DE202013007490U1 - Temperature sensor for a fluid - Google Patents

Abstract

A temperature sensor having a temperature sensor (11) mounted in a housing (20) penetrating a wall of the housing, the sensor comprising a thermistor (3) and a cladding (30) formed of a protective insulating material, which surrounds the thermistor, the sensor being arranged in the housing such that the thermistor is projected outwardly from the housing and contact wires (6) of the thermistor extend from the housing into the interior of the housing, characterized in that the cladding (30) of the probe extends longitudinally, one part having a generally cylindrical elongated shape so as to simultaneously surround the thermistor and a portion of the contact wires adjacent the thermistor, and wherein the length of the cylindrical portion is sufficient to to arrange on this cylindrical part an annular junction (40, 42), the zwi guaranteed the sensor and the housing.

Description

Technical area

The present invention relates to a temperature sensor for fluids, and more particularly to a temperature sensor for a fluid having an increased rate of temperature rise. These temperature sensors are particularly used in household appliances, such as tumble dryers. Another application is in the field of supercharged internal combustion engines for measuring the temperature of the supercharged air.

State of the art

There are various types of temperature sensors on the market for fluids that can achieve a rapid rate of temperature rise. These temperature sensors generally use probes with NTC (negative temperature coefficient) thermistors (NTC). Such a sensor comprises a sensing element consisting of the thermistor, surrounded by a protective insulating material having a generally teardrop-like shape, and connected to two contact wires extending outwardly from the cladding to allow its electrical connection , Normally, the probe is mounted in a housing, protruding therefrom, so that its sensing element is in the operating position of the sensor directly in the fluid stream, with the contact wires, which provide the connection of the thermistor with the measuring circuit, inside the Casing body extend. One problem that arises is to make the connection between the probe and the housing leaktight to prevent leakage of fluid or moisture from entering the unprotected part of the thermistor, which may affect the function of the sensor.

Various techniques are used to seal the connection between the probe and the housing, such as the use of a resin or adhesive poured between the two components, or even a plastic casting between them. When using these techniques to make such a sensor dense, the tightness is mostly provided on the contact wires of the probe.

The enclosed 1 shows an example of a temperature sensor according to the prior art, the sensor 1 which, in a housing 5 is mounted. The costume 2 of the sensing element 3 of the feeler 1 is realized so that the sensing element is either immersed in a resin or the sensing element is covered with molten glass. These manufacturing techniques cause most panels to have a geometry in the form of a drop. However, the shapes and exact dimensions of the fairing can vary considerably between two feelers from the same lot. Simply use a joint to check the tightness between such a drop-type probe and the housing 5 to ensure there is a risk that leaks are created because the geometric tolerances that can compensate for the joints are limited.

In an attempt to circumvent these problems, as well as the picture in it 1 Similarly, some sensor manufacturers use an adapter between the sensor and the housing in the form of a cylinder 7 in which two holes 8th are provided which are parallel to each other and to the cylinder axis. The contact wires 6 of the probe are each in the two bores 8th introduced until the panel comes into contact with the end of the cylinder. The cylinder 7 allows the electrical insulation of the contact wires 6 to avoid a short circuit and also serves to position the probe. The tightness between the panel 2 of the sensor and the cylinder 7 Is with an adhesive, a paint or a resin 10 realized. Incidentally, the outer surface forms 9 of the cylinder 7 that can be manufactured with a very precise geometry, a contact surface for the joint 4 which has an identical shape and dimension to all manufactured sensors. The connection point 4 around the cylinder 7 and into the bore of the housing 5 is arranged, so can effectively ensure the tightness between the cylinder and the housing.

A disadvantage of this system is that it requires the use of an intermediate piece between the probe and the housing and the insertion of the contact wires into the bores of the cylinder means a further assembly step, which also requires precision and absolute accuracy. In addition, this requires an additional tightness between the sensor and the cylinder, which increases the risk of a defect of tightness and this means an additional step to achieve this tightness before mounting the sensor in its housing.

Object of the invention

It is the object of the present invention to mitigate or circumvent these disadvantages. In particular, it aims to propose an alternative embodiment for the temperature sensors for fluids using NTC thermistors.

