KR20230003966A - Electroless plating device that can measure plating rate - Google Patents

Abstract

The present invention provides an electroless plating apparatus which comprises: a reactor for electroless plating (300); and a quartz crystal microbalance (QCM) sensor mounting body unit (600) mounted on the reactor for electroless plating (300). The QCM sensor mounting body unit (600) has an elongated shape in the longitudinal direction, and has a QCM sensor (60) built inside, whose electrode has an exposure unit (655), which is a partial area of the electrode, exposed through an exposure opening unit (688). Also formed are withdrawal guide units (611)(612) withdrawing extension lines (61)(62) which are extended by being connected to lead lines (631)(632) of the electrode of the QCM sensor (60). The reactor for electroless plating (300) has an inflow opening (185) of the QCM sensor mounting body unit, and also has a plurality of inflow openings (188) into which porous support bodies (11) in a tube shape such as a hollow fiber membrane are inserted and mounted. The extension lines (61)(62) are connected to QCM equipment (700)(800) and a calculation computer (900). Therefore, the plating rate can be measured in a scale where the actual plating is conducted.

Description

Electroless plating device that can measure plating rate}

The present invention relates to an electroless plating apparatus capable of measuring a plating rate, and more particularly, the present invention relates to an electroless plating device capable of measuring a plating rate in electroless plating a porous support such as a hollow fiber membrane for the manufacture of a hydrogen separation membrane. It relates to an electroless plating device capable of measuring plating speed.

In order to purify hydrogen produced from the reforming reaction of CH ₄ , a hydrogen separation membrane plated with dense palladium may be used.

Hydrogen can dissolve in various metals and can penetrate metals. Among them, palladium is the most studied metal as a hydrogen separation membrane material because it diffuses hydrogen rapidly and separates it with high purity.

A palladium-based hydrogen separation membrane can be manufactured by plating a dense palladium layer on a porous support.

The porous support may be used in various forms such as materials such as metals and ceramics and tubular, plate, and disk shapes.

In order to manufacture such a hydrogen separation membrane, various techniques such as sputtering, chemical vapor deposition, electroplating, and electroless plating may be used.

Among these methods, electroless plating is the most commonly used technology in manufacturing a hydrogen separation membrane using a metal layer because palladium can be plated on supports of various shapes and materials with simple and economical equipment.

However, electroless plating has different reactivity depending on various factors such as plating solution composition, volume, plating area, temperature, pH, solution stirring speed, etc. Plating is performed on various scales, and the factors determining the reaction change for each scale, Plating characteristics also change. Due to this, there is a problem that plating conditions must be searched again to reproduce the plating characteristics of the previous plating scale whenever the scale is changed, which is difficult in terms of time and cost.

The present invention seeks to solve these problems. That is, in the present invention, in performing electroless plating on a porous support for the manufacture of a hydrogen separation membrane, it is possible to measure the plating speed in each case while performing plating at various scales. Plating speed is a numerical expression of plating characteristics, and it can be used as an index to reproduce specific plating characteristics even in a situation where the plating scale changes, making it easy to optimize plating conditions.

The present invention uses QCM (Quartz Crystal Microbalance) to measure the plating speed. However, in the prior art search related to the present invention, it was not found that the plating speed of electroless plating can be measured using QCM as in the present invention. And, as for using QCM, 'Crystal Crystal Microscale (QCM) Biosensor Device' of Utility Model Registration No. 20-0440969-0000 was found.

