JP2969514B2 - Mounting structure of sensor for fluid measurement - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a variety of fluid measurement sensors such as a pressure sensor for measuring a fluid pressure of a chemical solution, an optical sensor for measuring the degree of contamination of a fluid, and a temperature sensor for measuring a fluid temperature. The present invention relates to a structure for mounting on a system, and more particularly, to a mounting structure for a fluid measurement sensor in which the above-described sensor is incorporated in a pipe joint such as a tee forming a part of a fluid piping system.

[0002]

2. Description of the Related Art Conventionally, as a mounting structure in which a fluid measuring sensor such as a pressure sensor is incorporated in a pipe joint such as a tee forming a part of a fluid piping system, for example, Japanese Patent Application Laid-Open No. 9-166 is disclosed.
As disclosed in Japanese Patent Publication No. 512, a sensor is mounted on a lid for sealing an open end of a joint body, and a fluororesin cylindrical sensor case containing the sensor is attached to an inner wall of an end of the pipe joint body. And fixing the lid and the sensor case to the pipe joint body by screwing a push ring screwed into the outer wall of the pipe joint body.

[0003]

In the above-described conventional sensor mounting structure, the sensor is mounted on the fluid pipe because the sensor is built in the pipe joint body itself which constitutes a part of the fluid pipe system. It is not necessary to add any special equipment to reduce the sensor installation cost, and it is easy to install and remove the sensor for maintenance such as maintenance, inspection, and replacement. Since it is built into the sensor case, even if it is a highly corrosive fluid such as a chemical solution, it protects the sensor from corrosion, and furthermore, there is no unnecessary inclusion that obstructs the flow of the fluid. Therefore, it is possible to maintain a smooth flow of the fluid without generating a fluid pool.

However, in the above-mentioned conventional sensor mounting structure, since the cylindrical sensor case is directly fitted to and fixed to the inner wall at the end of the pipe joint body, the flow of a high-temperature fluid or a fluid having a large temperature fluctuation is circulated. When creep or stress relaxation occurs in the cylindrical sensor case due to, a small gap is generated between the sensor case and the fitting body,
There is a great difficulty in sealing performance, such as leakage of fluid through the gap or retention of fluid.
Therefore, a sensor that measures fluids that are highly corrosive, such as chemicals, and can cause significant inconvenience to the surroundings if leaked to the outside, and that may cause errors in measured values such as pressure. Was unsuitable as a mounting structure.

[0005] The present invention has been made in view of the above-mentioned circumstances, and reduces the cost by incorporating a sensor in the pipe joint body itself, simplifies maintenance, and maintains the function of protecting the sensor. It is an object of the present invention to provide a mounting structure for a fluid measurement sensor capable of ensuring excellent sealing performance and achieving a predetermined measurement with high accuracy even for a severe fluid.

[0006]

In order to achieve the above object, a mounting structure for a fluid measuring sensor according to the present invention has a cylindrical receiving end at an end thereof. A pipe joint body in which at least an inlet portion has a seal portion crossing the axis of the socket, and a sealable portion that can be inserted into the tubular socket of the pipe joint body and in the inserted state. A cylindrical seal member having a seal portion abutting on
A built-in fluid measurement sensor, a resin sensor case that can be fitted into the cylindrical seal member, and screwed into an end of the joint body, screwing the cylindrical seal member to the sensor case. And a pressing ring that presses from the outside to apply a sealing force to the sealing portion on the cylindrical sealing member side and the sealing portion on the receiving side.

According to the first aspect of the present invention having the above-described structure, the sealing portion on the tubular receiving side of the pipe joint body is screwed by the push ring screwed into the end of the pipe joint body. And a sealing portion on the side of the cylindrical sealing member inserted into the cylindrical receiving port, a strong sealing force is applied, so that the sealing performance between the pipe joint body and the sensor case can be kept high. It is. By fitting a resin sensor case with a built-in fluid sensor into a cylindrical seal member inserted and installed in the socket of the fitting body with such excellent sealing performance secured, the sensor installation cost is reduced. And easy installation and removal for maintenance such as maintenance, inspection, and replacement of the sensor.
Further, even with a highly corrosive fluid such as a chemical solution, the sensor can be protected from corrosion, and at the same time, adverse effects on the surroundings due to leakage of the fluid and occurrence of measurement errors can be avoided.

