JPH11211593A - Mounting structure of pressure detector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent the occurrence of such a phenomenon that a diaphragm is strained by a stress applied to a diaphragm type pressure detector, and to prevent the output characteristic and temperature characteristic of the detector, after the detector is incorporated in the main body of a mounting structure for pressure detector provided to a conduit, equipment, etc., front largely varying as compared with those before the detector is incorporated in the main body. SOLUTION: A first step section 18 and a second step section 19 are provided below the detector inserting hole 12 of the main body 11 of a fitting, and the space between the horizontal surface of the second step section 19 and the lower contact surface of a gasket 13 is sealed. Then, flange sections are provided above the sensor base 1 of a pressure sensor and a diaphragm base 4 and both flange sections are combinedly fixed in such a state that the flange sections face oppositely each other. In addition, the space between the lower flange surface of the diaphragm base 4 and the upper contacting surface of the gasket 13 is sealed and the gasket 13 is constituted of a metallic gasket having a nearly rectangular cross section and provided with the upper and lower contacting surfaces. Moreover, the upper flange surface of the sensor base 1 is pressed down by means of a cylindrical sensor retainer 16.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an improvement in a mounting structure of a pressure detector using a sensor chip (pressure-sensitive element), and more particularly to a supply system of a highly corrosive gas in a semiconductor manufacturing facility. It is mainly used.

[0002]

2. Description of the Related Art A diaphragm type pressure detector using a sensor chip (pressure-sensitive element) or a strain gauge has been widely used for detecting a fluid pressure in a pipeline. By the way, in a conventional pressure detector of this type, the outer surface (gas contact surface) of an ultra-thin diaphragm (made of SUS316L), which is generally a pressure detector, is finished by electrolytic polishing, and the outer surface layer of the gas contact surface is provided. Fe and C with a thickness of about 30-50 °
An oxide film mixed with r is formed.

However, the mixed oxide film of Fe and Cr formed on the gas contact surface has a relatively low corrosion resistance and a function of preventing outgassing, and may promote self-decomposition of a semiconductor manufacturing gas by a catalytic action. is there. For this reason, hydrogen chloride (HCl) and hydrogen bromide (HB
r), a supply system of a strongly corrosive gas such as fluorine gas (F ₂ ) or hydrogen fluoride (HF) has a problem that a conventional diaphragm type pressure detector cannot be used.

On the other hand, in order to solve the above problems,
The applicant of the present application has previously developed a diaphragm type pressure detector A using a sensor chip having a structure as shown in FIG. 8, and has disclosed this as Japanese Patent Application No. 8-238706. That is, the pressure detector shown in FIG.
Chromium oxide passivation film (in the case of a Cr ₂ O ₃ · halogen-based gas) or fluoridation passivation film (CrF ₂ , CrF ₃ , FeF ₂ , FeF _3. Gas) or a mixed oxidation passivation film mainly composed of aluminum oxide and chromium oxide (Al ₂ O ₃ / Cr ₂
In the case of O ₃ · ozone-containing gas) 3b is formed,
Corrosion resistance, outgas prevention function, and non-catalytic property are greatly improved as compared with the conventional diaphragm type pressure detector having a structure in which a mixed oxide film of Fe and Cr is provided on the gas contact surface 3a.

Further, in order to enable high-temperature heat treatment (300 ° -500 ° C.) of the diaphragm 3 necessary for forming the passive film 3b, a sensor base 1 on which a sensor element (sensor chip) 2 is attached and a diaphragm 3 Are manufactured separately from the diaphragm base 4 integrally formed with the sensor base 1 after the passivation film 3b necessary for the gas contact surface 3a is formed by heat treatment of the diaphragm 3.
And the diaphragm base 4 is welded 8.

Further, in order to form the passive film 3b to have a uniform thickness over the entire area of the gas contact surface 3a, the diaphragm 3 having a thickness of about 1 mm is formed integrally with the diaphragm base 4 and the diaphragm 3 is formed. Gas contact surface 3
Approximately 0.05 by applying lapping polishing to a
~ 0.06mm (inner diameter about 10mmφ, detected pressure ... several To
After forming the diaphragm 3 of rr to 7 kgf / cm ² abs), the diaphragm 3 is subjected to a heat treatment to form a chromium oxide passive film 3b having a thickness of about 50 °.

