JPH1114469A - Sensor holder and composite sensor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a sensor holder for holding, with no deviation of a lead wire, a thermister at a correct position and a composite sensor using the sensor holder. SOLUTION: A rod part 9 of a sensor holder 4 with a second thermister 2 embedded is so formed as to follow the inside shape of a bottom part of a small-diameter part 6 of a case 3, a first thermister 1 is attached to a step part 7 of the case 3 for positioning, and the rod part 9 of the sensor holder 4 is inserted inside the bottom part of the case small-diameter part 6 through a through hole 1a of the first thermister 1 which was positioned so that the second thermister 2 is positioned. Lead wires 2a and 2b of the second thermister 2 are coated with an insulating tube 10 while twisted together, thus, the strength or the lead wire increases, so it is not deviated in the rod part 9 even under a injection pressure of a resin when the sensor holder 4 is formed, extending elastically to fix the second thermister 2 to a tip end or the rod part 9. The rod part 9 of the sensor holder 4 is immune to warping or bending due to cooling contraction.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sensor holder of a sensor used for detecting a water temperature of, for example, an engine cooling system for an automobile, and a composite sensor using the sensor holder.

[0002]

2. Description of the Related Art In an engine cooling system for an automobile, cooling water is sent into an engine room to cool the engine, and the cooling water is sent to a radiator to cool and circulate again in the engine room. The cooling water temperature of the car engine is measured by two temperature sensors,
Controls the cooling fan motor based on the sensor signal, controls fuel injection in the engine, and controls its ignition timing, idle speed, etc. (ECU control), and also measures the engine coolant temperature to provide information to the driver. Used for indicating (for water thermometer). Hereinafter, the thermistor for the water temperature gauge is referred to as a first thermistor, and the thermistor for ECU control is referred to as a second thermistor, so that the two are distinguished from each other.

Conventionally, the two types of temperature sensors used for the above purpose are separately mounted in the cooling water circuit of the engine. However, the two types of temperature sensors are combined because the processing step and the assembling step are troublesome. An integrated temperature sensor incorporated in two cases has been proposed (Japanese Utility Model Publication No. 54-2146).
No., Japanese Utility Model Laid-Open No. 6-7029).

Further, the present inventors have previously improved the integrated temperature sensor and have developed a composite sensor which can be assembled in a case by accurately regulating the positional relationship between two thermistors ( JP-A-7-239278).

According to this composite sensor, the second thermistor 32 is embedded in the connector 34 as shown in FIG.
The pointed end 34b of the connector portion 34 in which the second thermistor 32 is embedded is formed in the shape of the inside of the bottom of the small-diameter portion 33b of the case 33, and the first thermistor 31 is connected to the step 33c of the case 33. Mounted and positioned,
The second thermistor 32 is positioned by penetrating the through hole 31a of the first thermistor 31 and inserting the pointed end 34b of the connector 34 inside the bottom of the small diameter portion 33b of the case.

[0006]

By the way, the connector portion 34 is molded from a resin material by embedding the second thermistor 32. However, when the connector portion is molded, the connector portion 34 is affected by the injection pressure of the resin, and the injection pressure is reduced. There is a concern that the position of the second thermistor 32 may be displaced without being able to endure, and that the lead may be buried due to a bias. If the lead wire is biased, the tip of the connector 34 may be bent by cooling and shrinking after resin molding.

If the second thermistor is not arranged at the designed position and the lead wire of the second thermistor is exposed outside where the first thermistor is arranged,
Through the lead wire where the heat of the first thermistor is exposed,
There is a possibility that heat will be transmitted to the second thermistor.

[0008] An object of the present invention is to eliminate the bias of lead wires,
An object of the present invention is to provide a sensor holder for holding a thermistor in a correct position and a composite sensor using the sensor holder.

[0009]

According to another aspect of the present invention, there is provided a sensor holder having a connector portion and a rod portion, wherein the connector portion and the rod portion are made of synthetic resin. The molded part is a molded part, the connector part has a pair of terminals, the paired terminals are partially embedded in the molded part and held at a fixed position, and the rod part is connected to the connector part and is rod-shaped. The thermistor is buried at the tip, the lead wire of the thermistor pair is covered with an insulating tube, twisted with each other, passed through the rod part, and connected to each terminal of the connector part in the molded body. Is what it is.

