JPH0565741B2 - - Google Patents

Description

[Detailed Description of the Invention] [Field of Industrial Application] The present invention relates to a mounting device for a flow-type meter used for monitoring processes on process pipes, tanks, etc. of various plants, and particularly relates to This invention relates to improvements to instrument chambers used to connect shaped instruments to process piping, tanks, etc.

[Background Art] In power plants, chemical plants, etc., water quality and other factors of various fluids handled are analyzed in order to monitor processes. However, such analytical instruments include conductivity meters, dissolved oxygen meters, PH meters, dew point meters, etc., and these instruments usually have their detection ends inserted directly into process piping or tanks. However, in many cases, piping with a smaller diameter than the above piping or tank is branched off for sample analysis.
In such a case, it becomes difficult to directly insert the detection end of the meter into the small-diameter pipe. Therefore, a flow-through type instrument chamber (hereinafter simply referred to as an instrument chamber) has been developed as a means of making the instrument detection end fit well with small-diameter piping and bringing the fluid into contact with the detection end in an optimal state. ) is used.

FIG. 7 shows a conventional instrument chamber of this type. The instrument chamber consists of a tube body 12 that is closed at one end and open at the other end forming a chamber 10 for fluid communication. A fluid inlet 1 is provided at the closed end of the tube body 12 to connect to a sample pipe (not shown).
4, the open end is provided with a coupling flange 16 for coupling a meter (not shown), and a fluid outlet 18 is provided adjacent thereto. According to such a configuration, the inner diameter of the tube body 12 and therefore the chamber 10 is adapted to the size of the instrument, regardless of the diameter of the sample pipe, that is, the fluid inlet 14, and the inner diameter of the tube body 12 and therefore the chamber 10 is adapted to the size of the instrument, and the sample fluid to the detection end of the instrument is contact can be set optimally.

However, in such an instrument chamber, usually four to six bolts and nuts must be operated when attaching or detaching the instrument from the flange 16, which has the disadvantage of lengthening the working time and complicating the workability. It was hot. Furthermore, the bolt
There was a problem that if the nut was tightened unevenly, the sealing performance would be impaired. This has been a major safety problem, especially when handling fluids that are harmful to the human body. Note that for example, taper screws can be used instead of flanges to connect the instruments, but in this case, the screw tightening work using a spanner etc. is still the same, and in this case, the sealing material for the threaded part is not changed. It also involves additional complexity such as the use of

In order to solve these problems, the present applicant developed a divisible instrument chamber as shown in Figs. No. 14905). That is, according to the instrument chamber, the tube body 20 connects the main pipe section 22 provided with the fluid inlet 14, the detection tube insertion section 24 provided with the fluid outlet 18, and the instrument (not shown). The main pipe part 22 and the insertion part 24 are joined by welding or the like, but both the insertion parts 24 and 28 have a tapered flange part 26. 30 and 32 are crimped and clamped by a clamp band 34 via a butterfly nut 36, so that they can be detachably connected.

Therefore, in the instrument chamber described above, the instrument can be installed in advance in the detection end insertion part in a liquid-tight manner, and the insertion part can be easily and quickly connected to the main pipe part via the clamp band. Ru.
That is, it becomes possible to eliminate the long hours of work and complicated labor that were the drawbacks of the conventional method.

[Problem to be solved by the invention]

However, the above-mentioned instrument chamber still has the following drawbacks.

That is, in FIG. 8, both insertion portions 30, 3
The space between the two joint surfaces is sealed by an O-ring 38, but in this structure, a force is applied to both the joint surfaces to separate them in the axial direction due to internal pressure, so the internal pressure increases. Accordingly, the sealing performance between both bonding surfaces deteriorates. In this case, the sealing performance is achieved by the crimp force of the crank band 34, but the crank band is attached to the butterfly nut 3.
6 (see FIG. 9), it was difficult to achieve sufficient crimp clamping force. For this reason, it has been found that various recent high-pressure plants have major drawbacks in terms of safety and maintenance workability, especially when dealing with nuclear power-related or other harmful fluids.

SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide a flow-through type instrument chamber which allows instruments to be easily and easily attached to and removed from the instrument chamber, has excellent sealing performance, and has a relatively simple structure. be.

[Means to solve the problem]

In order to achieve the above object, the flow type instrument chamber according to the present invention includes a tube body with one end open forming a chamber through which sample fluid flows, and an insertion portion at the open end of the tube body. It consists of a cylindrical cover body that is inserted to close the chamber and hold an instrument in the chamber, and the tube body and the cover body are removably connected to each other via a detachable coupling means, and the tube body In the annular space formed at the insertion part of the cover body, there is a sealing rib that engages with the joint surface of the tube body and the cover body, and a tapered shape of the tube body and the cover body that is continuous with the joint surface. A seal ring having a sealing lip that engages with the inner circumferential surface is provided, and a taper angle θ ₁ of the tapered inner circumferential surfaces of the tube body and the cover body is set to be larger than a taper angle θ ₂ of the sealing lip to form a chamber. The sealing surface pressure of the seal ring is increased by the hydraulic pressure inside the seal ring.

