JPH0712696A - Moisture meter - Google Patents

Abstract

PURPOSE:To provide a moisture meter which requires no special skill and simplifies operation. CONSTITUTION:A moisture meter comprises a gas introduction division 10 which generates a carrier gas A, a heating division 12 which introduces the carrier gas A from this gas introduction division 10 to heat a measurement target X, a moisture collection division 14, and an electronic balance unit 16 which detects an increment weight of the moisture collection division 14. The fore stage of the moisture collection division 14 is provided with a filter 18 which adsorbs off vaporization products other than vaporization moisture in carrier gas B.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a moisture meter, and more particularly to heating an object to be measured to vaporize the moisture in the object to be measured and collecting and measuring the vaporized moisture to measure the object to be measured. The present invention relates to a moisture meter for measuring the amount of moisture contained therein.

[0002]

2. Description of the Related Art The KF method (Karl Fisher method) is known as a means for measuring the amount of water in a solidified or liquid. This KF method is widely used as a highly accurate water quantification method and has become a standard method in each field.
The KF method uses a Karl Fischer reagent (KF reagent) containing iodine, sulfur dioxide, pyridine and methanol as components.
It is a method that utilizes quantitative reaction with water. In this way, the titer of reagent (H ₂ 0 / ml) leave orientation with standard, by measuring the equilibrium dropping amount of KF reagent was added dropwise to the reagent in the measurement object, and orientation titer , It is possible to know the water content in the measured object.

However, such a water content measuring method has the following technical problems.

[0004]

That is, the above-mentioned K
In the measurement of the amount of water by the F method, the object to be measured and the reagent may react with each other to generate water or take away water, so that various corrections are required depending on the object to be measured, and accurate water content is required. It required considerable skill to determine the quantity. In addition, there is a problem that a special reagent or a glass container is required for the measurement.

The present invention has been made in view of such conventional problems, and an object thereof is to provide a moisture meter which does not require special skill and is easy to operate. is there.

[0006]

In order to achieve the above object, the present invention provides a gas introducing section for generating a carrier gas,
A heating unit for introducing a carrier gas from the gas introducing unit to heat an object to be measured, a moisture collecting unit for collecting vaporized moisture from the carrier gas derived from the heating unit, and an increased weight of the moisture collecting unit. An electronic balance unit for detecting, which is characterized in that a filter for adsorbing and removing vaporized substances other than the vaporized moisture is provided in the preceding stage of the moisture collection unit.

The gas introduction part is a mixture of an inert gas such as N ₂ or He and air or a desiccator unit for drying a single gas to generate the carrier gas, and the desiccator unit sends the desiccator unit to the heating part. A flow sensor for detecting the flow rate of the carrier gas, and the heating unit includes a tubular heating tube, and the heating tube has a heating zone and a non-heating zone that divide the longitudinal axis direction into two. The heating zone may be provided with an inlet for the carrier gas communicating with the flow sensor, and the non-heating zone may be provided with an outlet for the carrier gas communicating with the filter.

The filter comprises a hollow cylindrical holder, an adsorbent filled in the holder for adsorbing and retaining vaporized substances other than vaporized water, and a heater for heating wound around the outer periphery of the holder. can do.

[0009]

According to the moisture meter having the above-mentioned structure, the moisture gas other than the vaporized moisture is collected before the moisture collecting section for collecting the vaporized moisture in the carrier gas carrying the vaporized moisture vaporized from the object to be measured by being heated. Since the filter for adsorbing and removing the vaporized substance is provided, the increased weight of the moisture collecting portion is only the moisture vaporized from the measured object.

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT A preferred embodiment of the present invention will be described in detail below with reference to the accompanying drawings. 1 to 12 show an embodiment of a moisture meter according to the present invention. FIG. 1 is a path and a functional block diagram of a fluid system of the moisture meter of the present embodiment. The moisture meter shown in FIG. 1 is a gas introducing section 10 for generating a carrier gas and a carrier gas from the gas introducing section 10. The heating part 12 for introducing A to heat the object to be measured X, the water collecting part 14 for collecting vaporized water from the carrier gas B derived from the heating part 12, and the increased weight of the water collecting part 14 A known electromagnetic balance type balance unit 16 for detecting is provided.