Also, in the composite sensor, the composite sensor using the sensor holder includes a first thermistor and a second thermistor, the first thermistor being housed in a case, and a second thermistor. Is a thermistor in the sensor holder, and the sensor holder is combined with the case.

The sensor holder further includes a first thermistor electrode plate and a terminal thereof. The first thermistor electrode plate is attached to the connector portion around the rod portion of the sensor holder, and the first thermistor electrode plate is attached to the connector portion. The thermistor terminal is embedded in a part of the sensor holder and is electrically connected to the electrode plate in the molded body.The case is a metal hollow container, and has a large-diameter portion connected to each other. A small-diameter part, a large-diameter part is a cylinder having an opening, the small-diameter part is a bottomed cylinder having a relatively small diameter, the sensor holder is inserted into the case through the opening, and the connector part is a large-diameter part. Joined to the department
The rod portion reaches the bottom of the small-diameter portion, the first thermistor is housed in the large-diameter portion of the case around the rod portion, and one electrode of the first thermistor communicates with the electrode plate via a spring, and Are connected to the case.

Further, the sensor holder further has first and second electrode plates forming a pair of the first thermistor and respective terminals, and the first electrode plate of the first thermistor is provided on the sensor holder. Attached to the connector section around the rod section, a portion of the second electrode plate is exposed on the periphery of the connector section and electrically connected to the case, and each terminal of the first thermistor is connected to the sensor holder. It is embedded in a part and is electrically connected to each electrode plate individually in the molded body, the case is a metal hollow container,
It has a large-diameter part and a small-diameter part connected to each other, the large-diameter part is a cylinder having an opening, the small-diameter part is a bottomed cylinder having a relatively small diameter, and the sensor holder is inserted into the case through the opening into the case. The connector portion is connected to the large diameter portion, the rod portion reaches the bottom of the small diameter portion, the first thermistor is housed in the large diameter portion of the case around the rod portion, and one of the first thermistors is provided. Is connected to the electrode plate via a spring, and the other electrode is connected to the case.

The sensor holder further has first and second electrode plates forming a pair of a first thermistor and respective terminals, and the first electrode plate of the first thermistor is provided on the sensor holder. The second electrode plate is attached to the connector portion around the rod portion, and the second electrode plate is attached to the first electrode plate at a predetermined interval so as to protrude on the periphery of the rod portion.
Each terminal of the thermistor is embedded in a part of the sensor holder and individually connected to each electrode plate in the molded body, and the case is a metal hollow container and is connected to each other. It has a large diameter part and a small diameter part, the large diameter part is a cylinder having an opening, the small diameter part is a relatively small diameter bottomed cylinder, the sensor holder is inserted into the case through the opening, and the connector part Is connected to the large diameter portion, the rod portion reaches the bottom of the small diameter portion, the first thermistor is interposed between the first and second electrode plates on the periphery of the rod portion, and the first thermistor is connected to the first electrode plate. One electrode of the first thermistor is electrically connected via a spring, the other electrode of the first thermistor directly contacts the second electrode plate, and the second electrode plate and the case are separated by an insulating material. I have.

[0014]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing an embodiment of a composite sensor according to the present invention. 1 and 2,
The composite sensor has a combination of a first thermistor 1 and a second thermistor 2, a case 3, and a sensor holder 4. The first thermistor 1 is a disk-type thermistor for a water thermometer, and has a ring shape having a through hole 1a at the center and is housed in a case 3.

The second thermistor 2 is a glass-enclosed type for the ECU or a coated chip thermistor coated with a plastic such as epoxy resin, and is buried in the sensor holder 4 and housed in the case 3. . The case 3 is a hollow metal container having a large diameter portion 5 and a small diameter portion 6 integrally. The large-diameter portion 5 and the small-diameter portion 6 are cylindrical portions of a container connected coaxially, and the large-diameter portion 5 is a cylinder having an opening for inserting the sensor holder 4 at an upper edge thereof.
Is a bottomed cylinder protruding beyond the cylinder of the large-diameter portion 5, the inner diameter of which is smaller than that of the large-diameter portion 5, and the tip of which is conical. On the other hand, a step 7 is formed at the boundary between the small diameter section 6 and the large diameter section 5, and the first thermistor 1 is installed on the step 7 of the case 3 and housed in the large diameter section 5. . The sensor holder 4 is an electrically insulating synthetic resin molded body having the connector portion 8 and the rod portion 9 integrally.
Is formed in a shape imitating the inner diameter of the large-diameter portion 5 of the case 3, and the rod portion 9 passes through the through hole 1 a of the first thermistor 1 and reaches the bottom of the small-diameter portion 6 of the case 3. have. The second thermistor 2 is embedded at the tip of the rod 9. In the present invention, the pair of lead wires 2a and 2b of the second thermistor 2 is covered with a tube having electrical insulation and heat resistance, for example, a Teflon tube 10, and twisted by twist processing.