An object of the present invention is to perform electroless plating on a porous support for the manufacture of a hydrogen separation membrane, so that plating can be achieved on a variety of scales and the plating rate can be measured in each case. It is to provide a plating device.

the present invention

(a) a reactor for electroless plating;

(b) A QCM sensor mounting body in which a QCM sensor having two flat electrodes, a quartz crystal between the two flat electrodes, and a lead wire extending from the two flat electrodes is mounted. made up of wealth; here,

(c1) In the QCM sensor of the QCM sensor mounting body, a portion of the area of one of the flat electrodes is exposed to the outside of the QCM sensor mounting body, and the exposed portion of the flat electrode is the electrode. It becomes an exposed part, and the surface of the electrode on which the exposed part of the electrode is formed is pretreated,

(c2) An extension line connected to the lead wire of the QCM sensor and connected to the QCM measurement equipment is provided, and a drawing guide portion for guiding and drawing the extension line is formed on the QCM sensor mounting body,

(c3) the QCM sensor is mounted on the QCM sensor mounting body so that the two plate-shaped electrodes and the crystal oscillator are airtight except for the exposed portion of the electrode;

(d) In the reactor for electroless plating, an inlet opening of the QCM sensor mounting body is formed so that the QCM sensor mounting body can be inserted and mounted, and a plurality of tubular porous supports to be subjected to electroless plating are drawn in It provides an electroless plating device capable of measuring plating speed, characterized in that the inlet opening of a plurality of porous supports is formed so that it can be mounted.

According to the present invention,

(a) the inlet opening of the QCM sensor mounting body and the inlet opening of the porous support are formed on the upper surface of the electroless plating body,

(b) The QCM sensor mounting body has a long shape in the vertical direction, and when installed in the electroless plating reactor, the exposed portion of the electrode is located at the bottom thereof, and the exposed portion of the electrode has a length long enough to be submerged in the plating solution. , It is preferable that the withdrawal guide portion is formed on the opposite side of the exposed portion of the electrode along the longitudinal direction.

According to the present invention,

(a) the QCM sensor mounting body has an upper body and a lower body that are detachably coupled to each other,

(b) a QCM sensor mounting groove in which the QCM sensor is placed and an exposure opening through which the exposed portion of the electrode is exposed is formed on the bottom surface of the lower body, and a cover mounting groove covering the QCM sensor mounting groove is formed, In addition, the lower body portion is provided with a cover that covers the QCM sensor mounting groove and presses and fixes the QCM sensor.

(c) the QCM sensor is placed in the QCM sensor mounting groove by arranging O-rings above and below the QCM sensor, and the cover is detachably mounted on the cover mounting groove thereon;

(d) It is preferable that the upper and lower body parts are detachably coupled to each other with a sealing sheet interposed therebetween.

In this case, it is preferable that the withdrawal guide part communicates with the QCM sensor mounting groove in the lower body part and is formed along the vertical direction.

According to the present invention,

(a) the electroless plating reactor consists of an upper cap and a lower body that are detachably coupled to each other;

(b) the lower body has an open top and a cavity formed therein;

(c) It is preferable that the inlet opening of the QCM sensor mounting body part and the inlet opening of the plurality of porous supports are formed in the upper cap.

According to the present invention, the lower body portion of the electroless plating reactor preferably includes a hollow body portion and a bottom portion detachably coupled to maintain airtightness by blocking the lower portion of the hollow body portion.

According to the present invention, the QCM sensor mounting body portion is made of a Teflon material, and the porous support is preferably made of a ceramic material.

According to the present invention, it is preferable that the reactor for electroless plating is made of a transparent acrylic material, and the inner surface of the hollow part is coated with a plating blocking masking liquid.

According to the present invention, the plating speed can be measured using QCM in an environment in which actual plating is performed. In particular, the plating speed in that case is measured by mounting only the number of porous supports to be actually plated, which means that the plating speed can be measured from a small scale to a large scale.

That is, the present invention allows the plating speed to be measured on the scale in which actual plating is performed using QCM.

1 and 2 are views showing the basic configuration of an electroless plating apparatus capable of measuring plating speed according to the present invention;
Figure 3 is a view showing the appearance of the QCM sensor mounting body portion according to the present invention;
4 is a view showing a QCM sensor;
5 and 6 are views showing the structure of the QCM sensor mounting body portion according to the present invention;
7 is a view showing that an electroless plating device capable of measuring plating speed according to the present invention is connected to QCM equipment and a calculation computer;
8 is a view showing the result of measuring the amount of change in thickness according to the amount of change in frequency over time using QCM equipment;
Figure 9 is a view showing that the plating rate is calculated by differentiating the amount of change in thickness with time;
10 is a view showing the difference between the thickness measured according to the present invention and the thickness of palladium plated on the actual separator.

Now, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 and 2 are views showing the basic configuration of an electroless plating apparatus 1000 capable of measuring plating speed according to the present invention.

According to the present invention, first, the electroless plating apparatus 1000 capable of measuring the plating speed has a reactor 300 for electroless plating and a QCM sensor mounting body 600.

In the electroless plating reactor 300, a plating solution 4 is filled in a cavity 38 therein, and a palladium layer is plated on a tubular porous support 11 made of a ceramic material such as a hollow fiber membrane.

The QCM sensor mounting body 600 has a QCM sensor 60 installed therein, in this embodiment. It has an elongated shape in the vertical direction.

This QCM sensor mounting body 600 is mounted on the reactor 300 for electroless plating.

That is, an inlet opening 185 of the QCM sensor mounting body portion is formed in the electroless plating reactor 300 so that the QCM sensor mounting body portion 600 can be inserted and mounted therein.

In addition, a plurality of inlet openings 188 of the porous support through which the tubular porous support can be introduced and mounted are formed.

In addition, a reducing agent input opening 14 through which reducing agent can be injected is also formed.

In this embodiment, the reactor 300 for electroless plating has an upper cap 10 and a lower body 30 that are detachably coupled to each other.

The upper part 382 of the lower body part 30 is open and a cavity part 38 is formed therein.

In this embodiment, the lower body portion 30 has a hollow body portion 33 and a bottom portion 34 detachably coupled to maintain airtightness as blocking the lower portion of the hollow body portion 33. .

The hollow of the hollow body portion 33 forms the cavity portion 38.

In this embodiment, the hollow body part 33 and the bottom part 34 have a structure in which screws are fastened to each other, and an O-ring 341 is installed on the bottom part 34 to maintain airtightness.

In this case, it is preferable that the hollow body portion 33 is made of transparent acrylic, and the inner surface of the hollow portion 38 is coated with a plating blocking masking liquid (388).

In electroless plating, palladium is not plated on the porous support 11 during plating, but palladium is plated on the wall of the reactor. This phenomenon reduces plating efficiency and makes it difficult to form a dense palladium layer, so that the inside of the reactor is plated It is common that it is composed of materials that do not

However, in this embodiment, the hollow body 33 was made of a transparent acrylic material so that the inside of the reactor could be observed with the naked eye to observe the precipitation of palladium and the degree of plating of the separator, and the inside was coated with a plating blocking masking liquid. .

To this end, as described above, the lower body portion 30 is divided into the hollow body portion 33 and the bottom portion 34 that is detachably coupled to maintain airtightness by blocking the lower portion of the hollow body portion 33. that made it happen

In this embodiment, the main component of the plating blocking masking solution is polytetrafluoroethylene (PTFE), and the product name WJ-300 (Wooju Chemical) was used.

In this embodiment, the upper cap 10 has the form of a flat plate, and the above-described QCM sensor mounting body portion 185 and the plurality of porous support 188 are formed therein.

As shown, the circumferential portion 31 is formed around the open portion 382 of the upper portion of the hollow body portion 30, and the circumferential portion 31 and the upper cap 10 are mutually connected through screw holes. It is screwed through (12).

Accordingly, as shown in FIG. 2, the plating solution 4 is filled inside the electroless plating reactor 300, and the QCM sensor mounting body 600 and a plurality of porous supports are filled in the electroless plating reactor 300. (11) are mounted and immersed in the plating solution (4).

Figure 3 is a view showing the appearance of the QCM sensor mounting body portion 600 according to the present invention, Figure 4 is a view showing the QCM sensor (60).

The QCM sensor mounting body part 600 has a vertically long shape, and the QCM sensor 60 is installed so that a part of the electrode of the QCM sensor 60 is exposed to the outside.

4 is a view showing the structure of the QCM sensor 60, wherein the QCM sensor 60 is between two flat electrodes 63 and 65 and between the two flat electrodes 63 and 65 It has a quartz crystal 68 and lead wires 631 and 632 attached to the two plate-shaped electrodes 63 and 65.

The QCM sensor 60 has a support 69 on which electrodes 63 and 65 and lead wires 631 and 632 are installed.

In the QCM sensor 60 mounted on the QCM sensor mounting body 600, a portion of the area of the flat plate of any one 65 of the flat electrodes 63 and 65 is the QCM sensor mounting body 600. ) is exposed to the outside of

Referring to FIG. 3 , it can be seen that the exposed portion 655 of the electrode, which is a portion of the exposed plate-shaped electrode, is exposed to the outside through the exposure opening 668 .

As will be described later, the exposed portion 655 of the electrode is pretreated, and as palladium is plated thereon, it is recognized through the QCM equipment (700, 800) and the porous support mounted on the reactor (300) for electroless plating. The plating speed of (11) is measured.

Extension lines 61 and 62 connected to the lead wires 631 and 632 of the QCM sensor 60 and connected to the QCM measurement equipment are provided. These extension lines 61 and 62 are shown in FIG. Likewise, thread solder having a diameter of 0.4 to 0.5 mm is tightly wound around the lead wires 631 and 642 to form extensions from these lead wires 631 and 632.

Referring again to FIG. 3 , the QCM sensor mounting body 600 is formed with withdrawal guide parts 611 and 612 for guiding and withdrawing the extension lines 61 and 62 .

In the QCM sensor 60, the two plate-shaped electrodes 63 and 65 and the crystal oscillator 68 are airtight except for the exposed portion 655 of the electrode on the QCM sensor mounting body 600. installed to maintain

In addition, the QCM sensor mounting body part 600 has a long shape in the vertical direction, and when it is installed in the electroless plating reactor 300, the exposed part 655 of the electrode is located at the bottom thereof, so that the electrode The exposed portion 655 has a length sufficient to be immersed in the plating solution 4 .

In addition, the withdrawal guide parts 611 and 612 are formed on the opposite side of the exposed part 655 of the electrode along the vertical direction.

5 and 6 are views showing the structure of the QCM sensor mounting body 600 according to the present invention.

With reference to these, the QCM sensor mounting body portion 600 has an upper body portion 630 and a lower body portion 650 detachably coupled to each other.

In the lower body part 650, the QCM sensor 60 is placed, and a QCM sensor mounting groove 668 is formed on the bottom surface of which an exposure opening 688 through which the exposed part 655 of the electrode is exposed is formed, A cover mounting groove 664 covering the QCM sensor mounting groove 688 is formed thereon.

In addition, a cover 635 covering the QCM sensor mounting groove 668 and fixing the QCM sensor 60 by pressing is provided on the lower body part 650 .

Accordingly, the QCM sensor 60 is placed with O-rings 6a and 6b disposed above and below the QCM sensor 60 in the QCM sensor mounting groove 668, and the cover 635 is placed thereon. It is detachably mounted to the cover mounting groove 664 with screws 7.

In this state, the upper body portion 630 and the lower body portion 65 are detachably coupled to each other by screwing through a sealing sheet 693 therebetween.

In this case, the withdrawal guide parts 611 and 612 communicate with the QCM sensor mounting groove 668 in the lower body part 65 and are formed along the vertical direction.

According to the present invention, it is preferable that the QCM sensor mounting body 600 is made of Teflon material to minimize plating of palladium on its surface during electroless plating.

7 shows that the electroless plating apparatus 1000 capable of measuring the plating speed according to the present invention is connected to the QCM equipment 700 and 800 and the computer 900.

First, as shown, the QCM sensor mounting body 600 and the plurality of porous supports 11 are drawn into the cavity 38 and immersed in the plating solution 4 in the reactor 300 for electroless plating.

At this time, it is not necessary for the porous supports 11 to be drawn in and mounted to the inlet openings 188 of all the porous supports, and the required number of the porous supports 11 may be drawn in and mounted.

QCM (Quartz Crystal Microbalance) equipment 700, 800 measures the frequency change of the QCM sensor 60 to measure the weight change in ng / cm ² unit or the thickness between μm and nm in real time.

The QCM sensor 60 has a constant frequency, and when a specific material is adsorbed on the electrode surface and the weight of the electrode changes, the frequency also changes. will be able to calculate.

As shown in FIG. 7, the extension lines 61 and 62 of the QCM sensor 60 are connected to the oscillator 700 and connected again to the frequency meter 800, and through this, the QCM sensor 60 according to the plating The amount of frequency change is measured, and the calculation computer 900 receives the value to measure the plating speed.

In electroless plating, the plating speed is changed by various factors such as the volume of the plating solution, the composition of the plating solution, and the temperature of the solution.

Therefore, when measuring the plating rate, it is necessary to match the number of porous supports 11 as well.

Therefore, for example, if the plating speed for plating of six porous supports 11 is to be measured, the plating speed should be measured after mounting the six porous supports 11.

According to the present invention, the number of porous supports 11 inserted into the inlet openings 188 of the plurality of porous supports 11 is adjusted according to the plating scale. The number of inlet openings 188 of the porous support provided in this embodiment is 10, so it is possible to measure the plating speed while performing electroless plating on a scale equal to or smaller than 10.

In the case of the embodiment of FIG. 7, it is shown that the plating rate for plating of 10 porous supports 11 is measured.

As shown, the QCM sensor mounting body 600 is positioned only to the extent that the exposed portion 655 of the electrode is immersed in the plating solution 4.

This is because the deeper the immersion, the larger the area where palladium can be plated in addition to the hydrogen separation membrane, which can act as a factor in changing the plating speed.

When performing the above, an activation (pre-processing) process is required only for the plating portion of the QCM sensor 60.

The porous support 11 made of ceramic material is preceded by a process of seeding palladium nuclei, that is, an activation (pre-treatment) process before electroless plating. Since the porous support is pre-treated, the exposed portion 655 of the electrode Also, the same pretreatment should be performed.

The following shows the components and plating conditions of the plating solution subjected to electroless plating according to the present invention.

As shown in FIG. 8, the thickness change amount was measured according to the frequency change amount over time using the QCM equipment (700, 800), and the final palladium thickness was confirmed to be 3.617 μm. After about 5 hours, no further thickness was deposited, and it was confirmed that the reaction was terminated at that point.

The plating speed was calculated by differentiating the thickness change over time. The plating speed increased significantly at the time hydrazine was injected and then decreased gradually. could be observed to increase. (See Fig. 9)

In order to confirm that the thickness measured according to the present invention is different from the thickness of palladium plated on the actual separator, palladium was plated on the porous supports 11 of the hollow fiber membrane under the same solution composition and plating conditions. FE-SEM analysis was performed. As a result of SEM analysis, the thickness of the palladium layer plated on the porous supports 11 of the hollow fiber membrane is about 4.1 to 4.2 μm, which is very close as the thickness measured according to the present invention shows an error rate of about 11 to 14%. can know that (See Fig. 10)

According to the present invention, the plating speed can be measured using QCM in an environment in which plating is actually performed. In particular, the plating speed in that case is measured by mounting only the number of porous supports 11 that are actually plated, which means that the plating speed can be measured from a small scale to a large scale.

That is, the present invention allows the plating speed to be measured on the scale in which actual plating is performed using QCM.

1000: Electroless plating device capable of measuring plating speed
300: reactor for electroless plating
600: QCM sensor mounting body
10: top cap of electroless plating reactor
185: inlet opening of QCM sensor mounting body
188: inlet opening of porous support
30: lower body of electroless plating reactor
33: hollow body
34: bottom
11: porous support
60: QCM sensor
63, 65: flat electrode
68: crystal oscillator
631, 632: lead wire
61, 62: extension line
630: upper body of QCM sensor mounting body
650: lower body of QCM sensor mounting body
655: exposed portion of electrode
668: exposure aperture
700: Oscillator
800: frequency meter
900: calculation computer

Claims (8)

(a) a reactor for electroless plating;
(b) A QCM sensor mounting body in which a QCM sensor having two flat electrodes, a quartz crystal between the two flat electrodes, and a lead wire extending from the two flat electrodes is mounted. made up of wealth; here,
(c1) In the QCM sensor of the QCM sensor mounting body, a portion of the area of one of the flat electrodes is exposed to the outside of the QCM sensor mounting body, and the exposed portion of the flat electrode is the electrode. It becomes an exposed part, and the surface of the electrode on which the exposed part of the electrode is formed is pretreated,
(c2) An extension line connected to the lead wire of the QCM sensor and connected to the QCM measurement equipment is provided, and a drawing guide portion for guiding and drawing the extension line is formed on the QCM sensor mounting body,
(c3) the QCM sensor is mounted on the QCM sensor mounting body so that the two plate-shaped electrodes and the crystal oscillator are airtight except for the exposed portion of the electrode;
(d) In the reactor for electroless plating, an inlet opening of the QCM sensor mounting body is formed so that the QCM sensor mounting body can be inserted and mounted, and a plurality of tubular porous supports to be subjected to electroless plating are drawn in An electroless plating device capable of measuring plating speed, characterized in that an inlet opening of a plurality of porous supports is formed so that it can be mounted. According to claim 1,
(a) the inlet opening of the QCM sensor mounting body and the inlet opening of the porous support are formed on the upper surface of the electroless plating body,
(b) The QCM sensor mounting body has a long shape in the vertical direction, and when installed in the electroless plating reactor, the exposed portion of the electrode is located at the bottom thereof, and the exposed portion of the electrode has a length long enough to be submerged in the plating solution. , Electroless plating apparatus capable of measuring plating speed, characterized in that the withdrawal guide portion is formed on the opposite side of the exposed portion of the electrode along the longitudinal direction. According to claim 2,
(a) the QCM sensor mounting body has an upper body and a lower body that are detachably coupled to each other,
(b) a QCM sensor mounting groove in which the QCM sensor is placed and an exposure opening through which the exposed portion of the electrode is exposed is formed on the bottom surface of the lower body, and a cover mounting groove covering the QCM sensor mounting groove is formed, In addition, the lower body portion is provided with a cover that covers the QCM sensor mounting groove and presses and fixes the QCM sensor.
(c) the QCM sensor is placed in the QCM sensor mounting groove by arranging O-rings above and below the QCM sensor, and the cover is detachably mounted on the cover mounting groove thereon;
(d) The electroless plating device capable of measuring plating speed, characterized in that the upper body and the lower body are detachably coupled to each other with a sealing sheet interposed therebetween. According to claim 3,
The electroless plating device capable of measuring plating speed, characterized in that the withdrawal guide is formed along the longitudinal direction in communication with the QCM sensor mounting groove in the lower body. According to claim 4,
(a) the electroless plating reactor consists of an upper cap and a lower body that are detachably coupled to each other;
(b) the lower body has an open top and a cavity formed therein;
(c) The electroless plating device capable of measuring plating speed, characterized in that the inlet opening of the QCM sensor mounting body and the inlet opening of the plurality of porous supports are formed in the upper cap. According to claim 5,
Electroless plating device capable of measuring plating speed, characterized in that the lower body of the electroless plating reactor includes a hollow body and a bottom that is detachably coupled to maintain airtightness by blocking the lower portion of the hollow body. . According to any one of claims 1 to 6,
The QCM sensor mounting body is made of Teflon material,
The electroless plating device capable of measuring the plating rate, characterized in that the porous support is made of ceramic. According to claim 7,
The electroless plating device capable of measuring plating speed, characterized in that the reactor for electroless plating is made of a transparent acrylic material, and the inner surface of the hollow part is coated with a plating blocking masking liquid.

Images