[Effect]

The instrument chamber is composed of a tube body that forms the chamber and a cover body that closes the chamber and holds the instrument within the chamber, and the tube body and the cover body are connected to each other through a detachable coupling means. It is removably connected to the ring and has a self-tightening sealing means within the annular gap.

In this case, the self-tightening sealing means includes a sealing rib that engages the joint surfaces of the tube body and the cover body, and a sealing rib that engages the tapered inner circumferential surfaces of the tube body and the cover body that are continuous with the joint surfaces. By constructing the seal ring with a sealing lip that provides a sealing lip, the sealing performance between the tube body and the cover body can be most reliably achieved regardless of an increase in the chamber internal pressure.

〔Example〕

Next, embodiments of a chamber for a flow-through type instrument according to the present invention will be described in detail below with reference to the accompanying drawings.

In FIG. 1, the instrument chamber includes a tube body 42 with one end open forming a chamber 40 through which sample fluid flows, and a tube body 42 that is inserted into the open end insertion portion of the tube body 42 to close off the chamber 40. It consists of a cylindrical cover body 44 that holds a meter (not shown) within the chamber 40. The tube body 42 is provided with a fluid inlet 46 connected to a sample pipe (not shown) at its closed end, and a fluid outlet 48 near its open end.
The sample fluid is set to optimally contact the detection end of the instrument disposed within the chamber 40. Further, the cover main body 44 is provided with a tapered threaded portion 62 for mounting a meter (meter with a tapered thread) in a liquid-tight manner.

An O-ring 52 is installed in an annular gap 50 formed at the insertion portion of the cover body 44 into the tube body 42, and a back-up spring 5 is installed behind it.
Place 4. In addition, in the figure, reference numeral 56 indicates an O-ring fall prevention plate. In such a configuration, when internal pressure is applied within the chamber 40, the tube main body 42 and the cover main body 44 receive an axial force acting in a direction to separate them from each other due to the internal pressure, but at this time, O
The sealing surface pressure of the ring 52 is increased under the action of a back-up spring 54. Therefore, the sealing performance between the tube body 42 and the cover body 44 is maintained even if the two are slightly separated by the force acting in the axial direction. This is ensured by the effective sealing properties.

The tube body 42 and the cover body 44 each have tapered flange portions 58, 60 that protrude outward at their joint outer peripheral edges, and the flange portions 58, 6
0 through clamp means 64.
As shown in FIG. 2, the clamping means 64 consists of two semicircular ring-shaped clamp pieces 66, 66, each of which tightens two sets of bolts 70 and nuts 72 at both end fastening parts 68, 68; . The clamping means 64 is designed such that the contact surfaces of the nut 72 and the fastening portion 68 are both spherically processed, so that only a tensile force is applied to the bolt thread portion when the two connecting surfaces are fastened. Configure. Therefore, by attaching the instrument to the cover body 44 in advance, the instrument can be attached to and removed from the instrument chamber easily and in a short time.

According to the flow-through type instrument chamber configured in this way, the instrument can be attached and detached from the instrument chamber easily and in a short time, and at the same time, the sealing performance of the instrument chamber can be maintained regardless of the pressure of the sample fluid. , can be guaranteed with certainty. In addition, the fluid pressure can be sufficiently applied to high pressures up to 10,000 Kg/cm ² . Furthermore, this instrument chamber has the advantage of being relatively simple in structure, making it inexpensive to manufacture and easy to maintain.

FIG. 3 shows a modification of the flow-through type instrument chamber shown in FIG. That is, in Figure 3,
In the configuration shown in FIG. 1, the coupling means is made up of pin means instead of the clamp means. Therefore, the tube main body 74 has a stepped fastening surface portion 76 that is continuous with the annular gap 50, and the cover main body 78 has a fastening surface portion 8 corresponding to the fastening surface portion 76.
0, and as shown in FIG. 86, 86 are configured to be inserted therethrough. Note that in this configuration,
The meter 88 is screwed onto the cover body 78 via a gland nut 90.

The tightening force by the gland nut 90 is measured by the meter 88.
acts as a pushing force, and the structure is such that the necessary surface pressure is applied to the tapered seal portion 91 constituted by the tapered seat portion of the meter 88 and the seat portion of the cover body.

It is clear that such a configuration also provides the same effects as the configuration shown in FIG. .
It also has the advantage that the structure is simpler. Furthermore, the operation becomes simpler and easier to automate.

FIGS. 5 and 6 show a typical embodiment of a flow-through type instrument chamber according to the present invention. In this embodiment, in the configuration shown in FIG. 1, the self-tightening sealing means is constructed from a seal ring instead of the O-ring and the back-up spring. That is, a seal ring 94 is disposed within the annular space 92, and this seal ring 94 is
As shown enlarged in FIG. 6, the coupling surfaces 96a and 98 of the tube body 96 and the cover body 98
a sealing rib 94a that engages with a, and a tapered inner circumferential surface 96 of each of the tube body 96 and cover body 98 that are continuous with the coupling surfaces 96a and 98a.
a sealing lip 94b that engages b, 98b;
94b', and its surface is coated with MoS ₂ , graphite, gold, silver, etc. Note that this seal ring 94 has tapered surfaces of inverted T-shaped sealing lips 94b, 94b, an inner circumferential surface 96b,
The sealing surface pressure between the tapered surface of 98b is increased by the internal pressure, thereby exhibiting self-tightening sealing performance. The taper angle θ ₁ of the inner peripheral surfaces 96b and 98b is
With respect to the ring taper angle θ ₂ , the relationship θ ₁ >θ ₂ always holds true, allowing the ring's metal elastic region to effectively act on the seal. The angle difference is usually less than 5°, optimally between 0.5 and 2°.

According to the flow-through type instrument chamber of the present invention according to this embodiment, it goes without saying that the same effects as those of the configuration shown in FIG. 1 can be exhibited. Since it is composed of a specially processed metal gasket, it has the advantage of being able to be used safely and durablely, especially for fluids at high temperatures, such as over 250℃, or corrosive fluids. .

Although the present invention has been described above with reference to preferred embodiments, the present invention is not limited to the above-mentioned embodiments.
Of course, various design changes can be made without departing from the spirit thereof.

〔Effect of the invention〕

As explained above, the flow type instrument chamber according to the present invention includes a tube body with one end open, forming a chamber through which sample fluid flows, and a tube body with the open end of the tube body closed. and a cover body that holds the instrument in the chamber at the same time, coupling means that can freely connect and detach the tube body and the cover body, and a sealing rib that engages with the coupling surfaces of the tube body and the cover body, respectively. By being configured to be fastened via a self-tightening sealing means constituted by a seal ring having a sealing lip that engages with the tapered inner circumferential surface of each of the tube body and the cover body that are continuous with the coupling surface, The instrument can be attached and detached from the instrument chamber easily and quickly by attaching the instrument to the cover body in advance, and furthermore,
The sealing performance of the instrument chamber can be reliably guaranteed even for high-pressure handling fluids. Therefore, the instrument chamber of the present invention can be safely used, especially in various high-pressure plants related to nuclear power or handling hazardous fluids. Furthermore, if the sealing means is made of a metal gasket, it will also be able to withstand high temperature and corrosive fluids.
Can be used safely.

Further, since the instrument chamber of the present invention has a relatively simple structure, it has the advantage that it can be manufactured at low cost and is easy to maintain.

[Brief explanation of the drawing]

FIG. 1 is a partially sectional side view showing an example of the structure of the improved flow-through type chamber, FIG. 2 is a front view showing the clamping means of the flow-through type chamber shown in FIG. 1, and FIG. FIG. 4 is a side sectional view showing a modification of the flow-through type instrument chamber shown in FIG. 1, FIG. 4 is a perspective view of the flow-through type instrument chamber shown in FIG. 3, and FIG. FIG. 6 is an enlarged view showing the state of the flow-through type instrument chamber shown in FIG. 5 before the seal ring is attached, and FIG. 7 is a partial cross-sectional side view showing a typical embodiment of the flow-through type chamber. FIG. 8 is a partially sectional side view showing another conventional flow-through type instrument chamber; FIG. 9 is a partial cross-sectional side view showing a flow-through type instrument chamber shown in FIG. 8; FIG. 40...Chamber, 42...Pipe body, 44...
Cover body, 46...Fluid inlet, 48...Fluid outlet, 50...Annular gap, 52...O ring,
54... Backup spring, 56... Fall prevention plate, 58, 60... Tapered flange portion, 62...
...Tapered thread portion, 64... Clamping means, 66...
... Clamp piece, 68 ... Fastening section, 70 ... Bolt, 72 ... Nut, 74 ... Pipe body, 76 ...
Fastening surface portion, 78... Cover body, 80... Fastening surface portion, 82... Pin hole, 84... Pin means, 86...
...Pin, 88...Meter, 90...Gland nut, 92...Annular space, 94...Seal ring,
94a...Sealing rib, 94b...Sealing lip, 96...Pipe body, 96a...Joining surface,
96b...Tapered inner circumferential surface, 98...Cover body, 98a...Joining surface, 98b...Tapered inner circumferential surface.

Claims (1)

[Scope of Claims] 1. A tube body with one end open forming a chamber through which a sample fluid flows, and a tube body inserted into an insertion portion at the open end of the tube body to close the chamber and place an instrument within the chamber. The tube body and the cover body are removably connected to each other through a removable coupling means, and an annular gap is formed at the insertion portion of the cover body into the tube body. The interior includes a sealing rib that engages with the joint surfaces of the tube body and the cover body, and a sealing lip that engages with the tapered inner peripheral surfaces of the tube body and the cover body that are continuous with the joint surfaces. A seal ring is provided, and the taper angle θ ₁ of the tapered inner circumferential surfaces of the tube body and the cover body is set larger than the taper angle θ ₂ of the sealing lip, so that the sealing surface pressure of the seal ring is increased by the hydraulic pressure in the chamber. A chamber for a flow-through type instrument, characterized in that it is configured to do so.