The terminal of each lead wire 2a has a terminal 1
1a and 11b are attached, and the electrode plate 12 and the terminal 13 of the first thermistor 1 are integrally assembled and set in a split mold (not shown) of the molding die, and the resin material is placed in the molding die. To the sensor holder 4
To obtain a molded article. The electrode plate 12 is a ring, as shown in FIG.
As shown in (b), a terminal 13 is integrally provided on a shaft portion 12a protruding above a part of the peripheral surface of the ring.
2 is assembled around the rod portion 9 at the end outer surface of the connector portion 8, and the terminal 13 of the electrode plate 12 is partially embedded in the connector portion 8 together with the terminals 11 a and 11 b of the second thermistor 2. Rarely, the remainder protrudes above the connector portion 8 to form a three-terminal socket or plug. Note that the base of the connector portion 8 has a flange portion 16 projecting around.

The rod portion 9 of the sensor holder 4 is inserted through the through hole 1 a of the first thermistor 1 on the stepped portion 7 until the tip reaches the bottom of the small diameter portion 6 of the case 3. Is fitted to the opening edge of the case 3, the opening edge of the case 3 is bent, and the bent edge 3 a is pressed against the flange portion 16 and fixed. Prior to this, a ring serving as an electrode 1b is superimposed on the first thermistor 1, and a coil spring 17 is provided on the rod 9 of the sensor holder 4. When the sensor holder 4 is inserted into the case 3, the connector portion 8 of the sensor holder 4 is pressed into the opening edge of the case 3 against the elasticity of the spring 17, thereby connecting the electrode 1 b on the first thermistor 1. The electrode plate 12 mounted on the sensor holder 4 is electrically connected to the electrode plate 12 by a coil spring 17, which forms one electrode, and the case 3 is used for the other electrode.

A sleeve 18 is inserted into the large diameter portion 5 of the case 3. The sleeve 18 is a cylindrical body made of an insulating material, and the first thermistor 1 and its electrode plate 12
And the surroundings of a spring 17 provided on the rod portion 9 of the sensor holder 4 to electrically isolate these from the case 3. The flange portion 16 formed on the sensor holder 4 is fixed by being pressed against a seating surface formed on the inner periphery of the case 3, and a packing 19 is interposed on the seating surface, and the sensor holder 4 is provided. 4
Is pressed against a packing 19 and hermetically sealed. The seating surface is provided on the sensor holder 4.
Is a reference surface for regulating the insertion depth of the rod portion 9 of the rod portion 9.
Is inserted at a fixed position in the small diameter portion 6 of the case 3.

In the embodiment, the large-diameter portion 5 and the small-diameter portion 6 of the case 3 and the connector portion 8 and the rod portion 9 of the sensor holder 4 have a circular cross section. However, the present invention is not limited to this. Is also good. If the cross section is polygonal, the sensor holder 4 in the case 3 is prevented from rotating, and the thermistors 1 and 2 can be positioned more accurately.

Further, the case 3 may be filled with silicone oil to eliminate the variation in the heat dissipation constant of the first thermistor 1 and the second thermistor 2 and to make the heat dissipation uniform.

The sleeve 18 may be made of an electrically insulating resin, and may be formed integrally with the connector 8 of the sensor holder 4. In this case, the resin sleeve 1
8 is formed coaxially with the rod portion 9 of the sensor holder 4, so that the sleeve 18 includes the electrode 1a, the spring 17,
When the first thermistor 1 and the like are assembled, they can be used for positioning them.

The sleeve 18 is a cylindrical body, and is formed integrally with the sensor holder 4 to form a container. Therefore, the sleeve 18 is used as a silicone oil metering cup, and is filled in the case 3. Oil can be quantified.

