JPS63235811A - Sensor structure - Google Patents

Abstract

PURPOSE:To obtain a sensor improved in waterproofness and airtightness and enhanced in vibration resistance and impact resistance, by covering a sensor element part with the first resin part to protect the same from the molding of the second resin part under a high temp. and high pressure condition. CONSTITUTION:A sensor element part consisting of a magnet 2, a coil 3, a magnetic pole 4 and a bobbin 5 is received in a case 8 and the interior thereof is molded up to the vicinity of an opening part 12 by the first resin part 9a. Both ends of the fine wire wound around the coil 3 are soldered to the lower part 6a of a terminal 6 and the lower part 6a is covered with the resin part 9a. A bracket 11 fixing the whole of a rotation sensor is soldered to the outside of the case 8 and the chip end part 13 of an output wire 7 is bonded to the terminal upper part 6b by caulking. The second resin part 9b is formed under a high temp. and high pressure condition by molding to cover the opening part 12, the upper part 6b and the output wire 7. By this method, the wire 7 can be connected after the resin part 9a is allowed to fill and workability is enhanced and the mechanical strength of a sensor structure can be improved using a resin having high mechanical strength in the resin part 9b.

Description

[Detailed Description of the Invention] [Industrial Application Field] Is this invention outside the scope of the invention? A! This is related to Sen + F construction, which requires closeness from the W boundary.

[Prior Art] Various sensors such as rotation sensors, temperature sensors, pressure sensors, and acceleration sensors are conventionally known for use in automobiles and the like. In particular, rotation sensors for wheel speed detection are required to be resistant to salt water, vibration resistance, shock resistance, and waterproofness, as they are installed in harsh external environments, such as inside the Taisei House. .

FIG. 3 is a sectional view showing an example of a conventional rotation sensor. In the rotation sensor 31 shown in FIG. 3, a sensor element section consisting of R[T2, a coil 3, a magnetic pole 4, and a bobbin 5 is housed in a case 8.

Terminals 6 are provided at both ends of the winding wire wound around the coil 3, and the terminals 6 are connected to the tip of an output line 7. Inside the case 8, a resin portion 9 is formed by molding resin. Around the part of the output line 7 located at the opening of the case 80, there is a pipe-shaped protection forest 1 for the output line.
0 is attached. A bracket 11 is attached to the outside of the case 8 for fixing the rotation sensor 31 at a predetermined location.

In addition to the method of using a mounting bracket, there are other methods for adjusting the angle of the rotation sensor, such as cutting threads into the case, pressing the side of the case with bolts, etc.

[Problems to be solved by the invention] In conventional rotation sensors, by molding resin inside the case, the sensor element part inside the case is fixed, and the inside of the case is sealed to make it waterproof and airtight. retains gender.

However, the waterproof and airtight properties of conventional rotation sensors are not necessarily sufficient, and highly reliable rotation sensors with improved waterproof and airtightness are required, especially for automotive sensors that are used for a long time in harsh environments. ing. Also,
Sensors for automobiles are subject to severe vibrations, so sensors with mechanical strength such as impact resistance are also desired.

The purpose of this invention is to satisfy such conventional demands, and to improve waterproof and airtightness, as well as corrosion resistance and resistance*! If
The object of the present invention is to provide a sensor structure with improved f.

Means for Solving Problem E] In the sensor structure of the present invention, the first resin part is filled in the case so as to cover the sensor element part and the lower part of the terminal for connecting the sensor element part and the output line. Further, a second resin part is molded to cover the frontage J3 of the case and the upper part of the terminal.

The first resin part is preferably a thermosetting resin, such as an epoxy resin.

Further, as the second resin part, thermoplastic resin is preferable,
For example, nylon resin is used.

[Function] In the sensor structure of the present invention, the sensor/element part and the lower part of the terminal are covered and protected by the first resin part, so when molding the second resin part at the case opening, high temperature and high pressure is applied. Even if molded under these conditions, the exposed element will not be damaged. Therefore, the second resin part can be molded at higher temperature and pressure, and the sealing performance inside the case can be improved.

Further, in the sensor structure of the present invention, since the first resin part covers only the F part of the terminal, the output line can be connected to the upper part of the terminal after filling the first resin part. Therefore, when filling the first resin part, the output line is connected to the terminal (
Since there is no need to handle it in a vacuum, workability and roughness are significantly improved.

In general, according to the present invention, it is possible to use a material different from that of the first resin part as the material of the second resin part. using resin as a second resin part,
The mechanical strength of the sensor structure can be improved.

[Embodiment] FIG. 1 is a sectional view C showing an embodiment of the present invention. ,
In the rotation sensor 1 shown in FIG. 1, a sensor element section consisting of a stone 2, a coil 3, a magnetic pole 483, a bobbin 5, etc. is housed in a case 8.

The inside of the case 8 is molded with resin up to the vicinity of the frontage 12 of the case 8 by the first resin part 9a.

Both ends of the thin wire wound around the coil 3 are soldered to the lower part 6a of the end 'r-6, and the lower part 68 of the terminal is covered with the first resin part 9a.

Furthermore, a bracket 11 for fixing the rotation sensor 1 is joined to the outside of the case 8 by brazing. Output 1
The tip 13 of 7 is caulked to the upper part 61) of the terminal 6. A pipe-shaped output line protection forest 10 is arranged around the output line 7 near the tip.

The opening 12 of the case 8 is covered by a second resin part 9b, and the upper part 6b of the terminal is covered by the second resin part 9b. The second resin part 9b is molded at high temperature and pressure, so that the case opening 12, the output line protection forest 10, and the output line 7 side surfaces of the bracket 11 are respectively connected to the second resin part 9b. In close contact.

In this embodiment, epoxy resin was used as the material for the first resin part 9a, and glass IJiMt reinforced nylon resin was used as the material for the second resin part 9b.

In addition, urethane resin is used as the material for the output line protection material 10, and stainless steel S is used as the material for the metal case.
US 304 was used, respectively.

FIG. 2 is a sectional view showing another embodiment of the invention,
This shows a magnetic sensor. In the magnetic sensor 21 shown in FIG. 2, a magnetoresistive element 14 is provided so as to be in contact with the bottom surface inside the case 8, and a magnet 2 is provided at the bottom of the magnetoresistive element 14. Furthermore, an electric circuit section 15 is provided above the magnet 2. A pair of terminals 6 are attached to the electric circuit section 15 and connected at the lower part 6a of the terminals. Magnet 2, magnetoresistive element 1
4 and an electric circuit section 15, etc., the sensor element section includes:
It is housed in a case 8, and the inside of the case is shielded by a first resin part 9a. The lower part 6a of the terminal 6, which is the connection part with the sensor element part, is also covered with the first resin part 9a.

The tip 13 of the - output line 7 is connected to the upper part 6b of the end T-6. The opening 12 of the case 8 is covered by a second resin part 9b, and the upper part 6b of the terminal 6 is also covered by the second resin part 9b.

By molding the second resin part 9b at high temperature and high pressure, the case opening 12,
The output line protection forest 10 and the output line 7 side surfaces of the bracket 11 are in contact with the second resin portion 9b. In addition, in this embodiment, the first resin part 9a and the second resin part 9b
The same materials as in the first embodiment were used for the case 8 and the output line protection forest 10.

[Effects of the Invention] In the sensor structure of the present invention, since the sensor element portion is covered and protected by the first resin portion, the second resin portion can be molded at high temperature and high pressure. Therefore, the second resin part and the case opening can be molded in close contact with each other. Therefore, the sealing performance inside the case can be improved more than before.

In addition, with the senna structure of the present invention, an integrated terminal material can be obtained with the output wire separated, and the output wire can be eroded, thereby significantly improving workability and productivity. In addition, when molding the second resin part, the sensor element and the lower part of the terminal are formed in the first resin part.
Since the shield is fixed and protected thermally and mechanically, there is no possibility of deterioration of the sensor element or terminal part during molding of the second resin part.
There is no tl ft2.

In addition, in the embodiment, the rotation sensor J3 and the magnetic center
Although the sensor structure of the present invention has been described by illustrating the sensor structure of the present invention, the sensor structure of the present invention is not limited to these types of sensors, and can be applied to external environments such as temperature sensors, pressure sensors, acceleration sensors, etc. This can be widely applied to senna, which requires airtightness.

[Brief explanation of the drawing]

FIG. 1 is a sectional view showing an embodiment of the present invention. FIG. 2 is a sectional view showing another embodiment of the invention. FIG. 3 is a sectional view of a conventional rotation sensor. In the figure, 1 is a rotating sensor, 2 is a magnet, 3 is a coil, 4 is a magnetic pole, 5 is a bobbin, 7 is an output line, 8 is a case, 9
a is the first resin part, 9b is the second resin part, 12 is the 6n bottom part of the case, 13 is the tip of the output line, 14 is the magnetic resistance element, 15 is the electric circuit part, and 21 is the magnetic sensor. . Figure 1 Figure 2 Procedural amendment 1, Indication of the case Patent Application No. 69771 of 1988 2, Name of the invention Sensor structure 3, Person making the amendment i1 Relationship with the case Patent applicant address Kitahama, Higashi-ku, Osaka 5-15 Name (
213) Sumitomo Electric Industries Co., Ltd. Representative: Tetsubu 4, Agent address: 6, Sumitomo Bank Minamimorimachi Building, 2-1-29 Minamimorimachi, Kita-ku, Osaka, Claims column of the specification subject to amendment and Detailed Description of the Invention Column 7, Contents of Amendment (1) The claims of the specification are as attached. (2) "The opening of the case and the upper part of the terminal" in the 15th to 16th lines of page 4 of the specification is corrected to "the opening of the case, the upper part of the terminal, and the output line." Above 2, Claim (1) A sensor cable section, a case that houses the sensor cable section, and an output line led from the opening side of the case and connected to a terminal of the sensor cable section. A sensor structure comprising: a first resin part filled in the case so as to cover the sensor cord part and the lower part of the terminal; and an opening part of the case that covers the upper part of the terminal and the output line. A sensor structure characterized in that the first resin part is formed at an angle with a second resin part molded to cover the sensor structure.(2) Claims characterized in that the first resin part is a thermosetting resin. The sensor structure according to claim 1. (3) The sensor structure according to claim 2, wherein the thermosetting resin is an epoxy resin. (4) The second resin part is thermoplastic. The sensor structure according to claim 1.2 or 3, characterized in that the thermoplastic resin is a resin. (5) The sensor structure according to claim 4, characterized in that the thermoplastic resin is a nylon resin. sensor structure.

Claims (5)

[Claims] (1) A sensor structure comprising a sensor element section, a case housing the sensor element section, and an output line led from the opening side of the case and connected to a terminal of the sensor element section, the sensor element section and a first resin part filled in the case so as to cover a lower part of the terminal, and a second resin part molded to cover an opening of the case and an upper part of the terminal. Features: Sensor structure. (2) The sensor structure according to claim 1, wherein the first resin portion is a thermosetting resin. (3) The sensor structure according to claim 2, wherein the thermosetting resin is an epoxy resin. (4) The sensor structure according to claim 1, 2 or 3, wherein the second resin portion is a thermoplastic resin. (5) The sensor structure according to claim 4, wherein the thermoplastic resin is a nylon resin.