JPH075050U - Heating device for moisture meter - Google Patents

Abstract

(57) [Summary] [Purpose] Improving the measurement accuracy of moisture analyzers. [Constitution] The heating device 12 has a heating tube 12a supported by a plurality of support plates 12b. The heating pipe 12a is provided with a heating zone a and a non-heating zone b, and a heater 12c is wound and fixed to a portion corresponding to the heating zone a. A door receiving plate 12d is fixed to the opening end of the heating pipe 12a, and a door 12e for opening and closing the opening end of the heating pipe 12a is screwed to the lower end of the door receiving plate 12d. Door 12e
The inner surface of the heat-resistant cushion material 12f that abuts the open end of the heating tube 12a in the closed state of the door 12e, and the heat-resistant and non-permeable cover 12g that covers the surface of the cushion material 12f. Is attached. At the rear end side of the heating zone a of the heating tube 12a, a carrier gas inlet communicating with the gas inlet is provided, and the heating tube 1
A through hole penetrating the heating tube 12a is formed at a substantially central portion of the non-heating zone b of the filter 2a.
8 is fixed.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a heating device for a moisture meter, and particularly to heating the measured object to vaporize the moisture in the measured object, and collecting and measuring the vaporized moisture to measure the amount of water in the measured object. The present invention relates to a heating device for a moisture meter for measuring.

[0002]

[Prior 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 is a method that utilizes the quantitative reaction of Karl Fischer reagent (KF reagent) containing iodine, sulfur dioxide, pyridine, and methanol with water. In this method, the titer (H ₂ 0 / ml) of the reagent is standardized with a standard substance, the reagent is dropped into the measurement object, and the equilibrium dropping amount of the titered KF reagent is measured. It is possible to know the water content in the measured object.

However, such a method for measuring the amount of water has a drawback that it requires a considerable skill in handling and requires a special reagent or a glass container. Therefore, recently, a moisture meter is proposed that measures the amount of water in a measured object by heating the measured object to vaporize the water in the measured object and collecting and measuring the vaporized water. Has been done. However, even with such a moisture meter, there are technical problems described below.

[0004]

[Problems to be solved by the device]

 That is, in the above-described moisture meter, a carrier gas is introduced into the heating section from the outside, the carrier gas is separated from the object to be measured and vaporized water is carried, and then the vaporized water content is collected and measured. In such measurement of the water content, the inside of the heating unit is usually kept in a state of being shielded from the outside in order to ensure the measurement accuracy. However, since the object to be measured must be housed in the heating unit, it is inevitable that it can be opened and closed, and in general, an opening / closing door is installed.

However, when the opening / closing door is provided as described above, the inside of the heating unit is heated and dried even if a sealing material having a cushioning property is interposed, so that outside air enters the heating unit from the outside, There was a problem that sufficient measurement accuracy could not be secured. The present invention has been made in view of such conventional problems, and an object thereof is to provide a heating device for a moisture meter capable of improving measurement accuracy.

[0006]

[Means for Solving the Problems]

 In order to achieve the above-mentioned object, the present invention introduces a carrier gas from the outside to heat an object to be measured, vaporizes the water contained in the object to be measured, and discharges the vaporized water. In a heating device for a moisture meter that collects and weighs water, it is provided with an inlet for the carrier gas and an outlet for a carrier gas carrying vaporized moisture, and one end for heating the DUT stored inside is provided. A closed heating tube, a door that opens and closes the open end of the heating tube, a heat-resistant cushion material that is provided on the inner surface of the door and that abuts the opening edge of the heating tube when the door is closed, It is characterized by having a heat-resistant and non-breathable cover that covers the surface of the cushion material.

[0007]

[Action]

 According to the heating device for a moisture meter having the above structure, a heat-resistant cushion material that abuts the opening edge of the heating tube on the inner surface of the door that opens and closes the opening end of the heating tube, and the cushion material of this cushion material. Since it has a heat-resistant and non-breathable cover that covers the surface, invasion of outside air containing vaporized water from the outside is blocked by the cover.

[0008]

【Example】

 Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. 1 to 6 show an embodiment of a heating device for a moisture meter according to the present invention. FIG. 1 is a path and function block diagram of a carrier gas system of a moisture meter to which the heating device of the present invention is applied. The moisture meter shown in the figure is a gas introduction unit 10 for generating a carrier gas A. And a heating device 12 for introducing the carrier gas A from the gas introducing part 10 to heat the object to be measured X, and a moisture collecting device for collecting vaporized water from the carrier gas B derived from the heating device 12. The unit 14 and a known electromagnetic balance type balance unit 16 for detecting the increased weight of the water collecting unit 14 are provided.

A filter 18 that adsorbs and removes vaporized substances other than vaporized moisture in the carrier gas B is provided in the preceding stage of the moisture collector 14. The gas introduction unit 10 switches between the air pump 10a, the air supplied from the air pump 10a, and the dry nitrogen N ₂ (which may be an inert gas such as He) supplied from the outside. The flow rate of the carrier gas A supplied to the electromagnetic valve 10b and the desiccator unit 10c which generates the carrier gas A by drying the mixed or single gas C sent from the electromagnetic valve 10b and the carrier gas A is controlled. It is composed of a needle valve 10d and a flow sensor 10e for detecting the flow rate of the carrier gas A supplied to the heating device 12.

2 and 3 are detailed views of the heating device 12. The heating device 12 has a cylindrical heating tube 12a whose one end is open, and the heating tube 12a has a plurality of supporting members. It is supported by the plate 12b. 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 approximately two equal parts, and the outer periphery of the heating tube 12a is covered at a portion corresponding to the heating zone a. Thus, the planar heater 12c is wound and fixed.

Further, a square door receiving plate 12d is fixed to the open end of the heating pipe 12a, and a door 12e for opening and closing the open end of the heating pipe 12a is screwed to the lower end of the door receiving plate 12d. ing. Then, on the inner surface of the door 12e, a heat-resistant cushion material 12f made of, for example, silicon rubber, which comes into contact with the open end of the heating tube 12a in a closed state of the door 12e, and a heat-resistant cushion material covering the surface of the cushion material 12f. A cover 12g, which is flexible and non-breathable and is made of, for example, Teflon resin, is attached.

At the rear end side of the heating zone a of the heating tube 12a, an inlet 12h for the carrier gas A communicating with the flow sensor 10e of the gas introducing section 10 is provided, and the non-heating zone of the heating tube 12a is provided. A through hole 12i penetrating the heating pipe 12a is formed substantially in the center thereof, and a filter 18 is fixedly installed in the through hole 12i. The carrier gas B discharged from the heating device 12 is filtered by the filter. Guided in 18.

The object to be measured X is housed in the carrier 20, and is first introduced into the non-heating zone b of the heating pipe 12a with the door 12e opened, and after being closed by the door 12e, it is placed in the heating zone a. Transferred, where heat is applied by the heater 12c. The carrier 20 includes a frame 20a formed in a substantially rectangular shape, a pair of front and rear rollers 20b and 20c rotatably supported on the short side of the frame 20a, and an outer peripheral portion of the frame 20a locked to the covered portion. It is composed of a heat-resistant container 20d for placing and storing the measured object X.

The frame 20a and the rear roller 20c of the carrier 20 are made of stainless steel which is a non-magnetic material, and the front roller 20b is made of a permanent magnet. The moving mechanism 22 of the carrier 20 configured as described above includes a suction arm 22a installed on the outer periphery of the non-heating zone b of the heating tube 12a and a lower side of the heating tube 12a along the longitudinal axis direction thereof. A guide rack 22b extending in a vertical direction, a flexible rack 22c that is movably mounted on the lower surface of the guide rail 22b, a pinion 22d that meshes with the rack 22c, and a geared motor 22e that rotationally drives the pinion 22d. I have.

The suction arm 22a includes a mounting plate 22f formed in a substantially Y shape, and a magnet piece 22g fixed to the inner surface of the mounting plate 22f on the tip side, and is guided to the inner surface side of the base of the mounting plate 22f. The rail 22b and the rack 22c are inserted, and the base of the mounting plate 22f is fixed to the rack 22c. The guide rail 22b is supported by a plurality of fixtures 22h on the lower case 24 of the upper and lower cases 24, 26 covering the outer circumference of the heating device 12.

A pair of limit switches 22i for detecting the position of the suction arm 22a corresponding to the movement stroke of the carrier 20 is provided on the upper surface side of the guide rail 22b. In addition, in FIG. 3, a member indicated by reference numeral 28 is a protective cylinder that covers the outer circumference of the heater 12c wound around the outer circumference of the heating tube 12a. The filter 18 includes a hollow cylindrical holder 18a having an open upper end, a hollow cylindrical insertion portion 18b protruding from the center of the lower end of the holder 18a, and an adsorbent (not shown) housed in the holder 18a. , And a cap 18c screwed onto the upper end of the holder 18a. The filter 18 thus configured is attached by inserting the insertion portion 18b into the through hole 12i formed in the upper portion of the heating tube 12a and fixing it by welding or the like.