In the examples shown in FIGS. 1 and 2, one electrode of the first thermistor 1 is connected to the terminal 13 and the other electrode is connected to the case 3. As shown in FIG. The plate 12 is used as a first electrode plate, a second electrode plate 20 and a terminal 21 are integrally mounted on the connector portion 8 together with a shaft portion 20 a thereof, and a part of the electrode plate 20 is connected to the connector portion 8.
When the terminal 21 is projected on the connector portion 8 in parallel with the terminal 13 by exposing it on the periphery of the case 3 and pressing the bent edge 3a of the case 3, the two terminals 11a and 11b of the second thermistor are connected to each other. A total of four terminals are formed. Of course, a four-terminal composite sensor can also be configured without a case. As shown in FIG.
Also in this example, apart from the electrode plate 12, a long electrode plate 23 of a shaft portion 23a integrally having a terminal 22 is added, the terminal 22 is exposed to the outside, and the shaft portion 23a
Is embedded in the rod portion 9 and the connector portion 8 of the sensor holder 4, and the electrode plate 23 is protruded around the rod portion 9 to be integrally molded. When assembling the sensor holder 4 to the case 3, the spring 17 and the electrode 1 b are interposed between the two electrode plates 12 and 20, and the one electrode plate 2
0 and the case 3 are isolated by an insulating material 24. Thereby, the sensor holder 4 has two terminals 11a and 11b for the first thermistor and two terminals 11a and 11b for the second thermistor.
A total of four terminals including the terminals 13 and 21 are formed. 3 and 4, the same components as those in FIGS. 1 and 2 are denoted by the same reference numerals, and description thereof is omitted.

In any of the embodiments described above, the lead wires 2a and 2b of the second thermistor 2 embedded in the sensor holder 4 are covered with a tube 10 and given a certain twist to form the sensor holder 4. Since the lead wires 2a and 2b are embedded in the molded body, the strength of the lead wires 2a and 2b is large, and the pressure resistance against the injection pressure of the resin material injected into the molding die is increased. The lead wires 2a, 2
b is sealed in the center of the rod portion 9 so that the embedded position does not have a bias. Further, even after the resin of the molded body is cooled after being released from the molding die, the rod portion 9 of the sensor holder 4 hardly bends or warps, and the injection wires and the thermal stress cause the lead wires 2a and 2b to twist. The mating portion is flexibly stretched to relieve the stress, and the second thermistor 2 can be accurately guided and fixed to the tip of the rod portion 9.

[0025]

As described above, the composite sensor according to the present invention incorporates the first thermistor for the water temperature gauge and the second thermistor for the ECU in the same case. To be loaded in the case, the second thermistor is embedded in the molded body of the sensor holder according to the present invention, and the sensor holder is assembled to the case. In the present invention, since the lead wire of the second thermistor is covered with a tube and twisted into one, its strength increases,
The second thermistor maintains the linearity by withstanding the resin injection pressure during molding, and the resin is uniformly wrapped around the lead wire due to the twisted lead wire, the eccentricity of the lead wire itself is small, No warping or bending occurs in the rod part of the sensor holder in which the embedded wire is embedded, and the wire length is reliably extended to the point where the twisted lead wire comes into contact with the point of the tip by the injection pressure at the same time as the molding resin is injected. In addition, the first thermistor and the second thermistor can be maintained at a designed interval by being accurately sealed at the tip of the rod portion. In addition, since the lead wire can be buried evenly in the rod portion, the second thermistor is not affected by the heat generated by the first thermistor, and each thermistor can be operated with high accuracy.

Although the composite sensor of the present invention has been described for use in measuring the water temperature of an automobile engine cooling system, the present invention is not limited to this. Further, the sensor holder is not limited to the case where the sensor holder is assembled into a case and used as a composite sensor, but can also be used as a sensor for various applications.

[Brief description of the drawings]

FIG. 1 is a sectional view showing a first embodiment of a composite sensor according to the present invention.

2A is a sectional view taken along line II-II of FIG. 1, FIG.
FIG. 3 is a view showing an electrode plate.

FIG. 3 is a diagram showing another embodiment of the composite sensor according to the present invention.

FIG. 4 is a sectional view showing still another embodiment of the composite sensor according to the present invention.

FIG. 5 is a diagram showing a preceding example of a composite sensor.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 1st thermistor 2 2nd thermistor 2a, 2b Lead wire 3 Case 4 Sensor holder 5 Large diameter part 6 Small diameter part 7 Step part 8 Connector part 9 Rod part 10 Tube 11a, 11b Terminal 12 Electrode plate 12a Shaft part 13 Terminal DESCRIPTION OF SYMBOLS 14 Molding die 15 Molded body 16 Flange part 17 Coil spring 18 Sleeve 19 Packing 20 Electrode plate 20a Shaft part 21 Terminal 22 Terminal 23 Electrode plate 23a Shaft part 24 Insulation material

Claims (5)

[Claims] 1. A sensor holder having a connector portion and a rod portion, wherein the connector portion and the rod portion are a molded body integrally formed of a synthetic resin, the connector portion has a pair of terminals, The terminal of the pair is held in place by embedding a part in the molded body, and the rod part is a part that is connected to the connector part and protrudes in a rod shape, a thermistor is embedded at the tip, and the pair of the thermistor A sensor holder, wherein a lead wire is covered with an insulating tube, twisted with each other, passed through a rod portion, and connected to each terminal of a connector portion in a molded body. 2. A composite sensor using the sensor holder according to claim 1, comprising a first thermistor and a second thermistor, wherein the first thermistor is housed in a case, Is a thermistor in a sensor holder, wherein the sensor holder is combined with a case. 3. The sensor holder further includes an electrode plate of a first thermistor and a terminal thereof, wherein the electrode plate of the first thermistor is attached to a connector portion around a rod portion of the sensor holder. The thermistor terminal is embedded in a part of the sensor holder and is electrically connected to the electrode plate in the molded body.The case is a metal hollow container, and has a large-diameter portion connected to each other. A small-diameter part, a large-diameter part is a cylinder having an opening, the small-diameter part is a relatively small-diameter bottomed cylinder, the sensor holder is inserted into the case through the opening, and the connector part has a large-diameter part. The first thermistor is housed in the large diameter portion of the case around the rod portion, and one electrode of the first thermistor is connected to the electrode via a spring. The other electrode leads to the plate , Claim 2, characterized in that connected to the casing
2. The composite sensor according to 1. 4. The sensor holder further includes first and second electrode plates forming a pair of a first thermistor and respective terminals, wherein the first electrode plate of the first thermistor is provided on the sensor holder. Attached to the connector section around the rod section, a portion of the second electrode plate is exposed on the periphery of the connector section and electrically connected to the case, and each terminal of the first thermistor is connected to the sensor holder. It is buried in a part and is electrically connected to each electrode plate individually in the molded body.The case is a metal hollow container, and a large diameter portion and a small diameter portion connected to each other are connected. The large diameter part is a cylinder having an opening, the small diameter part is a bottomed cylinder having a relatively small diameter, the sensor holder is inserted into the case through the opening, and the connector part is connected to the large diameter part. , The rod part reaches the bottom of the small diameter part, The first thermistor is housed in the large diameter portion of the case around the rod portion, one electrode of the first thermistor communicates with the electrode plate via a spring, and the other electrode is connected to the case. 3. The method according to claim 2, wherein
2. The composite sensor according to 1. 5. The sensor holder further includes first and second electrode plates forming a pair of a first thermistor, and respective terminals, wherein the first electrode plate of the first thermistor is provided on the sensor holder. The second electrode plate is attached to the connector portion around the rod portion, and the second electrode plate is attached to the first electrode plate so as to protrude on the periphery of the rod portion at a predetermined interval, and is connected to each terminal of the first thermistor. Is embedded in a part of the sensor holder and is individually connected to each electrode plate in the molded body.The case is a metal hollow container, and a large-diameter portion and a small-diameter portion connected to each other are provided. The large diameter part is a cylinder with an opening, the small diameter part is a bottomed cylinder with a relatively small diameter, the sensor holder is inserted into the case through the opening, and the connector part is connected to the large diameter part. The rod part reaches the bottom of the small diameter part, The first thermistor is interposed between the first and second electrode plates on the circumference of the rod portion, and the first electrode plate and one electrode of the first thermistor are electrically connected via a spring. 3. The composite sensor according to claim 2, wherein the other electrode of the thermistor directly contacts the second electrode plate, and the second electrode plate and the case are separated by an insulating material. 4.