The mounting structure for a fluid measurement sensor according to the second aspect of the present invention has a cylindrical receiving port at an end,
A pipe joint body in which a primary seal portion is formed in a deep portion of the socket, and a secondary seal portion crossing the axis of the port is formed in an inlet portion; A cylindrical seal member that can be inserted into the cylindrical receptacle and has an inner end seal portion abutting on the primary seal portion and an outer end side seal portion abutting on the secondary seal portion in the inserted state; A resin sensor case which has a built-in sensor and can be fitted into the cylindrical seal member, and is screwed to the end of the joint body, and the cylindrical seal member is pressed from the outside of the sensor case by screwing. The cylindrical seal member further includes an inner end seal portion and an outer end side seal portion, and a pressing ring for applying a sealing force to the primary seal portion and the secondary seal portion of the receiving port.

According to the second aspect of the present invention having the above-described structure, the primary seal portion and the secondary seal portion of the pipe joint body are screwed by the push ring screwed to the end of the pipe joint body. And the inner end seal portion and the outer end side seal portion of the cylindrical seal member are respectively provided with a strong sealing force by being inserted into the cylindrical socket of the pipe joint body, thereby providing a sealing performance between the pipe joint body and the sensor case. And the cylindrical seal member is strongly pinched and held from both sides in the axial direction by the press ring and the primary seal portion of the pipe joint body, and the fluid flowing through the pipe joint body is a high-temperature fluid or a fluid with severe temperature fluctuation. Even in this case, it is possible to suppress creep and stress relaxation of the cylindrical seal member. By fitting a resin sensor case with a built-in fluid sensor into a tubular seal member attached to the fitting body with such excellent sealing performance and creep resistance secured, the sensor installation cost is reduced. In addition to reducing the number of sensors and facilitating installation and removal for maintenance such as sensor maintenance, inspection and replacement, even for highly corrosive fluids such as chemicals,
While protecting the sensor from corrosion,
It is possible to avoid adverse effects on the surroundings due to leakage of the fluid and occurrence of measurement errors.

In the mounting structure for a fluid measuring sensor according to the second aspect of the present invention, the primary sealing portion at the inner portion of the cylindrical receiving portion and the inner end sealing portion of the cylindrical sealing member may be used. As described in (4), the secondary seal portion is formed in a crossing direction opposite to the axis of the receiving port, or as described in (4), an inner side crossing with the axis of the receiving port. By forming a two-stage seal part with a seal part and an outer seal part that fits deeply along the axis of the receptacle, the function of preventing fluid leakage (seal performance) is further enhanced, and pressure measurement accuracy is particularly improved. It is possible to

Further, by forming the sensor case, which is in contact with the fluid flowing through the inside of the pipe joint body, from a fluororesin, even if the fluid is a highly corrosive chemical, It is possible to prevent corrosion of the sensor case and contamination of the chemical solution.

[0012]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a longitudinal sectional view showing a first embodiment of a mounting structure of a pressure sensor which is an example of a sensor for measuring fluid according to the present invention. In FIG. 1, reference numeral 1 denotes a resin pipe joint called a tee. The pipe joint 1 is formed of a fluororesin having excellent properties such as chemical resistance and heat resistance such as PFA, PTFE, and CTFF, and has a straight line for connecting the two fluid pipes 2 and 2 linearly. Ends of a rising pipe portion 5B having cylindrical receiving ports 3, 3 at both left and right ends of the tubular portion 5A and integrally projecting upward from an axial center of the linear tubular portion 5A. A pipe joint body 5 having a cylindrical socket 4 therein, cylindrical seal members 6, 6 and 7 inserted into the three cylindrical sockets 3, 3 and 4 of the pipe joint body 5, and three pressing rings 8 , 8 and 9.

Each of the tubular sockets 3 in the pipe joint body 5
At the back of 3 and 4, the axis C1 of the sockets 3, 3 and 4
And C2, the primary seal portion 10 having a tapered surface whose diameter gradually decreases outward in the axial direction.
10 and 11 are formed, and the entrances of the respective cylindrical sockets 3, 3 and 4 are crossed in the direction opposite to the primary seals 10, 10 and 11 with respect to the axes C1 and C2, In other words, the secondary seal portions 12, 12, and 13 each having a tapered surface whose diameter gradually increases outward in the axial direction.
Are formed on the outer periphery of the receiving ports 3, 3 and 4, respectively.