A filter 18 for adsorbing and removing vaporized substances other than vaporized moisture in the carrier gas B is provided in front of the moisture collector 14. The gas introduction unit 10 includes an air pump 10a, air supplied from the air pump 10a, and dry nitrogen N ₂ (He) supplied from the outside.
And a desiccator unit 10c for drying the mixed or single gas C sent from the electromagnetic valve 10b to generate the carrier gas A, and a heating unit. Needle valve 10 for controlling the flow rate of the carrier gas A supplied to 12
d and a flow sensor 10e that detects the flow rate of the carrier gas A supplied to the heating unit 12.

FIG. 2 is an overall perspective view of the moisture meter of this embodiment, in which the desiccator unit 10c of the gas introducing section 10 is arranged on the front side of the apparatus body 20 and the inside of the apparatus body 20 is heated. The unit 12, the water collecting unit 14, the electronic balance unit 16, and the filter 18 are arranged. In addition, the member shown by the reference numeral 22 in FIG. 2 is an operation key switch of the moisture meter, and the same 24 is an indicator for displaying a measurement result and the like.

FIG. 3 is a detailed perspective view of the heating section 12,
The heating unit 12 has a cylindrical heating tube 12a having one end opened, and the heating tube 12a includes a plurality of support plates 12b.
It is supported by. Further, the heating tube 12a is provided with a heating zone a and a non-heating zone b such that the longitudinal axis direction thereof is divided into two substantially equal parts, and a portion corresponding to the heating zone a has its outer periphery covered. Thus, the planar heater 12c is wound and fixed.

Further, a square door receiving plate 12d is fixedly provided at the open end of the heating tube 12a, and a door 12e for sealing the open end of the heating tube 12a is screwed to the lower end of the door receiving plate 12d. There is. The heating pipe 12a is provided on the inner surface of the door 12e.
A heat-resistant cushion material 12f that abuts the open end of the sheet and a heat-resistant, non-breathable cover 12g that covers the surface of the cushion material 12f are attached.

At the rear end side of the heating zone a of the heating tube 12a, there is provided an inlet 12h (see FIG. 5) for the carrier gas A which communicates with the flow sensor 10e of the gas inlet 10 and the heating tube 12a. A through hole 12i penetrating the heating tube 12a is formed at substantially the center of the non-heating zone, and a filter 18 is fixedly installed in the through hole 12i. Are guided into the filter 18. In addition, filter 18
The heating tube 12a does not necessarily have to be provided in the non-heating zone b, and may be provided in the heating zone a.

The object to be measured X is housed in the carrier 26, first introduced into the non-heating zone b of the heating tube 12a with the door 12e opened, and closed by the door 12e, and then transferred to the heating zone a. Then, the heater 12c applies heat thereto. Details of the carrier 26 are shown in FIG.
The carrier 26 shown in the figure has a frame 26a formed in a substantially rectangular shape, a pair of front and rear rollers 26b and 26c rotatably supported on the short side of the frame 26a, and an outer peripheral portion of which is locked to the frame 26a. And a heat-resistant container 26d for placing and storing the object to be measured X.

The frame 26a and the rear roller 26c of the carrier 26 are made of stainless steel which is a non-magnetic material, and the front roller 26b is made of a magnetic material. 5 to 7 show the moving mechanism 2 of the carrier 26 configured as described above.
8 is shown. The moving mechanism 28 shown in FIG.
Suction arm 2 installed around the non-heating zone b of 2a
8a, a guide rail 28b below the heating tube 12a and extending along the longitudinal axis thereof, and a guide rail 2
Flexible rack 2 movably mounted on the lower surface side of 8b
8c and a pinion 28d that meshes with this rack 28c
And a geared motor 28 that rotationally drives the pinion 28d
e and.

