FR2793020A1 - Temperature sensor for measuring the temperature of a fluid in an automobile engine - Google Patents

Abstract

The sensor has a body (200) which ensures protection of the thermistance (100) and fixes the sensor. integrally into plastic material. The plastic body (200) is formed with a plunger (210) and with a surrounding support (250) over molded on the plunger (210). Fixing clips (270,280) are formed on the body (200) and also a connector with outputs (260,262) connected to the thermistance. The plunger (210) is formed with a hollow section designed to receive the thermistance. The end wall (222) of the plastic body (200) placed on the thermistance (100) has a thickness of about 0.5 mm.

Description

The present invention relates to the field of temperature sensors.

  The present invention finds particular, but not exclusively, application in the measurement of the temperature of a fluid on a motor vehicle engine. Many temperature measuring devices at this

effect have already been proposed.

  Most known temperature measuring devices are based on the use of a thermistor

sensitive to temperature.

  Even more precisely, most of the devices known and used today include a thermistor placed in a metal body designed to protect the thermistor from its environment and to secure the sensor to a support casing, for example using a thread, as well as a plastic coating designed to immobilize the thermistor in the body. Where appropriate, the above coating may be

  shaped like an electrical connector.

  The present invention now aims to improve the known temperature measuring devices. This object is achieved in the context of the present invention thanks to a sensor in which the body ensuring the protection of the thermistor and the fixing of the sensor

  is made entirely of plastic.

  Other characteristics, objects and advantages of the present invention will appear on reading the

  detailed description which follows, and next to

  attached drawings, given by way of nonlimiting example, and in which: - Figure 1 shows a perspective view of a temperature sensor according to the present invention, - Figure 2 shows a view in longitudinal section of this sensor , - Figure 3 shows an end view, connector side, of this sensor, - Figure 4 shows a cross-sectional view of the sensor according to the cutting plane referenced IV-IV in Figure 2, - Figures 5 and 6 represent two side views, respectively orthogonal to each other, of a thermistor whose bristles are fixed on connection blades, - Figure 7 shows an external side view of a plunger belonging to the sensor according to the present invention, - Figure 8 represents a view in longitudinal section of this plunger, and

  - Figure 9 shows an end view of this plunger.

  The temperature sensor according to the present invention illustrated in the appended figures, essentially comprises a thermistor 100 and a body 200 made entirely of plastic material and itself composed of a plunger 210 and a coating 250 which are

thereafter will be called "support".

  Thermistor 100 can be conventional in itself.

  We can see in the appended figures such a thermistor 100 comprising a rounded bulb 102, for example in the general shape of a water drop, housing the pellet whose electrical resistance is sensitive to temperature, and two output bristles 104, 106 formed of electrically conductive wires connected respectively

  on two faces of the above-mentioned transducer patch.

  The plunger 210 is formed of an elongated hollow body receiving the thermistor 100. The plunger 210 is designed to allow the said thermistor 100, and more precisely its bulb 102 housing the transducer patch, as far as possible from the attachment zone of the sensor and therefore as much as possible at

  within the fluid whose temperature is to be detected.

  Furthermore, the plunger 210 is designed to preserve the thermistor 100 with respect to the environment of the fluid to be measured, in particular with regard to pollution, while in a sufficiently fine state to allow satisfactory heat exchange, in particular with time. short response time on the order of a few seconds (typically 10 to 11

  seconds), between said fluid and thermistor 100.

  To this end, a tight connection is defined with respect to

  to the fluid between the plunger 210 and the coating 250.

  Essentially the diver 210 is composed of a

  sheath 220 extended by a flare 230.

  The sheath 210 is blind, that is to say that its end, the fluid side to be measured is closed. More precisely still, at this level the sheath 220 preferably comprises a spherical cap 222 convex towards the outside and concave towards the inside. The spherical cap 222 thus preferably defines a cradle in the general shape of a hemisphere, the radius of curvature of which is complementary to that of the outer outer surface of the

thermistor bulb 102.

  By way of nonlimiting example, this spherical cap 222 has an external radius of the order of 1.95 mm and an internal radius of the order of 1.45 mm, ie a thickness

wall thickness of the order of 0.5 mm.

  This spherical end cap 222 is extended towards the inside of the sensor by a skirt 224. This is preferably slightly frustoconical, flared in

distance from end 222.

  The thickness of the skirt 220 can be constant. As a variant, however, the thickness of the skirt is slightly increasing away from the spherical cap.

end 222.

  By way of nonlimiting example, the thickness of the skirt 224 can be of the order of 0.5 mm, ie identical to that of the spherical cap 222, at its end adjacent to the latter, while at its opposite end, adjacent to the flare 230 ,. the skirt

  224 has a thickness of the order of 0.75 mm.

  The flaring 230 comprises a cylinder 232 of constant diameter connected to the end of the skirt 220 opposite the end 222 by means of a recess

radial 234.

  The cylinder 232 has a diameter greater than that of

skirt 220.

  Furthermore, the cylinder 232 which is intended to be embedded in the coating 250 preferably comprises, on its outer periphery ribs 235, 236, 237 forming a labyrinth with the material making up the coating 250

  to ensure the aforementioned seal.

  By way of nonlimiting example, there is thus provided a first annular rib 235, of rectangular cross section, with an outside diameter of the order of .35 mm, substantially mid-length of the cylinder 232, an annular rib 237 of section rectangular right and diameter of the order of 9.15 mm adjacent to the end of the cylinder 232 opposite the sheath 220 and a third rib of height and geometry comparable to the rib

  237, located between the two aforementioned ribs 235, 237.

  In addition, preferably there are provided anti

  rotation between the plunger 210 and the coating 250.

  These anti rotation means consist of structures

  not symmetrical of revolution around the axis of the sensor.

  More specifically still preferably these anti-rotation means consist of ribs of generally axial orientation projecting from the internal surface of the plunger 210 at the transition zone between the

cylinder 232 and the sleeve 220.

  According to the preferred embodiment illustrated in the appended figures, there are thus provided four ribs 238 distributed equally around the longitudinal axis of the sensor. We will now describe the structure of enrQbage 250

forming support.

  Its primary function is to fill the plunger 210 in order to immobilize the thermistor 100 in contact.

  with the curved end 222 of the plunger.

  As can be seen in the appended figures, preferably the coating 250 is moreover shaped to define at the end of the sensor opposite the bulb 222 a connector body capable of cooperating with an element of

  connection of complementary geometry.

  Thus, according to the preferred embodiment illustrated in the appended figures, the covering 250 forming the connector body is overmolded on two blades of electrically conductive material 260, 262 which emerges on the rear of the covering, in the internal chamber of the body. connector, parallel to the longitudinal axis of the sensor. These two blades 260, 262 are welded respectively in

  261, 263 on the outputs 104, 106 of the thermistor.

  Where appropriate, these blades 260, 262 may include shapes referenced 264, 265 in FIGS. 2 and 4, serving as a guide for the output bristles 104, 106 of the thermistor 100 to center them on their zone of

welding on said blades 260,262.

  As a variant, however, the coating 250 may be shaped differently from the illustration given in the appended figures and in particular be devoid of such a connector body. In this case the output wires 104, 106 of the thermistor emerge directly on the outside of

  coating 150 for a suitable electrical connection.

  The coating 250 forming a support is also shaped to define a means of fixing the sensor to the site of use, for example a motor housing of

motor vehicle.

  To this end, if necessary, the coating 250 forming a support may include a section having a thread associated with a section in the form of a hexagon or equivalent that is not symmetrical in revolution. However, according to the preferred embodiment illustrated in the appended figures, the fixing means defined on the support coating 250 are designed to immobilize the sensors by snap-fastening. In this context, these fixing means consist of two legs 270, 280 in the form of a diametrically arched arch.

  opposite to the longitudinal axis of the sensor.

  Each of these arches comprises a pair of branches 271, 272 parallel to each other and parallel to the longitudinal axis, connected substantially at mid-length on the support 250. From this connection zone the aforementioned branches 271, 272, 281, 282 extend in the direction of the plunger 210. They are connected at this level by a transverse branch 273, 283 designed to engage on a toothing linked to the support means of the site of use, for example the motor vehicle casing. Preferably, of course, a seal such as an O-ring is interposed between the sensor according to the invention and the support of the site of use. Such a seal can be interposed between a radial recess

  any of the sensor and said site of use.

  The coating 250 can be made of any suitable material known to those skilled in the art capable of withstanding

  temperature of the environment involved.

  By way of nonlimiting example, the coating 250 can be made of polyamide, in particular polyamide 6/6 loaded with glass fiber, for example at 30%, or even polyester, polybutyl. To manufacture a sensor according to the present invention, it suffices to place the thermistor 100 inside the plunger 210, if necessary after having welded the outlets 104, 106 of the thermistor to the

  blades 260, 262, then to make the coating 250 by molding. Of course the present invention is not limited to the embodiment which has just been described but extends any variant in accordance with its spirit.

Claims (13)

  1. Temperature sensor, in particular for measuring the temperature of a fluid on a motor vehicle engine, characterized in that it comprises a body (200) ensuring the protection of the thermistor (100) and the fixing of the sensor , made entirely of plastic. 2. Sensor according to claim 1 characterized in that the body (200) of plastic material is formed by a plunger (210) and a support coating (250) molded onto the plunger (210).   3. Sensor according to claim 2 characterized by   the fact that the coating (250) fills the plunger (210).   4. Sensor according to one of claims 1 to 3   characterized by the fact that the plastic body   (200) defines fixing means.   5. Sensor according to one of claims 1 to 4   characterized in that the fixing means defined on the plastic body (200) are   formed by snap-fastening means (270, 280).   6. Sensor according to one of claims 1 to 4   characterized in that the fixing means provided on the sensor body (200) include a thread and   a non-circular section of revolution.   7. Sensor according to one of claims 1 to 6   characterized in that the support body (200) defines a connector body overmolded on outputs   (260, 262) connected to the thermistor (100).   8. Sensor according to one of claims 1 to 6   characterized in that the plastic body (200) is molded onto the outlets (260, 262) linked to the thermistor (100).   9. Sensor according to one of claims 1 to 8   taken in combination with claim 2 characterized in that the plunger (210) is formed by an elongated hollow body defining a receiving cradle for the thermistor (100).   10. Sensor according to one of claims 1 to 9 characterized in that the end wall (222) of the plastic body (200) placed on the thermistor (100) has a thickness of the order 0.5 mm.   11. Sensor according to one of claims 1 to 10   taken in combination with claim 2 characterized in that the plunger (210) has ribs (235, 236, 237) ensuring the tightness with the coating (250).   12. Sensor according to one of claims 1 to 11   taken in combination with claim 2 characterized in that it comprises anti rotation means (238).   13. Sensor according to claim 12 characterized in that the anti rotation means are formed by ribs projecting from the internal surface of the plunger (210).