Then, by connecting the connector 30 to the protrusion 18 d provided on the cap 18 c, the filter 18 and the water collecting unit 14 are connected and connected via the tube 32. In the filter 18 configured as described above, the adsorbent adsorbs and removes vaporized substances other than vaporized water that is generated when the object to be measured X is heated. It is appropriately selected and, for example, activated carbon is preferably used. The water collecting unit 14 includes a cell to which one end of the tube 32 is connected. The cell is filled with a zeolite that collects vaporized water, for example, which has a molecular selectivity, and the cell has an electromagnetic balance. The load of the water collecting unit 14 is transmitted to the electronic balance unit 16 by being coupled to the load transmitting shaft of the electronic balance unit 16 of the formula.

Next, an operation for measuring the water content of the object X to be measured with the above-described moisture meter will be described. In the measurement, first, the object to be measured X is stored in the carrier 20 and introduced into the non-heating zone b of the heating pipe 12a with the door 12e opened. Next, when the geared motor 22e is driven after the door 12e is closed, the rack 22c meshed with the pinion 22d moves to the heating zone a side of the heating pipe 12a. Along with this movement, the suction arm 22a also moves to the heating zone a side of the heating tube 12a. At this time, since the magnet piece 22g attracts the front roller 20b of the carrier 20, the suction arm 22a moves. The carrier 20 also moves to the heating zone a side of the heating tube 12a. When the carrier 20 is completely moved into the heating zone a, this is detected by the limit switch 22i, and the rotational drive of the geared motor 22e is stopped.

When the heating of the object to be measured X is completed, the operation opposite to the above is performed and the door 12e is opened to remove the burned residue of the object to be measured X from the inside of the heating pipe 12a. You can get out. When the heating pipe 12a is closed by the door 12e before and after the above operation, the carrier gas A is introduced from the gas introducing portion 10 into the heating pipe 12a through the introduction port 12h, and the inside of the heating pipe 12a When the air is completely replaced by the carrier gas A, the heater 12c is energized to heat the object to be measured X.

The vaporized substance containing the vaporized moisture separated from the object to be measured X by this heating is carried to the carrier gas A, introduced as the carrier gas B into the filter 18, and the vaporized substance other than the vaporized moisture is adsorbed by the filter 18. After being removed, the carrier gas carrying only the vaporized moisture is introduced into the moisture collecting unit 14, and then the vaporized moisture is adsorbed and held in the moisture collecting unit 14, and the increased weight of the moisture collecting unit 14 at this time is the balance unit. Measured at 16.

As described above, during the measurement process using the moisture meter, in the heating device 12 of the present embodiment, the opening of the heating pipe 12a is opened on the inner surface of the door 12e that opens and closes the opening end of the heating pipe 12a in the closed state of the door 12e. Since the heat-resistant cushion material 12f that abuts against the edge and the heat-resistant and non-breathable cover 12g that covers the surface of the cushion material 12f are provided, the vaporized water content inside the heating pipe 12a. The cover 12f prevents the invasion of the outside air carried by the operator, and as a result, the measurement accuracy of the moisture meter can be kept high.

[0022]

As described above in detail in the embodiments, the heating device for a moisture meter according to the present invention prevents outside air from entering the system of the moisture meter from the outside. The measurement accuracy of the moisture meter is kept high.

[Brief description of drawings]

FIG. 1 is a functional configuration block diagram of a moisture meter to which a heating device according to the present invention is applied.

FIG. 2 is a perspective view of a heating device according to the present invention.

FIG. 3 is a sectional view of a heating device according to the present invention.

FIG. 4 is a perspective view of a moving mechanism used in the heating device according to the present invention.

5 is a cross-sectional view of the main parts of FIG.

[Explanation of symbols]

 10 gas introduction part 12 heating device 12a heating pipe 12b support plate 12c heater 12d door receiving plate 12e door 12f cushion material 12g cover 12h inlet port 12i through hole 14 moisture collecting part 16 balance unit 18 filter A carrier gas B carrier gas C mixed gas X DUT

Claims (1)

[Scope of utility model registration request] 1. A moisture which collects and measures the vaporized water by introducing a carrier gas from the outside to heat the object to be measured, vaporizing and discharging the moisture contained in the object to be measured. In a heating device for measurement, an inlet for the carrier gas and an outlet for the carrier gas carrying vaporized moisture are provided, and a heating tube having one end for heating the object to be measured housed therein, which is closed, A door that opens and closes the open end of the heating tube, a heat-resistant cushion material that is provided on the inner surface of the door and that contacts the opening edge of the heating tube when the door is closed, and a heat-resistant cushion material that covers the surface of the cushion material. And a non-breathable cover, which is a heating device for a moisture meter.