The suction arm 28a includes a mounting plate 28f formed in a substantially Y shape, and a magnet piece 28g fixed to the inner surface of the mounting plate 28f on the front end side.
A guide rail 28b and a rack 28c are inserted on the inner surface side of the base portion of, and the base portion of the mounting plate 28f is fixedly mounted on the rack 28c. The guide rail 28b is supported by a plurality of fixtures 28h on the lower case 40 of the upper and lower cases 38, 40 covering the outer circumference of the heating unit 12.

Further, on the upper surface side of the guide rail 28b,
A pair of limit switches 28i for detecting the position of the suction arm 28a corresponding to the movement stroke of the carrier 26.
Is installed. In addition, in FIG. 5, the member indicated by reference numeral 42 is the heater 1 wound around the outer circumference of the heating tube 12a.
It is a protective cylinder that covers the outer periphery of 2c. In the moving mechanism 28 configured as described above, the DUT X is first housed in the carrier 26, and the door 12e is opened.
After being introduced into the non-heating zone b of No. 1 and closed with the door 12e,
When the geared motor 28e is driven, the rack 28c meshed with the pinion 28d moves to the heating zone a side of the heating pipe 12a.

Along with this movement, the suction arm 28a also moves to the heating zone a side of the heating tube 12a. At this time, since the magnet piece 28g attracts the front roller 26b of the carrier 26, the suction arm 28a moves. Accordingly, the carrier 26 also moves to the heating zone a side of the heating pipe 12a.
Then, when the carrier 26 is completely moved into the heating zone a, this is detected by the limit switch 28i, and the rotational drive of the geared motor 28e is stopped.

When the heating of the object to be measured X is completed, the reverse operation is performed and the door 12e is opened to take out the burned residue of the object to be measured X from the inside of the heating pipe 12a. You can FIG. 8 shows details of the filter 18 and its mounting structure. Filter 1 shown in the figure
Reference numeral 8 denotes a hollow-cylindrical holder 18a having an open upper end, a hollow-cylindrical insertion portion 18b projecting from the center of the lower end of the holder 18a, and a container portion 1 housed in the holder 18a.
8c and the adsorbent 18 filled in the container portion 18c
d, a cap 18e screwed to the upper end of the holder 18a
And have.

At the center of the lower end of the container portion 18c, the insertion portion 18
A through hole 18f communicating with b is bored, and a mesh 18g is placed on the inner bottom surface of the container portion 18c. Also,
A packing 18h is interposed between the outer bottom surface of the container portion 18c and the inner bottom surface of the holder 18a, and a packing 18i is provided between the upper end surface of the container portion 18c and the inner surface side of the cap 18d. It is inserted and the cap 18e
When is screwed onto the holder 18a, the upper and lower ends of the container portion 18c are sealed.

A temperature sensor 18j is arranged on the outer periphery of the holder 18a, and the temperature sensor 18j
A sheet-shaped heater 18k is wound so as to cover the outer periphery of j, and a heat insulating material 18l is provided on the outer periphery of the heater 18k. The filter 18 configured in this manner has the insertion portion 18b formed in the upper portion of the heating tube 12a and the through hole 12 formed therein.
It is attached by inserting it into i and fixing it by welding or the like.

Then, by connecting the connector 30 to the protrusion 18m provided on the cap 18e, the filter 18 and the water collecting unit 14 are connected to each other through the tube 32. In addition, the part shown by the code | symbol 18n in FIG. 8 is a ventilation hole provided in the protrusion part 18m. In the filter 18 configured as above, the adsorbent 18d
Is appropriately selected depending on vaporized substances other than vaporized water generated when the object X is heated, for example, basic gases such as ammonia and trimethylamine, various organic substances and inorganic substances, and, for example, substances having different pore sizes are mixed. Activated carbon that is made to react with or impregnated with an acidic substance is preferably used. At this time, by energizing the heater 18k, the adsorbent 18d can be heated and the passing speed of vaporized moisture can be increased.