The cylindrical seal member 6 has a fitting portion 16 having an outer diameter fitted to the tubular receiving port 3 at an inner end thereof, and a vicinity of a connecting portion with the fitting portion 16. The press-fit portion 17 having an outer diameter smaller by the thickness of the fluid pipe 2 corresponds to the fitting portion 1.
6 is formed in a sleeve shape as a whole. The inner circumference of the cylindrical seal member 6 has the same diameter as the inner circumference of the fluid pipe 2 and the inner circumference of the straight pipe portion 5A of the pipe joint body 5, and is formed so as not to obstruct the flow of the fluid. In addition, an inner end seal portion 18 formed of a tapered surface that comes into contact with the primary seal portion 10 is formed at an inner end portion of the cylindrical seal member 6, and an outer periphery of the outer end portion, that is, an outer periphery of the press-fit portion 17. The diameter gradually increases from the outer end toward the inner end in the axial direction.
Further, a tapered outer end side seal portion 19 whose outer end intersects the inner periphery of the cylindrical seal member 6 is formed, and the diameter of the top portion of the outer end side seal portion 19 is the outer diameter of the fitting portion 16. It is set larger than. That is, the outer end side seal portion 1
The large-diameter side of 9 forms a bulged portion 20 having a mountain-shaped cross section on the outer peripheral surface on the outer end side of the cylindrical seal member 6, and gradually from the top of the bulged portion 20 to the inner end side of the cylindrical seal member 6. The inclination angle of the tapered surface 23 whose diameter is reduced coincides with the inclination angle of the secondary seal portion 12 in the pipe joint body 5 and the inner end seal portion 1 is formed.
When the pipe 8 comes into contact with the primary seal portion 10 of the pipe joint body 5, the opposed interval between the secondary seal portion 12 and the tapered surface 23 is formed to be an interval corresponding to the thickness of the fluid pipe 2. .

The cylindrical sealing member 6 having the above-described structure is
As shown in FIG. 2, the press-fitting portion 17 is press-fitted into one end of the fluid pipe 2 to expand the peripheral wall of one end of the fluid pipe 2,
Further, the fitting portion 16 of the cylindrical seal member 6 is integrally connected to the fluid pipe 2 by protruding from the one end of the fluid pipe 2. At this time, the enlarged diameter portion of the peripheral wall of the fluid pipe 2 is
The pressing portion 21 is pressed into the pressing portion 21. In a state where the pushing portion 21 is pushed into the receiving port 3, the inner end seal portion 18 is in contact with the primary seal portion 10 of the pipe joint body 5, and the outer end side seal portion 19 is in contact with the pushing portion 21. It is in contact with the inner surface of the inclined portion 22. Further, the secondary seal portion 12 of the pipe joint body 5 and the tapered surface 2 of the cylindrical seal member 6 are formed.
3, one end of the fluid pipe 2 is sandwiched in an inclined state, and when the peripheral wall enlarged diameter portion of the fluid pipe 2 is pushed into the receiving port 3 of the pipe joint body 5, the cylindrical seal member 6 is closed. The outer peripheral surface of the fluid pipe 2 deformed along the tapered surface 23 contacts the secondary seal portion 12 of the pipe joint body 5.

On the other hand, as shown in FIG. 3, the cylindrical seal member 7 is formed at its inner end with an inner end seal portion 24 having a tapered surface which comes into contact with the primary seal portion 11 of the receiving port 4. The outer end near the outer end has a tapered surface that gradually decreases in diameter from the outer end toward the inner end in the axial direction and abuts against the secondary seal portion 13 of the receptacle 4. A seal portion 25 is formed. At the inner end of the cylindrical seal member 7, a thin portion 26 that is deformed in accordance with fluid pressure is formed in connection with the inner periphery of the inner end seal portion 24.
A pressure sensor 27 is provided in the cylindrical seal member 7.
A sensor case 28 made of a fluororesin containing therein is fitted. A flange 29 having substantially the same diameter as the outer diameter of the outer end surface of the cylindrical sealing member 7 is provided on the outer peripheral portion near the outer end of the sensor case 28. They are integrally formed to protrude.

The push rings 8 and 9 are female screw portions which can be screwed into male screw portions 14 and 15 formed on the inner peripheral surface of the cylindrical portion 30 on the outer periphery of each of the sockets 3 and 4 in the pipe joint body 5 respectively. 31 and 32 are formed, and annular pressing pieces 33 and 34 extending toward the axial center are integrally formed at the outer ends, and pressing is performed on the inner end of the annular pressing pieces 33 and 34 on the inner surface side. Edge portions 35 and 36 are formed.

Next, an operation for connecting the two fluid pipes 2 and 2 and an operation for installing the pressure sensor 27 using the pipe joint 1 having the above-described components will be described. First, the press-fitting portion 17 of the cylindrical seal member 6 is press-fitted into one end of each fluid pipe 2 so that the diameter of the one end of the fluid pipe 2 is increased as a whole, and the bulging portion 20 of the cylindrical seal member 6 is enlarged.
Is formed at the portion corresponding to the above. The push-in portion 21 of the fluid pipe 2 formed in this manner is inserted into the tubular receptacles 3 at both left and right ends of the straight pipe portion 5A of the pipe joint 1 so that the inner end seal portion 18 of the pipe joint body 5 is inserted. The outer peripheral surface of the fluid pipe 2 deformed along the tapered surface 23 of the cylindrical seal member 6 is brought into contact with the secondary seal portion 12 of the pipe joint body 5 while being brought into contact with the primary seal portion 10.

Next, the female thread portion 31 of the press wheel 8 previously loosely fitted to each fluid pipe 2 is connected to each of the sockets 3 in the pipe joint body 5.
By being screwed into the outer threaded portion 14 on the outer periphery and screwed and strongly tightened, the space between the inner end seal portion 18 and the primary seal portion 10 and the tapered surface 23 of the cylindrical seal member 6 are formed.
Outer peripheral surface of the fluid pipe 2 deformed along the
Between the two fluid pipes 2 in the tubular receiving ports 3 at the left and right ends of the straight pipe portion 5A in the pipe joint body 5 by applying a strong sealing force between the two pipes.
Can be connected in a state where an excellent sealing property is ensured so as to prevent leakage of fluid and intrusion of foreign matter. Also,
The inner circumference of the cylindrical seal member 6 is formed to have the same diameter as the inner circumference of the straight pipe portion 5A in the pipe joint body 5 and does not hinder the flow of the fluid, so that the fluid does not stay and flows smoothly. It is possible to secure the property.

On the other hand, a fluororesin sensor case 28 having a built-in pressure sensor 27 is fitted and held in the cylindrical sealing member 7 and the cylindrical sealing member 7 is attached to the end of the rising pipe portion 5 B of the pipe joint 1. It is inserted into the cylindrical receptacle 4, and the inner end seal portion 24 is brought into contact with the primary seal portion 11 of the receptacle 4, and the outer end side seal portion 25 is brought into contact with the secondary seal portion 13 of the receptacle 4. Contact Thereafter, the female screw portion 32 of the press ring 9 loosely fitted in the sensor case 28 in advance is screwed into the male screw portion 15 on the outer periphery of the socket 4 of the pipe joint body 5, and is screwed forward to be tightly tightened. The cylindrical sealing member 7 is provided via a flange 29 of the case 28.
Are pressed inward in the axial direction to apply strong sealing force between the inner end seal portion 24 and the primary seal portion 11 and between the outer end side seal portion 25 and the secondary seal portion 13, respectively. Seal member 7 is composed of pressing ring 9 and primary seal portion 11
Therefore, even if the fluid flowing through the pipe joint body 5 is a high-temperature fluid or a fluid having a large temperature fluctuation, the creep and stress of the cylindrical seal member 7 can be increased even when the fluid flowing through the pipe joint body 5 is a high-temperature fluid or a fluid having a large temperature fluctuation. The mitigation is suppressed, and the fluid leakage from the built-in portion of the pressure sensor 27 is reliably prevented.

A resin sensor case 28 in which a pressure sensor 27 is built in a cylindrical seal member 7 that can be attached to the pipe joint body 5 with excellent sealing performance as described above.
To reduce sensor installation cost,
The sensor 27 can be easily attached and detached during maintenance such as maintenance, inspection, and replacement, and can achieve a protection function of protecting the sensor 27 from corrosion when the fluid is a highly corrosive fluid such as a chemical. It is possible to avoid adverse effects on the surroundings due to leakage and occurrence of pressure measurement errors.

FIG. 4 is a longitudinal sectional view showing a second embodiment of a pressure sensor mounting structure which is an example of a fluid measurement sensor according to the present invention. The inner diameters of the cylindrical receiving ports 3, 3 formed at the left and right ends of the straight pipe section 5A are set to be the same as the outer diameters of the fluid pipes 2, 2, and the inlet ports of the receiving ports 3, 3 have the same inner diameter. Axis C1
, Seal portions 12 ′, 12 ′ each having a tapered surface whose diameter gradually increases outward in the axial direction are formed.

The end portions of the fluid pipes 2 are respectively inserted into the cylindrical receptacles 3 at both ends of the straight pipe portion 5A so that the inner diameters thereof are the same and a step which causes fluid retention can be prevented. The seal ring 40 is formed with a seal surface 41 formed of a tapered surface whose diameter gradually decreases inward in the axial direction with respect to the axis C1.
1 is brought into contact with the seal portion 12 ′, and the female screw portion 31 of the press ring 8 previously loosely fitted to each fluid pipe 2 is screwed into the male screw portion 14 on the outer periphery of each socket 3 in the pipe joint body 5. And tightly tightened by screwing, so that the sealing surface 41 of the seal ring 40 and the seal portion 1 on the socket 3 side
2 ′ to the two pipes 3 at the left and right ends of the straight pipe section 5A in the pipe joint body 5 so as to prevent fluid leakage or foreign matter intrusion. Connection is possible with excellent sealing properties.

On the other hand, the rising pipe portion 5 in the pipe joint body 5
At the entrance of the cylindrical socket 4 at the end of B, the axis C2 of the socket 4
, A seal portion 13 ′ having a tapered surface whose diameter gradually increases outward in the axial direction is formed. The outer diameter of the cylindrical seal member 7 which can be inserted into the cylindrical receptacle 4 is gradually reduced from the outer end toward the inner end in the axial direction. A seal portion 25 'formed of a tapered surface that comes into contact with the seal portion 13' is formed. As in the first embodiment, a fluororesin sensor case 28 having a built-in pressure sensor 27 is fitted into the cylindrical seal member 7. A flange 29 having substantially the same diameter as the outer diameter of the outer end surface of the cylindrical seal member 7 is integrally formed at the inner end, and a pressure sensor 27 is provided at the inner end.
The thin portion 28a that can operate is formed.

When the pressure sensor 27 is attached to the tubular receiving port 4 at the end of the rising pipe portion 5B of the pipe joint body 5, a fluororesin sensor case 28 containing the pressure sensor 27 is attached to the tubular seal. After fitting and holding the cylindrical sealing member 7 in the member 7, the cylindrical sealing member 7 is inserted into the cylindrical receiving port 4 at the end of the rising pipe portion 5B in the pipe joint body 5, and the outer end side sealing portion 25 'is used as a receiving port. 4, the female thread 32 of the press ring 9, which has been loosely fitted in the sensor case 28 in advance, is screwed into the external thread 15 of the outer periphery of the receptacle 4 in the pipe joint body 5. The cylindrical seal member 7 is pressed inward in the axial direction via the flange portion 29 of the sensor case 28 by being screwed together and screwed tightly, so that the outer end side seal portion 25 'and the seal portion Strong between 13 ' A sealing force is applied, thereby maintaining a high sealing property between the cylindrical sealing member 7 and the cylindrical receiving port 4 on the pipe joint body 5 side, and reliably preventing fluid leakage from the built-in portion of the pressure sensor 27. In a state where the pressure sensor 27 is prevented, the pressure sensor 27 can be attached to the tubular socket 4 at the end of the rising pipe portion 5B in the pipe joint body 5.

In particular, in the second embodiment shown in FIG. 4, the tapered surface of the outer end side sealing portion 25 'of the cylindrical sealing member 7 is set to about 45.degree. By providing an angle difference between the tapered surfaces, such as setting the tapered surface of the seal portion 13 'on the fourth side to about 40 °, the contact surface pressure between the two seal portions 25' and 13 'is increased to improve the sealing performance. It can be kept high.

FIG. 5 is a longitudinal sectional view showing a third embodiment of a pressure sensor mounting structure which is an example of a fluid measurement sensor according to the present invention. Connection structure of fluid pipes 2 and 2 to cylindrical receiving ports 3 and 3 formed at both left and right ends of straight pipe section 5A, and pressure on cylindrical receiving port 4 at end of rising pipe section 5B in pipe joint body 5 Most of the sensor mounting structure is substantially the same as that of the first embodiment, and the difference is that the primary sealing portions 10 and 11 and the cylindrical sealing members 6 and 7 at the back of the cylindrical receiving ports 3 and 4 are different. The inner end seal portions 18 and 24 are aligned with the axes C1 and C
Inner seal portion 1 consisting of a tapered surface intersecting with 2
Outer seal portions 10b, 11b and 18b, 24b which are fitted concentrically and deeply in a press fit along the axes C1, C2 of Oa, 11a and 18a, 24a and the receiving ports 3, 4.
Since the other configuration is the same as that of the first embodiment, the corresponding portions are denoted by the same reference numerals and detailed description thereof will be omitted.

And, in the case of the third embodiment shown in FIG. 5, as in the case of the first embodiment, the pipe joint body 5
The two fluid pipes 2 are connected to the tubular receiving ports 3 at both left and right ends of the straight tubular section 5A in a state where an excellent sealing property for preventing leakage of fluid and intrusion of foreign matter is secured, and a tubular sealing member is provided. 6 has a straight pipe portion 5 in the pipe joint body 5.
A is formed to have the same diameter as the inner circumference of A, so that smooth fluidity can be secured without obstructing the flow of the fluid, and at the same time, the installation cost of the pressure sensor 27 is reduced,
7 can be easily attached and detached during maintenance such as maintenance, inspection and replacement, and a protective function of protecting the sensor 27 from corrosion even with a highly corrosive fluid such as a chemical solution. By adopting this, it is possible to further enhance the sealing performance and to avoid adverse effects on the surroundings due to leakage of fluid from the mounting location of the pressure sensor 27 and occurrence of a pressure measurement error.

In the first and third embodiments, the inner end seal portion 1 of the cylindrical seal members 6, 7 is provided.
8, 24 (24 ') is the primary seal portion 1 of the pipe joint body 5.
Although the one formed on the taper surface having the same angle as 0, 11 (11 ') has been described, the inner end seal portions 18, 24 (24
') Is a taper surface of about 40 °, while the primary seal portion 1
By providing an angle difference between 0 and 11 (11 ') as a taper surface of about 45 °, the two seal portions 18, 10 and 11 (11'), 24
(24 ') can be brought into pressure contact, whereby a strong sealing force can be concentrated on the inner diameter side to eliminate the generation of a fluid stagnation portion.

In each of the above embodiments, the case where the fluid measurement sensor to be attached to the piping system is a pressure sensor has been described. However, the present invention is not limited to this pressure sensor, and the degree of contamination of the fluid is optically detected. Even when applied to the installation of optical sensors and temperature sensors that measure the temperature of fluid, it is possible to achieve the same sealing performance as above and achieve the protection function of protecting the sensor from fluid and the function of improving measurement accuracy. It is.

Further, as shown in each of the above embodiments, by using a fluororesin as the sensor case, even if the sensor case is a corrosive fluid such as a chemical solution, the corrosion of the sensor case can be prevented. Although it is possible to prevent contamination of the chemical solution, the present invention is not limited to this, and a polyethylene resin, an epoxy resin, or the like can be selectively used according to the properties of the fluid.

[0032]

As described above, according to the first aspect of the present invention, the push ring screwed into the end of the pipe joint main body is screwed into the tubular socket side of the pipe joint main body. A strong sealing force is applied to the sealing portion and the sealing portion on the side of the cylindrical sealing member inserted into the cylindrical receiving opening, so that high sealing performance can be secured between the pipe joint body and the sensor case. Therefore, by adopting a configuration in which a resin sensor case with a built-in fluid sensor is fitted into a cylindrical seal member inserted and installed in the socket of the fitting body, the sensor installation cost is reduced and the sensor maintenance is reduced. This makes it possible to achieve easiness of maintenance such as inspection, replacement, and the protection function of the sensor, and at the same time, it is possible to avoid adverse effects on the surroundings due to leakage of fluid and occurrence of measurement errors.

According to the second aspect of the present invention, by pressing the push ring screwed into the end of the pipe joint main body, the primary seal part and the secondary seal part of the pipe joint main body and the resin sensor are formed. A strong sealing force is applied to the inner end seal portion and the outer end side seal portion of the cylindrical seal member to which the case is fitted, and the cylindrical seal member is axially moved by the pressing ring and the primary seal portion of the pipe joint body. High clamping performance by suppressing creep and stress relaxation of the cylindrical sealing member, even if the fluid flowing through the pipe fitting body is a high-temperature fluid or a fluid with severe temperature fluctuations. Can be secured. Therefore, by adopting a configuration in which the fluid sensor is built into the sensor case attached to the fitting body, the sensor installation cost is reduced, and maintenance of the sensor such as maintenance, inspection and replacement is easy, and the sensor protection function is achieved. Even with highly corrosive fluids such as chemicals, high-temperature fluids, and fluids with high temperature fluctuations, it is possible to reliably prevent fluid leakage and avoid adverse effects on the surroundings and measurement errors. It has the effect of being able to.

According to the third and fourth aspects of the present invention, in addition to the effects of the second aspect of the present invention, the function of preventing fluid leakage (seal performance) is further enhanced, and particularly pressure measurement is performed. Accuracy can be improved.

Further, according to the invention described in claim 5,
In the case of a highly corrosive fluid such as a chemical solution, corrosion of the sensor case and contamination of the chemical solution can be reliably prevented.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional view showing a first embodiment of a pressure sensor mounting structure which is an example of a fluid measurement sensor according to the present invention.

FIG. 2 is an enlarged vertical sectional view showing a structure of a fluid pipe connecting portion in FIG.

FIG. 3 is an enlarged vertical sectional view showing a structure of a pressure sensor mounting portion in FIG.

FIG. 4 is a longitudinal sectional view showing a second embodiment of a pressure sensor mounting structure as an example of a fluid measurement sensor according to the present invention.

FIG. 5 is a longitudinal sectional view showing a third embodiment of a pressure sensor mounting structure which is an example of a fluid measurement sensor according to the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Pipe joint 2 Fluid pipe 4 Cylindrical socket 5 Pipe joint main body 7 Cylindrical seal member 11, 11 'Primary seal part 11a Inner seal part 11b Outer seal part 13 Secondary seal part 13' Seal part 24 Inner end seal part 25 Outer end seal part 27 Pressure sensor (Sensor for fluid measurement) 28 Resin sensor case

──────────────────────────────────────────────────続 き Continued on the front page (58) Fields surveyed (Int.Cl. ⁶ , DB name) G01D 11/30 G01L 19/00 G12B 9/08

Claims (5)

(57) [Claims] 1. A pipe joint body having a cylindrical receiving end at an end thereof, and a seal formed at least at an inlet of the receiving opening so as to intersect an axis of the receiving end. A tubular seal member that can be inserted into the tubular receptacle of the joint body and has a seal portion that comes into contact with the seal portion in the inserted state, and a built-in fluid measurement sensor that fits inside the tubular seal member A possible resin-made sensor case, screwed into the end of the joint body, and pushing the cylindrical seal member from the outside of the sensor case by screwing to allow the cylindrical seal member-side seal portion to A mounting structure for a sensor for measuring fluid, comprising a sealing ring on the mouth side and a pressing ring for applying a sealing force. 2. An end portion having a cylindrical receiving port, a primary seal portion is formed in a deep portion of the receiving port, and a secondary crossing with respect to an axis of the receiving port at an inlet portion. A pipe joint body in which a seal portion is formed, and an inner end seal portion and a secondary seal portion that can be inserted into the tubular socket of the pipe joint body and abut on the primary seal portion in the inserted state. A cylindrical seal member having an outer end side seal portion in contact therewith; a resin sensor case having a built-in fluid measurement sensor and capable of being fitted into the cylindrical seal member; and being screwed to an end of the joint body. The cylindrical seal member is pressed from the outside of the sensor case by screwing to seal the inner seal portion and the outer end seal portion of the cylindrical seal member with the primary seal portion and the secondary seal portion of the receiving port. And a press wheel for applying force. Mounting structure for body measurement sensor. 3. A primary seal portion at an inner portion of the cylindrical receiving port and an inner end sealing portion of the cylindrical sealing member are formed in a cross shape opposite to the secondary sealing portion with respect to an axis of the receiving port. The mounting structure of the fluid measurement sensor according to claim 2, wherein the mounting structure is formed. 4. A primary seal portion at an inner portion of the cylindrical socket and an inner end seal portion of the cylindrical seal member are formed along an inner seal portion intersecting an axis of the socket and an axis of the socket. 3. The mounting structure for a fluid measurement sensor according to claim 2, wherein the mounting structure is formed in a two-stage seal portion with an outer seal portion that fits deeply. 5. The mounting structure for a fluid measurement sensor according to claim 1, wherein the sensor case is formed of a fluororesin.