In FIG. 8, reference numeral 1c denotes an oil injection hole;
Is a pressure transmission medium (silicone oil), 6 is a ball, 7
Is a lead pin, 9 is a ball weld, and 10 is a fluid pressure. The sensor base 1 has a thick disk shape as shown in FIG. 8, and a concave portion for accommodating and fixing the sensor element 2 is formed on the lower surface side. A flange 1a is provided at an intermediate portion in the thickness direction of the sensor base 1, and an upper surface 1b thereof serves as a pressing surface when the pressure detector A is attached to a pipe or the like as described later. Further, the diaphragm base 4 has a ring-shaped main body 4b having an appropriate thickness and height, and a flange 4 provided above the main body 4b.
The lower surface of the main body 4b serves as a sealing surface when the pressure detector A is attached to a pipe or the like, as described later.

FIGS. 9 and 10 show an example of a conventional structure for mounting a diaphragm type pressure detector on a pipeline. The pressure detector A is inserted through a gasket 13 and a sensor guide 14 into a detector insertion hole 12 provided in the center of a pressure detector attachment main body 11 provided in the middle of the pipe. When the fixing bolt 15 is tightened, the pressure detector A is evenly pressed from above by the sensor retainer 16, whereby the bottom surface 12 a of the insertion hole 12 and the end of the gas contact surface 3 a of the diaphragm 3 (that is, the diaphragm) The gasket 13 inserted between the base 4 and the lower surface of the main body 4b of the base 4 ensures airtightness.

The gasket 13 is made of SUS316L-
As shown in FIG. 9, the cross section of the diaphragm base 4 is finished by chamfering four corners of a rectangular shape using a P (w-melt) material, and the lower surface of the main body 4 b of the diaphragm base 4 and the bottom surface 12 of the insertion hole 12 are formed.
The widths of the contact surfaces 13a and 13b with respect to a are set to about 0.25 mm.

The diaphragm type pressure detector shown in FIG. 8 can reduce the so-called dead space when it is attached to a pipe or the like, and is advantageous in improving gas exchangeability. In addition, the desired passivation film 3b can be relatively easily formed on the gas contact surface 3a to have a uniform thickness with no unevenness, and excellent practical utility is achieved.

However, there are still many problems to be solved in the diaphragm type pressure detector, and the greatest problem among them is caused by stress distortion of the diaphragm 3 when the diaphragm 3 is attached to a pipeline or the like. It is the point of fluctuation of the measured value.

That is, in order to increase the pressure detection sensitivity, the thickness of the diaphragm 3 is selected to be as thin as about 0.05 to 0.06 mm. As a result, when the contact surface 13a of the gasket 13 is in contact with the outer peripheral edge lower surface 4b of the diaphragm base 4 as shown in FIG. 9, stress distortion generated in the diaphragm 3 when tightening with the fixing bolt 15 becomes unavoidable. The stress applied to the sensor element 2 via the oil 5 changes greatly.

Table 1 shows six pressure detectors (sample No. 1).
~ Sample No6) was a free state without incorporation into the pressure detector fixture main body 11, P _O = 0 kg pressure P applied to the diaphragm 3 at the state under the free
3 shows the outputs V _O and V _S (mv) of the detector and the temperature characteristics ZTC and STC (% FS / ° C.) when f / cm ² abs and P _S = 7 kgf / cm ² abs.

The outputs V _O and V _S (mv) were measured at a temperature of 25 ° C. and an applied current of 1.5 mA. In addition, “C” in the temperature characteristics ZTC and STC
"OLD" is a characteristic (% FS) when the temperature drops (25 ° C → 0 ° C).
/ ° C) and “HOT” indicates that the temperature rises (from 25 ° C to 5 ° C).
0 ° C.) (% FS / ° C.).

[0015]

[Table 1]

On the other hand, Table 2 shows that the sample No. 1
The pressure detector of sample No. 6 is assembled into the pressure detector mounting body 11 having the structure as shown in FIG. 9, and under this condition, the pressure P applied to the diaphragm is changed to P _O = 0 kgf in the same manner as in Table 1 above. / Cm ² abs and pressure P _S = 7k
Output V _O , V _S (m when gf / cm ² abs
v), temperature characteristics ZTC, STC (% FS / ° C.), and output variation ΔV _O (difference between V _O before assembling and V _O after assembling)
Is shown.

[0017]

[Table 2]

As is clear from the comparison between Table 1 and Table 2, the pressure P applied to the diaphragm 3 is P _S = 7 kgf /
In the case of a high pressure of about ² cm ² abs, even when the pressure detector is mounted on the pressure detector mounting body 11, the output V is higher than when the pressure detector is in a free state.
_There is no significant difference between _S (mv) and temperature characteristics STC (% FS / ° C.).

However, when the pressure P applied to the diaphragm 3 is low, for example, when the pressure P _O = 0 kgf / cm ² abs, the output V _O becomes 5.2 m due to the assembly of the pressure detector.
v, and the temperature characteristic ZTC
The value of (% FS / ° C.) also fluctuates greatly, for example, from 0.162 to 0.719. That is, from the point of output, the variation of the measured value is too large to be put to practical use, and in addition to the temperature characteristic, it becomes a large fluctuation outside the compensable range, so that it cannot be put to practical use as a pressure detector. There is a difficulty.

[0020]

SUMMARY OF THE INVENTION The present invention relates to a diaphragm-type pressure detector having the structure shown in FIG. 8 disclosed in Japanese Patent Application No. 8-238706, which is actually applied to a pipe line or the like. That is, the output and temperature characteristics are largely fluctuated due to the variation in the stress and strain of the diaphragm caused when the pressure sensor is incorporated into the pressure sensor mounting body, and cannot be put to practical use as a pressure measuring device. In order to solve the problem, even if the pressure detector is fixed to the fixture body by improving the mounting structure of the pressure detector to the pressure sensor fixture body, the output and temperature The pressure detector can be applied to piping lines without causing any difference from the output and temperature characteristics under the free condition, and without increasing the dead space of the fluid passage. The Rukoto, it is an primary object of the invention.

[0021]

The inventors of the present invention have found that, through the output and temperature characteristic tests of the pressure detectors shown in Tables 1 and 2, the stress strain applied to the diaphragm when the pressure detector is assembled is determined by each characteristic. We found that it was the direct cause of the fluctuation, and repeated many output and temperature characteristics tests on the mounting structure of various pressure sensors.

The present invention has been made based on the results of the above-mentioned numerous output / temperature characteristic tests.
According to the invention, a pressure detector A formed by combining and fixing a diaphragm base 4 having a diaphragm 3 and a sensor base 1 having a built-in sensor element operated by displacement of the diaphragm 3 is attached to a pipeline or a mechanical device. The gasket 13 is inserted into the detector mounting hole 12 of the pressure detector mounting body 11 with the gasket 13 interposed therebetween.
In the pressure detector mounting structure in which the pressure detector A is pressed and fixed in an airtight manner by the sensor retainer 16 inserted therein, the lower part of the detector insertion hole 12 of the pressure detector mounting body 11 is provided. Provided with a first step portion 18 and a second step portion 19,
A portion between the horizontal surface 19b of the second step portion 19 and the lower contact surface 13b of the gasket 13 is used as a seal portion, and a flange portion 1a and a flange portion 4a are provided above the sensor base 1 and the diaphragm base 4 of the pressure detector A. Provided, both flange portions 1a, 4a
And a seal is provided between the lower surface 4c of the flange 4a of the diaphragm base 4 and the upper contact surface 13a of the gasket 13.
3 is a metal gasket 13 having an upper contact surface 13a and a lower contact surface 13b having a substantially rectangular cross section, and a sensor base 1 of the pressure detector A is formed by a cylindrical sensor retainer 16.
Pressing the flange upper surface 1b downward is a basic configuration of the present invention.

According to a second aspect of the present invention, in the first aspect, the pressure detector A is provided with a sensor chip (pressure-sensitive element) therein.
And a pressure detector A containing silicon oil.

According to a third aspect of the present invention, there is provided the detector insertion hole 12 forming the fitting portion of the gasket 13 according to the first aspect of the invention.
Peripheral wall surface 19a of the second step portion 19 and the diaphragm base 4
The length of the space between the main body 4b and the outer peripheral surface 4d is set to be substantially the same as or slightly larger than the width of the gasket 13.

According to a fourth aspect of the present invention, in the first aspect, the peripheral wall surface 19a of the second step portion 19 of the detector insertion hole 12 and the outer peripheral surface 13c of the gasket 13 are brought into contact with each other and the main body portion 4b Outer peripheral surface 4d and inner peripheral surface 13d of gasket 13
And the upper surface 16 of the flange portion of the sensor base 1.
Is a contact surface of the sensor presser 16.

[0026]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a front view in which a part of a diaphragm type pressure detector A used in the present invention is longitudinally cut, and FIG. 2 shows an internal electric circuit of the pressure detector. FIG.
In FIG. 2, A is a pressure detector, 1 is a sensor base, 2 is a sensor element (sensor chip), 3 is a diaphragm, 3a is a gas contact surface, 3b is a passive film, 4 is a diaphragm base, and 4a is a diaphragm base. A flange portion, 4b is a main body portion, 4c is a lower surface of the flange portion, 4d is an outer peripheral surface of the main body portion 4b, 5 is a pressure transmitting medium (silicon oil), 6 is a sealing ball, 7 is a lead pin, 8 is a welding portion, 9 is a ball weld, 10 is a fluid pressure,
R ₁ to R ₄ the resistance, G is the ground electrode.

A flange portion 1a and a flange portion 4a are formed above the sensor base 1 and the diaphragm base 4, respectively, and the outer peripheral portions thereof are welded 8 with the both flange portions 1a and 4a facing each other. ing. In the diaphragm type pressure detector A used in the present invention, the diaphragm base 4 is formed of a ring-shaped main body 4b and a flange 4a, and a lower surface 4c of the flange 4a is described later. The seal surface is in contact with the upper contact surface 13a of the gasket 13. Therefore, the lower surface 4c of the flange 4a is finished to a highly accurate smooth surface.

The structure and operation of the pressure detector A are the same as those shown in FIG. 8 except that the lower surface 4c of the flange 4a of the diaphragm 4 is used as a contact surface with the upper contact surface 13a of the gasket 13.
And the pressure detector A according to the prior application of the present applicant shown in FIG.
Therefore, the detailed description is omitted here.

In the present embodiment, the diameter of the diaphragm base 4 is 13 mmφ, the diameter of the diaphragm pressure receiving surface is 11 mmφ, the thickness of the diaphragm 3 is 0.06 mm, and the passive film 3b is about 200 mm thick. A pressure detector A having a total thickness of 4 mm and seven lead pins (one of which is a ground electrode) is used. Further, as shown in FIG. 2, DC5V is the input circuit, 1.5MmA is applied, by pressure applied to the sensor element (sensor chip) is changed, the resistance value of 4 Ke formed by a sensor chip R ₁ ~
R ₄ is changed, the output voltage V between the output terminals is changed.

The diaphragm type pressure detector A shown in FIG. 1 has a structure in which the diaphragm base 4 and the diaphragm 3 are integrally formed, but the pressure detector A is of another type. For example, as shown in FIG. 7, the diaphragm 3 and the diaphragm base 4 are formed as separate bodies, and the outer peripheral end of the dish-shaped diaphragm 3 is welded 17 to the outer peripheral surface 4d of the main body 4b of the diaphragm base 4. It may be a vessel. In addition, pressure detector A
Replaces the use of silicon oil and sensor chips,
A so-called metal strain gauge (not shown) is attached as a sensor element to the back surface of the diaphragm, and a pressure detector A having a configuration in which distortion of the diaphragm due to fluid pressure is transmitted to the strain gauge to obtain an output proportional to the fluid pressure is used. It is also possible.

FIG. 3 is a longitudinal sectional view showing a mounting structure of the diaphragm type pressure detector according to the present invention, FIG. 4 is a plan view thereof, and FIG. 5 is an enlarged view of a part of FIG. 3 to 5, A is a pressure detector, 11 is a pressure detector mounting body, 1 is a sensor base, 3 is a diaphragm, 3a is a gas contact surface, 4 is a diaphragm base, 15 is a fixing bolt,
Reference numeral 16 denotes a sensor presser.

The main body 11 of the pressure detector mounting member is inserted in the middle of a pipe (not shown), or is attached and fixed to a fluid-using device or a pipe by direct welding, and is usually made of stainless steel (SUS316L or the like). ). A cylindrical detector insertion hole 12 is formed in the center of the upper part of the attachment main body 11, and the bottom of the insertion hole 12 has two steps of a first step 18 and a second step 19. The diameter is reduced throughout.

That is, the peripheral wall surface 18 a of the first step portion 18 of the insertion hole 12 serves as a guide surface of the sensor retainer 16. The peripheral wall surface 19a of the second step 19 of the insertion hole 12 is in contact with the outer peripheral surface 13c of the gasket 13, and the horizontal plane 19b is in contact with the lower contact surface 13b of the gasket 13.
The fitting portion of the gasket 13 is formed by 9a and the horizontal surface 19b. Further, the inside of the horizontal surface 19b of the second step portion 19 of the insertion hole 12 is formed in a tapered portion 11b, and the center of the bottom surface of the insertion hole 12 has a fluid passage 11a.
Are drilled.

The gasket 13 has a circular ring shape, and the cross section of the sheet portion is formed in a vertically long quadrangular shape with four chamfered rectangular corners. The inner peripheral surface 13d of the gasket 13 is not in contact with the outer peripheral surface 4d of the main body 4b of the diaphragm base 4.
The upper contact surface 13a of the gasket 13 contacts the lower surface 4c of the flange 4a of the diaphragm base 4. Further, the outer peripheral surface 13c of the gasket 13 is in contact with the peripheral wall surface 19a of the second step portion 19. That is, the fitting portion of the gasket 13 is formed by the flange lower surface 4 c of the diaphragm base 4, the peripheral wall surface 19 a of the second step portion 19, and the horizontal surface 19 b, and the second step portion 19 of the detector insertion hole 12 is formed. The distance between the peripheral wall surface 19a and the outer peripheral surface 4d of the flange main body is set to be substantially the same as or slightly larger than the lateral width of the gasket 13.

In FIGS. 3 to 5, the gasket 13 has an outer diameter of 14.7 mm, an inner diameter of 13.0 mm, a width of 0.8 mm for the sheet portion, and a 0.9 m thickness (height) for the sheet portion.
m, width 0.4 mm of the contact surfaces 13a and 13b of the seat portion
The gasket 13 is made of SUS316L-P (w melt).

The sensor retainer 16 is formed of a thick cylindrical retainer 16a having a flat lower end surface and a rectangular flat plate 16b provided at the upper end thereof. The upper surface of the flange 1a of the sensor base 1 is pressed downward by the lower end surface of the pressing body 16a by tightening it into a bolt hole (not shown) on the main body 11 side. As a result, between the horizontal surface 19b of the second step portion 19 and the lower contact surface 13b of the gasket 13, and between the lower surface 4c of the flange portion of the diaphragm base 4 and the lower contact surface 1 of the gasket 13.
The space between 3a is hermetically sealed.

In the mounting structure of the pressure sensor according to the present invention, as shown in FIG.
The lower surface 4c of the flange portion 4a provided with the diaphragm base 4
A gasket 13 is disposed between the outer peripheral surface 4d of the thick (about 2 mm) main body 4b and the gasket 13
13d and the outer peripheral surface 4d of the main body 4b are in a non-contact state, so that a downward pressing force is applied to the gasket 13 by the sensor presser 16 via the sensor base 1 and the diaphragm base 4. Well, gasket 1
All the upward and downward reaction forces of the diaphragm 3 are received by the flange 4a and the main body 4b of the diaphragm base 4, and the diaphragm 3 formed integrally with the main body 4b of the diaphragm base 4 has a distortion during tightening. No stress is applied.
In addition, since the taper portion 11b is provided at the center of the bottom surface of the detector insertion hole 12 to increase the gap on the lower surface side of the diaphragm 3, gas replacement is enhanced.

Table 3 shows that five new pressure sensors (samples No. 1 to No. 5) were kept free and their output and temperature characteristics were measured under the same conditions as in Table 1. Things.

[0039]

[Table 3]

Table 4 shows the above-mentioned five pressure sensors.
3 and 4 relating to the light to the fixture body 11
Built-in, output and temperature characteristics under the same conditions as in Table 2 above
Nature and pressure P_O= 0kgf / cm^Two・ Changes in case of abs
Momentum (output V in free state) _OOutput when embedded with
V_O(Difference from this).

[0041]

[Table 4]

As can be seen from the value of the variation ΔV _O (mv) in Table 4, according to the mounting structure of the pressure detector according to the present invention, the pressure detector after the assembly at the pressure P _O = 0 kgf / cm ² · abs. The variation ΔV _O of the output value is in a range of ± 3.5 mV or less, which is about ４ of the variation shown in Table 2 above.
It decreases to about 1/2. As a result, even when assembled into an actual pipeline, it can be sufficiently put into practical use by a predetermined calibration operation.

[0043]

According to the present invention, a plurality of steps are formed below the detector insertion hole 12 of the pressure detector mounting body, and the diaphragm base of the pressure detector is formed with a flange and a thick wall. And a gasket 1 having a substantially rectangular cross section.
3 is arranged in a fitting portion formed by the peripheral wall surface of the second step portion, the horizontal surface, and the lower surface of the flange portion of the diaphragm base. As a result, even if the sensor retainer is inserted into the detector insertion hole and the upper part of the sensor base is pressed downward, the reaction force applied to the diaphragm base 4 via the gasket 13 is completely reduced. The distortion caused by the reaction force hardly occurs in the diaphragm 3 received by the portion 4a and the thick main body 4b and integrated with the main body 4b. Therefore, fluctuations in output and temperature characteristics before and after mounting the pressure detector to the mounting
Even in the low-pressure region of the fluid, it becomes extremely small and does not become a practical obstacle, so that this kind of diaphragm type pressure detector can be applied to a piping line or the like. The present invention has excellent practical utility as described above.

[Brief description of the drawings]

FIG. 1 is a sectional front view of a part of a diaphragm type pressure detector used in the present invention.

FIG. 2 is an internal connection diagram of the pressure detector of FIG.

FIG. 3 is a longitudinal sectional view showing an assembly structure of a pressure detector according to the present invention.

FIG. 4 is a plan view of FIG. 3;

FIG. 5 is an enlarged view of a portion A in FIG. 3;

FIG. 6 is a longitudinal sectional view of a gasket used in the present invention.

FIG. 7 illustrates another type of pressure detector used in the present invention.

FIG. 8 is a front view in which a part of a diaphragm type pressure detector developed earlier by the applicant has been longitudinally cut.

FIG. 9 is a longitudinal sectional view showing a conventional structure for mounting a diaphragm type pressure detector on a pipeline.

FIG. 10 is a plan view of FIG. 9;

[Explanation of symbols]

A is a diaphragm type pressure detector, 1 is a sensor base,
1a is a flange, 1b is a flange upper surface, 1c is an oil injection hole, 2
Is a sensor element, 3 is a diaphragm, 3a is a gas contact surface,
3b is a passive film, 4 is a diaphragm base, 4a is a flange, 4b is a main body, 4c is a lower surface of the flange, 4d is an outer peripheral surface of the main body, 5 is a pressure transmitting medium (silicone oil), 6 is a sealing ball. , 7 are lead pins, 8 is a welded portion, 9 is a ball welded portion, 10 is a fluid pressure, 11 is a pressure detector mounting body, 1
1a is a fluid passage, 11b is a tapered portion, 12 is a detector insertion hole, 12a is an insertion hole bottom surface, 13 is a gasket, 13a
Is an upper contact surface, 13b is a lower contact surface, 13c is an outer peripheral surface,
13d is an inner peripheral surface, 14 is a sensor guide, 15 is a fixing bolt, 16 is a sensor retainer, 16a is a retainer, 16b is a flat plate, 17 is welding, 18 is a first step portion, 18a is a peripheral wall surface,
19 is a 2nd step part, 19a is a peripheral wall surface, 19b is a horizontal surface.

 ────────────────────────────────────────────────── ─── Continuing on the front page (72) Ryosuke Doi 2-3-2, Noribori, Nishi-ku, Osaka, Osaka Prefecture Fujikin Co., Ltd. (72) Koji Nishino 2-3-2, Noribori, Nishi-ku, Osaka, Osaka Fujikinnai Co., Ltd. (72) Inventor Tomio Uno 2-3-2, Noribori, Nishi-ku, Osaka-shi, Osaka Fujikin Co., Ltd. (72) Inventor Michio Yamaji 2-3-2, Noribori, Nishi-ku, Osaka-shi, Osaka Fujikinnai (72) Inventor Shinichi Ikeda 2-3-2 Nobori, Nishi-ku, Osaka-shi, Osaka Fujikin Co., Ltd.

Claims (4)

[Claims] 1. A sensor base (1) including a diaphragm base (4) having a diaphragm (3) and a sensor element operated by displacement of the diaphragm (3).
A pressure detector mounting body (11) in which a pressure sensor (A) formed by combining and fixing the above is mounted on a pipeline or a mechanical device.
A gasket (13) is inserted into the detector insertion hole (12) of the above, and the pressure detector (A) is inserted by the sensor presser (16) inserted into the detector insertion hole (12) from above. In a pressure detector mounting structure in which the pressure sensor is pressed and fixed in an airtight manner, a first step portion (18) is provided below the detector insertion hole (12) of the pressure detector mounting body (11). And a second step portion (19), and a horizontal surface (19) of the second step portion (19) is provided.
b) and a lower contact surface (13b) of the gasket (13) as a seal portion, and a flange portion (1a) above the sensor base (1) and the diaphragm base (4) of the pressure detector (A). And a flange (4a).
a) and (4a) are combined and fixed to face each other, and the lower surface (4) of the flange (4a) of the diaphragm base (4) is fixed.
c) and the upper contact surface (13a) of the gasket (13) as a seal portion, and further, the gasket (13) is formed of an upper contact surface (13a) and a lower contact surface (1) having a substantially rectangular cross section.
3b) a metal gasket (13) having a configuration in which the upper surface (1b) of the flange portion of the sensor base (1) of the pressure detector (A) is pressed downward by the cylindrical sensor retainer (16). A mounting structure of a pressure detector characterized by the above-mentioned. 2. The pressure detector mounting structure according to claim 1, wherein the pressure detector (A) is a pressure detector (A) containing a sensor chip (pressure-sensitive element) and silicone oil therein. 3. A peripheral wall (19) of a second step portion (19) of a detector insertion hole 12 forming a fitting portion of a gasket (13).
The distance between the a) and the outer peripheral surface (4d) of the main body (4b) of the diaphragm base (4) is set to be substantially the same as or slightly larger than the width of the gasket (13). A mounting structure for a pressure detector according to claim 1. 4. A second step (1) of a detector insertion hole (12).
9) and the outer peripheral surface (13c) of the gasket (13) is brought into contact with the outer peripheral surface (4d) of the main body (4b) and the inner peripheral surface (13d) of the gasket (13). The mounting structure for a pressure detector according to claim 1, wherein the contact is made, and the upper surface (1b) of the flange portion of the sensor base (1) is used as a contact surface of the sensor retainer (16).