9 to 12 show the details of the water collecting section 14. The water collecting unit 14 shown in the figure has a cell stand 14a to which one end of the tube 32 is connected, and an adsorbent 14b for adsorbing vaporized water, for example, a cell 14c filled with zeolite. A connector portion 14d for mounting the tube 32 is fixedly attached to the side surface of the cell base 14a, and a hole portion 14e having a closed lower end is provided inside thereof.

A cylindrical projection 14f projecting downward is integrally formed on the lower end surface of the cell stand 14a. The cylindrical projection 14f is provided on the balance cover 34 covering the outer circumference of the balance unit 16. With the both ends thereof being inserted into the guide cylinder 36 having an open end, the lower end thereof is brought into contact with the upper end of the load transmission shaft 16a of the electronic balance unit 16 of the electromagnetic balance type, and the load of the moisture collecting unit 14 is applied to the electronic balance unit. 16 is transmitted.

The cell 14c has a substantially hollow cylindrical shape with open upper and lower ends, and is provided in the hole 14e of the cell base 14a.
A small-diameter insertion portion 14h, which is inserted with packings 14g installed in multiple stages interposed, is integrally formed at the lower end. A mesh 14i for preventing the adsorbent 14b from falling off is inserted inside the cell 14c, and the packing 14
The cap 14k holding j is attached.

On the upper end side of the cap 14k, a plurality of discharge ports 14l are provided which are oriented horizontally and are symmetrically arranged with respect to the center of the cell 14c. On the other hand, in the vicinity of the guide tube 36 of the balance cover 34, the guide pole 4
4 is erected, and a protective cap 46 installed on the outer circumference of the cell 14c is attached to the guide pole 44.

The protective cap 46 of this embodiment has a cylindrical cap body 46a whose upper end is closed and whose lower end is open.
A rotary plate 46b for supporting the lower end side of the cap body 46a, an electric heating cylinder portion 46c provided on the inner circumference of the cap body 46a and having an open lower end, and a sheet arranged on the outer peripheral surface of the electric heating cylinder portion 46c. Heater 46d.

At the center of the rotary plate 46b, the water collecting section 14 is provided.
A through hole 46e through which the guide pole 44 is inserted is formed, and a guide cylinder portion 46f inserted into the guide pole 44 is attached to one end edge side thereof. In the protective cap 46 thus configured, the guide pole 44 is inserted into the guide tube portion 46f, and the moisture collecting unit 1 is provided in the through hole 46e.
4 is installed on the outer circumference of the collecting unit 14.

By energizing the heater 46d to heat the adsorbent 14b of the water collecting section 14, the H ₂ O selectivity of the adsorbent 14b can be improved. Further, in this case, since the cap 14k is provided with a plurality of symmetrically arranged discharge ports 14l on the upper end side in the horizontal direction, the carrier gas discharged from the discharge ports 14l is Since it uniformly collides with the inner peripheral surface of the electric heating cylinder portion 46c, the reaction force at the time of discharging the carrier gas acts uniformly on the cell 14c, and this reaction force prevents the measured value of the balance unit 16 from fluctuating. To be done.

Next, the object X to be measured is measured by the moisture meter having the above-mentioned structure.
The operation for measuring the water content of the will be described. In the measurement of the water content of the object to be measured X, first, the heating tube 1 of the heating unit 12 is
The object to be measured X is positioned in the heating zone a of 2a via the moving mechanism 28. Then, in this state, the carrier gas A is introduced into the inside of the heating tube 12a through the inlet 12h, and the heater 12c of the heating unit 12 is energized and heated.

Moisture vaporized and separated from the object to be measured X by heating and vaporized substances other than water are carried in the carrier gas A and led out as the carrier gas B from the through hole 12i. The carrier gas B thus derived is introduced into the filter 18, and vaporized substances other than vaporized water carried in the carrier gas B are adsorbent 18d filled in the container portion 18c of the filter 18. Adsorbed on
It is removed from the carrier gas B.