In view of these objects, the object of the invention is to provide a temperature sensor having a temperature sensor mounted in a housing and penetrating a wall of the housing, the sensor having a thermistor and a cover made of a protective insulating material which surrounds the thermistor, wherein the sensor is disposed in the housing such that the thermistor is projected outwardly from the housing and extending contact wires of the thermistor from the panel into the interior of the housing. According to the invention, the sensor is characterized in that the panel of the sensor extends in one piece longitudinally, a part having a generally cylindrical elongate shape so as to simultaneously surround the thermistor and a part of the contact wires adjacent to the thermistor, and wherein the length of the cylindrical part is sufficient to arrange on this cylindrical part an annular junction which ensures the tightness between the sensor and the housing.

General description of the invention

Due to the sufficiently elongated cylindrical portion of the probe, it is possible to arrange an annular junction surrounding this part and in contact therewith at an axial length sufficient to ensure good sealing.

In contrast to the prior art, the cladding does not have a teardrop shape with a fluctuating and inaccurate dimension and shape profile surrounding only the thermistor and the contact wires at the very beginning. In contrast, the cladding according to the invention covers not only the sensing element of the thermistor, but also a large part of the contact wires with a long cylindrical part, which is usually greater than or equal to twice their diameter, ie with a constant over its entire length diameter, whereby the Junction reliably and without the risk of leakage can be arranged.

At least the portion of the trim surrounding the contact wires is cylindrical because the joint is applied precisely to that part so that the end of the probe comprising the thermistor can protrude outwardly from the housing to be placed in the fluid flow whose temperature is to be measured. The end of the probe comprising the thermistor can thus have a shape and a cross section which differ from the cylindrical part. Preferably, however, the entire panel is cylindrical over its entire length and terminates in two hemispherical shapes.

The junction is supported directly on the cylindrical part of the panel of the sensor on the one hand and on the housing on the other hand, to ensure the tightness of the thermistor. Preferably, the joint also has flexible or very flexible lips on its outer surface in contact with the housing, and also on its inner surface in contact with the probe. These lips adapt to the sensor and the housing and can thus compensate for possible variations in the geometry of the components.

According to one embodiment, the joint consists of an elastically deformable material which is simply radially compressed during assembly between the housing and the probe to ensure good contact between it and the probe and between the latter and the housing.

According to another preferred embodiment of Stopfbüchsentyp the connection point consists of an elastically deformable material, which is axially compressed so that it is at the same time on the sensor and in the housing under radial pressure or introduced. The axial pressure allows expansion in the radial direction, which ensures that the contact between the connection point and the temperature sensor and between the connection point and the housing.

Preferably, in this case, to facilitate the assembly and increase the radial pressure of the joint to both the probe and the bore of the housing, the joint comprises a frusto-conical male member which cooperates with a frusto-conical female member of the housing by placing the male member under the axial force exerted on an end face of the joint is inserted into the receiving part, whereby the joint can be compressed by a combined movement in the radial and in the axial direction.

According to another device, the joint may also have a shoulder which may serve as an axial abutment for the rear end of the probe opposite to where the thermistor is located, thus determining its positioning in the housing. At least one opening in the shoulder for the passage of contact wires is provided. The shoulder preferably has two openings, through which a contact wire is guided in each case. In addition, each opening may have a flexible lip, to ensure a further tightness directly with the contact wires.

After a special installation of the sensor, the connection point is held by a cover on the housing, wherein the connection point ensures the tightness with the lid or with a body of the housing on which the lid is held, or with these two components.

The axial arrangement of the probe can also be determined by the application of the bent ends of the contact wires against an inner end face of the housing. In such a case, the connection point only serves to ensure the tightness and plays no role in the arrangement of the probe. The bent ends of the wires can be supported by springs in abutment against the inner end face supporting, the springs also ensure an electrical connection between the contact wires of the sensor and electrical connection means of the sensor with an external measuring circuit.

An axial compression body is disposed inside the body so as to be axially supported on the end face of the joint located to the interior of the housing. Advantageously, the contact wires are passed through respective bores of the compression body, and the position of the sensor is determined by the abutment of the casing at the end of the axial compression body.

The object of the invention is also a temperature sensor for a sensor as defined above, wherein the sensor comprises a thermistor and a cladding formed of a protective insulating material surrounding the thermistor and contact fibers of the thermistor resulting from the cladding the probe being characterized in that the panel of the probe extends in one piece longitudinally, a portion having a generally cylindrical elongated shape so as to simultaneously surround the thermistor and a portion of the contact fibers adjacent to the thermistor, wherein the fibers in their clad parts are substantially parallel to the axis of the cylindrical part of the cladding and the length of the cylindrical part is greater than or equal to twice their diameter. At least the part of the panel that surrounds the contact wires is cylindrical.

The joint, which in most cases is made of an elastic material, also has the advantage of mitigating the vibrations that can be transmitted from the housing to the temperature sensor, thus protecting the temperature sensor.

Brief description of the drawings

Further particular features and features of the invention will become apparent from the detailed description of some advantageous embodiments, which are presented below for purposes of illustration with reference to the accompanying drawings. Show it:

1 FIG. 4 is a longitudinal section of a prior art sensor already described in the introductory part of this specification.

2 FIG. 2: an axial sectional view of a sensor according to the invention according to a first embodiment. FIG.

3 FIG. 2: an axial sectional view of a sensor according to the invention according to a second embodiment. FIG.

4 FIG. 2: an axial sectional view of a sensor according to the invention according to a third embodiment. FIG.

5 : A view of the protective geometry of the embodiment according to 3 or 4 ,

Description of a preferred embodiment

The in 2 The sensor shown comprises a housing 20 that has a housing body 21 and a box 22 in which the body is inserted and by a crimped lid 23 is held. A feeler 11 according to the invention is mounted in the housing and leads into a hole 211 of the body and an opening 231 of the lid. The feeler 11 has a thermistor 3 on that in a disguise 30 , For example, made of glass, of generally cylindrical and elongated shape is embedded. The costume 30 , which may have a thickness in the range of 1 to 5 mm, also surrounds the contact wires over a large length 6 , for example, over a length that can be between 5 and 20 mm. The free ends 61 the contact wires are bent over and by springs 62 against an inner end wall 212 held the body, which springs also the electrical connection with connectors 63 , which are located at the bottom of the box, serve. An annular junction 40 is arranged around the sensor and in a receptacle, on the one hand by a cylindrical cuff plate 232 the lid and on the other hand of a reduction 213 the housing body is formed. The connection point 40 has very flexible lips 41 . 42 on, each one on the panel 30 support the sensor and inside the receptacle. The joint is held compressed in the receptacle by the crimp connection of the cover on the body and the box of the sensor. Because the connection point 40 only to ensure the tightness, without guaranteeing the positioning of the probe, the correct positioning of the probe, the end of which includes the outside of the housing thermistor, resulting from the installation of the bent ends 61 the contact wires on the front wall 212 of the body or the plant of the disguise 30 at a tip of the housing 25 ,

In the in 3 Example of the sensor shown is the tightness between the sensor 3 and the housing 24 through a junction 42 , the lips 41 having, in a cylindrical bore portion 241 abut the housing, and a frustoconical part 421 ensured, which is inserted into a truncated cone-shaped bore with a corresponding shape and dimension, which is also realized in the housing. A compression body or a printing device 50 engages the face of the joint opposite to the side having the frusto-conical portion so that the joint is axially compressed to push it into the frusto-conical bore causing the joint to be radially fixed between the housing and the feeler is pressed. They are bores 51 in the printing device 50 realized and allow the implementation of contact wires 6 , In this embodiment, the arrangement of the probe is realized by the abutment of the end of this against the printing device. The housing 24 can with a geometry 26 Be provided by the panel 30 of the thermistor 3 can be protected. So that the fluid flow is not hindered and the sensor offers a good temperature rise rate, the protective geometry is 26 with openings 27 provided (see also 5 ).

The embodiment of 4 is similar to that of 3 and differs only in the presence of a paragraph 422 the joint, which is a positioning abutment for the probe. The contact wires 6 are by bores formed in the paragraph 423 guided, wherein the bores may have flexible lips, which can ensure a tightness of the contact wires of the probe.

Claims (16)

Temperature sensor, one in a housing ( 20 ) mounted temperature sensor ( 11 ), which penetrates a wall of the housing, wherein the sensor is a thermistor ( 3 ), and a fairing ( 30 ), which is formed of a protective insulating material surrounding the thermistor, wherein the sensor is arranged in the housing such that the thermistor is projecting outwardly from the housing and contact wires ( 6 ) of the thermistor from the cladding to the interior of the housing, characterized in that the cladding ( 30 ) of the probe extends in one piece, one part having a generally cylindrical elongated shape so as to simultaneously surround the thermistor and a portion of the contact wires adjacent to the thermistor, and wherein the length of the cylindrical member is sufficient to rest thereon cylindrical part an annular junction ( 40 . 42 ), which ensures the tightness between the sensor and the housing. Sensor according to claim 1, wherein the length of the cylindrical part is greater than or equal to twice its diameter. A sensor according to claim 1, wherein at least the part of the cladding surrounding the contact wires is cylindrical. Sensor according to one of claims 1 to 3, wherein the connection point ( 40 . 42 ) on its outer surface flexible lips in contact with the housing ( 20 . 24 ), and / or wherein the connection point on its inner surface flexible lips in contact with the sensor ( 11 ) having. Sensor according to one of claims 1 to 4, wherein the connection point made of an elastically deformable material and between the housing ( 20 ) and the sensor ( 11 ) is radially compressed. Sensor according to one of claims 1 to 4, wherein the connection point made of an elastically deformable material and preferably by an axial compression body ( 50 ), which is located inside the body ( 24 ) is axially compressed so that it is axially on the front side of the joint ( 42 ), which is located to the interior of the housing, so that the joint is pressed with radial compression simultaneously on the probe and in the housing. Sensor according to claim 6, wherein the connection point ( 42 ) a frustoconical plug-in part ( 421 ), which with a frusto-conical receiving part ( 242 ) of the housing ( 24 ) cooperates. Sensor according to one of claims 1 to 4, wherein the connection point has a shoulder ( 422 ), which serves as an axial abutment for the sensor ( 11 ) serves. Sensor according to claim 8, wherein at least one opening ( 423 ) for the implementation of the contact wires ( 6 ) in the paragraph ( 422 ) is omitted. Sensor according to claim 9, wherein the shoulder has two openings ( 423 ), through which in each case a contact wire ( 6 ), each opening having a flexible lip to ensure sealing with the contact wires. Sensor according to one of claims 1 to 4, wherein the connection point by a cover ( 23 ) on the housing ( 20 ), wherein the joint at the same time the tightness with the lid ( 23 ) and with a body ( 21 ) of the housing on which the lid is held. Sensor according to one of claims 1 to 4, wherein the axial arrangement of the sensor by the application of the bent ends ( 61 ) of the contact wires ( 6 ) against an inner end face ( 212 ) of the housing and wherein the bent ends ( 61 ) of the wires preferably by springs ( 62 ) on the front side ( 212 ) are supported, wherein the springs, moreover, provide an electrical connection. Sensor according to claim 6, wherein the contact wires ( 6 ) through respective bores ( 51 ) of the compression body ( 50 ) are passed. Sensor according to claim 6, wherein the position of the sensor ( 11 ) by the concern of the panel ( 30 ) at the end of the axial compression body ( 50 ) certainly. Temperature sensor for a sensor according to any one of claims 1 to 14, comprising a thermistor ( 3 ) and a panel ( 30 ), which is formed of a protective insulating material and surrounding the thermistor, and contact wires ( 6 ) of the thermistor extending out of the cladding, characterized in that the cladding of the sensor extends in one piece longitudinally, one part having a generally cylindrical elongate shape so as to simultaneously enclose the thermistor and a part of the thermistor surrounding the thermistor adjacent contact wires, wherein the wires are in their clad parts substantially parallel to the axis of the cylindrical part of the cladding and the length of the cylindrical part is greater than or equal to twice their diameter. A sensor according to claim 15, wherein at least the part of the cladding surrounding the contact springs is cylindrical.

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