relative to an axis (26) of movement of the influence member (22) so that the component (23) is traversed by this axis.  7- A sensor according to claim 5 or 6, characterized in that the body comprises a skirt (44) directed towards the influence member (22) and separating the plate (24) and the component (23), located radially to inside, and a return spring (19) of the influence member, the spring being radially outside the skirt (44).  8- A sensor according to claim 7, characterized in that the skirt surrounds the end (27) of the plate (24) directed towards the influence member (22), and in that a free end (46) the skirt forms for the influence member (22) a stop preventing the influence member (22) from coming, even indirectly, into contact with the plate (24) and the component (23).  9- Sensor according to one of claims 1 to 7, characterized in that the body (1) has a stop  (46) limiting the stroke of the influence member (22) to prevent the influence member (22) from coming, even indirectly, into contact with the plate (24) and the component (23).  10- Sensor according to one of claims 1 to 9, characterized in that the wafer (24) is a printed circuit board.  11- Sensor according to one of claims 1 to 10, characterized in that the influence member (22) is magnetic and the component (23) is a Hall effect detector.  12- Sensor according to one of claims 1 to 11, characterized in that the influence member (22) is part of a sliding member (18) loaded by a return spring (19), which biases the sliding member (18) in opposite direction to the component (23).  13- Sensor according to one of claims 1 to 12, characterized in that the sensor is a pressure sensor, the influence member (22) moves under the action of the pressure of a fluid.