At this time, in order to increase the passage rate of H ₂ O through the adsorbent 18d, the heater 18k is appropriately energized,
The adsorbent 18d is heated to a predetermined temperature. Then, the carrier gas B from which vaporized substances other than vaporized moisture have been removed is next introduced into the moisture collection unit 14, and the vaporized moisture is adsorbed and held by the adsorbent 14b filled in the cells 14c. The amount of water of the object to be measured X is obtained by detecting the weight increased by the agent 14b adsorbing and holding the vaporized water, by the electronic balance unit 16.

The moisture meter constructed as described above does not require special skill, is simple in operation, and is a liquid B that carries the vaporized moisture vaporized from the object X to be measured by being heated. Moisture collecting section 14 for adsorbing vaporized water inside
Since the filter 18 that adsorbs and removes vaporized substances other than vaporized moisture is provided in the preceding stage, the increased weight of the moisture collection unit 14 is only the moisture vaporized from the object X to be measured, and the measurement accuracy of the moisture meter is improved. .

[0036]

As described above in detail in the embodiments,
According to the moisture meter of the present invention, it is possible to measure only vaporized moisture separated from the object to be measured by heating, without requiring special skill, and in addition to being easy to operate,
Measurement accuracy is improved.

[Brief description of drawings]

FIG. 1 is a functional block diagram of a moisture meter according to the present invention.

FIG. 2 is an external perspective view of a moisture meter according to the present invention.

FIG. 3 is a perspective view of a heating unit of the moisture meter according to the present invention.

FIG. 4 is a perspective view of a carrier of a moisture meter according to the present invention.

FIG. 5 is a cross-sectional view of a moving mechanism of the moisture meter according to the present invention.

FIG. 6 is an explanatory diagram of a moving mechanism shown in FIG.

7 is a cross-sectional explanatory view of the moving mechanism shown in FIG.

FIG. 8 is a sectional view of a filter of a moisture meter according to the present invention.

FIG. 9 is an exploded perspective view of a moisture collecting unit of the moisture meter according to the present invention.

FIG. 10 is a cross-sectional view of a moisture collecting unit of the moisture meter according to the present invention.

FIG. 11 is an external perspective view of a moisture collecting unit of the moisture meter according to the present invention.

12 is a cross-sectional view of FIG.

[Explanation of symbols]

 10 Gas Introducing Section 10c Desiccator Unit 10e Flow Sensor 12 Heating Section 12a Heating Tube 12c Heater 12h Inlet Port 14 Moisture Collecting Section 14a Cell Platform 14b Adsorbent 14c Cell 16 Electronic Balance Unit 18 Filter 18a Holder 18d Adsorbent 18j Temperature Sensor 18k Heater A Carrier gas B Carrier gas C Mixed gas X DUT

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Takaaki Kagawa 1-243 Asahi, Kitamoto City, Saitama Stock & Stock Company A & D Development & Technology Center

Claims (3)

[Claims] 1. A gas introducing section for generating a carrier gas,
A heating unit for introducing a carrier gas from the gas introducing unit to heat an object to be measured, a moisture collecting unit for collecting vaporized moisture from the carrier gas derived from the heating unit, and an increased weight of the moisture collecting unit. A moisture meter comprising an electronic balance unit for detecting, wherein a filter for adsorbing and removing vaporized substances other than the vaporized moisture is provided before the moisture collection unit. 2. The desiccator unit for generating the carrier gas by drying a mixture of an inert gas such as N ₂ or He and air or a single gas, and the desiccator unit to the heating unit. A flow sensor for detecting a flow rate of the carrier gas to be delivered, the heating unit includes a tubular heating tube, and the heating tube includes a heating zone and a non-heating zone which divide the longitudinal axis direction into two. And an inlet for the carrier gas that communicates with the flow sensor is provided in the heating zone, and an outlet for the carrier gas that communicates with the filter is provided in the non-heating zone. The moisture meter according to claim 1. 3. The filter comprises a hollow cylindrical holder, an adsorbent filled in the holder for adsorbing and holding vaporized substances other than vaporized water, and a heater for heating wound around the outer periphery of the holder. The moisture meter according to claim 2, further comprising: