KR20240028881A - Bio-signal measuring device having solderable electro-conductive fiber - Google Patents

Abstract

The present invention relates to a biosignal measurement device equipped with an improved solderable electrically conductive fiber that allows for soldering of the biosignal measurement electrode thread woven into the electrically conductive fiber and improves durability and electrical conductivity.
The present invention provides a base member, a first adhesive member attached to the upper surface of the base member, a metal mesh member attached to the upper surface of the adhesive member, a second adhesive member attached to the upper surface of the metal mesh member, and a measuring pad including electrically conductive fibers attached to the upper surface of the second adhesive member and a protective member provided on the upper surface of the electrically conductive fibers; A circuit board provided in a connection pattern for soldering electrode yarns drawn from the electrode yarns of the electrically conductive fiber, wherein the electrode yarns and the electrode yarns are made of a metal material having a melting point higher than a soldering temperature and can be soldered. A biosignal measuring device equipped with a conductive fiber is provided.

Description

Biosignal measurement device equipped with electrically conductive fibers that can be soldered {BIO-SIGNAL MEASURING DEVICE HAVING SOLDERABLE ELECTRO-CONDUCTIVE FIBER}

The present invention relates to a biosignal measuring device equipped with an electrically conductive fiber that can be soldered. More specifically, the biosignal measurement electrode thread woven into the electrically conductive fiber is improved to enable soldering and improve durability and electrical conductivity. This relates to a biosignal measuring device equipped with electrically conductive fibers.

Recently, due to increased interest in health, changes in lifestyle, and the entry into an aging society, the need for systematic management of individual health from a social perspective is emerging.

Accordingly, the demand for technology that can systematically monitor and manage individual health is increasing.

In particular, bio-signal measurement fibers are suitable for measuring bio-signals because they are in contact with the human body anytime and anywhere, and research and attempts are being made to easily mount various types of bio-signal measurement sensors on bio-signal measurement clothing.

Additionally, an inductive biosignal measurement sensor has been proposed that consists of a coil-type magnetic field sensor based on conductive thread or conductive fabric and detects volumetric changes in biological tissue using changes in inductance.

Meanwhile, a conductive fabric-based inductive biosignal measurement sensor is disclosed in Registered Patent No. 10-1302600 (registered on August 26, 2013).

An example of an electrically conductive fiber for measuring biosignals applied to the above-described biosignal measurement sensor is shown in FIG. 1.

Referring to FIG. 1, the electrically conductive fiber 10 was woven into a fabric or patch form to be applied to a bio-signal measurement sensor or device.

In other words, the electrically conductive fiber 10 for measuring biosignals applied to a biosignal measuring sensor or device is manufactured by weaving a composite conductive yarn 11 with a warp yarn (warp yarn) and a weft yarn (weft yarn).

At this time, the composite conductive yarn 11 consists of a conductive layer coated on the outside of the fiber yarn.

For example, polyamide (PA) may be used as the fiber yarn, and the conductive layer may be coated with silver (Ag).

In order to electrically connect the electrically conductive fiber 10 for measuring biosignals configured as described above to a circuit board (not shown) of a biosignal measurement sensor or device, a lead electrode yarn 11a drawn from the composite conductive yarn 11 is used. Solder it to the connection pattern of the circuit board.

However, the lead-out electrode yarn 11a of the conventional composite conductive yarn 11 as described above has a problem in that it is difficult to solder.

The reason is that when soldering the lead-out electrode yarn 11a, the soldering temperature (about 350°C) is too high and the lead-out electrode yarn 11a cannot withstand the high soldering temperature.

1. Biological signal measurement clothing using a conductive member placed on the skin of Registered Patent Publication No. 10-1840115 (registered on March 13, 2018) 2. Conductive fabric-based inductive biosignal measurement sensor of Registered Patent Publication No. 10-1302600 (registered on August 26, 2013) 3. Unconstrained motion measurement device and method using electrically conductive fiber of Patent Publication No. 10-2010-0063595 (published on June 11, 2010)

The present invention was created to solve the above problems, and the lead electrode thread of the electrically conductive fiber for measuring biosignals can be soldered to the connection pattern of the circuit board, and the solderable electrical conductivity is improved to improve durability and electrical conductivity. The purpose is to provide a biosignal measuring device equipped with fibers.

The biosignal measuring device equipped with the solderable electrically conductive fiber of the present invention to achieve the above object is,

A base member, a first adhesive member attached to an upper surface of the base member, a metal mesh member attached to an upper surface of the adhesive member, a second adhesive member attached to an upper surface of the metal mesh member, and the second adhesive a measuring pad including electrically conductive fibers attached to the upper surface of the member and a protective member provided on the upper surface of the electrically conductive fibers;

A circuit board provided in a connection pattern for soldering electrode threads drawn from the electrode threads of the electrically conductive fiber,

The electrode yarn and the lead-out electrode yarn are characterized in that they are made of a metal material having a melting point higher than the soldering temperature.

In the present invention, the second adhesive member is formed by penetrating the first adhesive member through the metal mesh member.

In the present invention, the base member and the protective member are made of insulating members.

In the present invention, the metal mesh member is made of copper mesh.

In the present invention, the electrically conductive fiber is woven with composite conductive yarns as warp and weft yarns, and is made of electrode yarns woven with warp and weft yarns at regular intervals between the composite conductive yarns, wherein the electrode yarn and the lead yarn are The electrode yarn contains Cu.

In the present invention, the composite conductive yarn includes a fiber yarn as a core; A conductive layer coated on the outside of the fiber yarn, wherein the fiber yarn contains polyamide (PA) and the conductive layer contains silver (Ag).

In the present invention, the first and second adhesive members include a hot melt adhesive.

According to an embodiment of the present invention, a metal mesh member made of a mesh of Cu material is laminated on an electrically conductive fiber, and the first adhesive member is adhered to the metal mesh member 130 to improve adhesion with the metal mesh member. , the first adhesive member passes through the through hole 131 of the metal mesh member due to external pressure and then protrudes on the upper surface of the metal mesh member to form the second adhesive member 120a, forming a measurement pad.

Therefore, the electrically conductive fiber and the metal mesh member are integrated by the second adhesive member, thereby improving the electrical conduction performance of the electrically conductive fiber.

In addition, by forming a protective member on the upper part of the electrically conductive fiber and providing a base member on the lower part, the durability of the measurement pad is improved.

In addition, electrode yarns are woven with weft and warp yarns at regular intervals between the composite conductive yarns, and the electrode yarns are made up of lead electrode yarns drawn from the electrode yarns, and the lead electrode yarns are soldered to a connection pattern of a circuit board, and the electrode yarns and By using Cu as the lead electrode yarn, which has a high melting temperature, excellent electrical conductivity, and is relatively inexpensive compared to silver (Ag), it can be easily soldered to the connection pattern of the circuit board.

Figure 1 is an enlarged plan view showing the overall configuration of an electrically conductive fiber for measuring biological signals according to the prior art.
Figure 2 is a plan view showing an enlarged overall configuration of a biosignal measuring device equipped with a solderable electrically conductive fiber according to the present invention.
Figure 3 is a cross-sectional view taken along line AA in Figure 2.
Figure 4 is a detailed view showing part 'A' of Figure 3 in detail.
Figure 5 is a cross-sectional view showing the configuration of the composite conductive fiber provided in the electrically conductive fiber of Figure 3.
Figure 6 is an exploded cross-sectional view shown to more clearly reveal the configuration of the members required to manufacture the measurement pad of Figure 2.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the attached drawings.

Figure 2 shows a plan view showing the overall configuration of a bio-signal measuring device equipped with a solderable electrically conductive fiber according to the present invention.

And FIG. 3 shows a cross-sectional view cut along line A-A in FIG. 2.

Additionally, FIG. 4 shows a detailed view showing part 'A' of FIG. 3 in detail.

Referring to Figures 2 to 4, the biological signal measuring device equipped with an electrically conductive fiber that can be soldered according to the present invention includes a base member 110 and a first adhesive member attached to the upper surface of the base member 110. (120), a metal mesh member 130 attached to the upper surface of the first adhesive member 120, a second adhesive member 120a attached to the upper surface of the metal mesh member 130, and the second adhesive member 120a. A measuring pad 100 including an electrically conductive fiber 140 attached to the upper surface of the adhesive member 120a and a protective member 150 provided on the upper surface of the electrically conductive fiber 140, and this measuring pad ( It is configured to include a circuit board 200 provided with a connection pattern 201 so that the lead-out electrode yarn 141 drawn from the electrode yarn of the electrically conductive fiber 140 of 100 is soldered.

The base member 110 and the protective member 150 are made of an insulator, and the base member 110 and the protective member 150 may be laminated by, for example, laminating or thermal bonding. .

And the electrode yarn and the lead-out electrode yarn 141 are made of a metal material having a melting point higher than the soldering temperature.

These electrode yarns and the lead-out electrode yarn 141 may be composed of Cu.

Additionally, the base member 110 is formed by penetrating the first adhesive member 120 through the metal mesh member 130, as will be described later.

This metal mesh member 130 is made of copper mesh (Cu mesh).

And the electrically conductive fiber 140 is woven using the composite conductive yarn 140 as warp and weft yarns, and is made of electrode yarns woven with warp and weft yarns at regular intervals between the composite conductive yarns 140.

In addition, as shown in FIG. 5, the composite conductive yarn 140 includes a core fiber yarn 143a and a conductive layer 143b coated on the outside of the fiber yarn 143a. The yarn 143a contains polyamide (PA), and the conductive layer 143b contains silver (Ag).

The first and second adhesive members 120 and 120a include hot melt adhesive.

The hot melt adhesive applied as the first and second adhesive members 120 and 120a is not limited to a specific material, and since hot melt adhesive is a known technology, detailed description will be omitted here.

Meanwhile, the circuit board 200 includes a Flexible Printed Circuit Board (FPCB).

The operation of the bio-signal measuring device equipped with the solderable electrically conductive fiber according to the present invention having the above-mentioned configuration will be described as follows.

Referring again to FIGS. 2 to 4, the biosignal measuring device equipped with a solderable electrically conductive fiber according to the present invention is provided at the bottom of the electrically conductive fiber 140 to improve the electrical conductivity of the measurement pad 100. Metal mesh members 130 made of Cu mesh were laminated, and the first adhesive member 120 was attached to the lower part of the metal mesh member 130 to improve adhesion to the metal mesh member 130. .

To explain this in detail, FIG. 6 is an exploded cross-sectional view shown to more clearly reveal the configuration of the parts required to manufacture the measurement pad 100.

Referring to FIG. 6, the measurement pad 100 includes, first, a base member 110, a first adhesive member 120 on the upper surface of the base member 110, and an upper surface of the first adhesive member 120. A metal mesh member 130, an electrically conductive fiber 140 on the upper surface of the metal mesh member 130, and a protective member 150 on the upper surface of the electrically conductive fiber 140 are sequentially stacked to prepare.

Subsequently, when the stacked members 110, 120, 130, 140, and 150 are pressed with a certain pressure from above and below, the upper part of the first adhesive member 120 is formed through the through hole of the metal mesh member 130 due to external pressure, as shown in FIG. 4. After passing through 131), it protrudes from the upper surface of the metal mesh member 130 and a second adhesive member 120a is formed.

Accordingly, the electrically conductive fiber 140 and the metal mesh member 130 are integrated by the second adhesive member 120a, thereby improving the electrical conduction performance of the electrically conductive fiber 140.

In addition, by forming a protective member 150 on the upper part of the electrically conductive fiber 140 and providing a base member 110 on the lower part, the durability of the measurement pad 100 is improved.

Next, the lead electrode yarn 141 is pulled out from the electrode yarn of the electrically conductive fiber 140 of the measurement pad 100 configured as above and soldered to the connection pattern 201 of the circuit board 200.

At this time, by applying Cu, which has a high melting temperature (about 1,080°C), excellent electrical conductivity, and is relatively inexpensive compared to silver (Ag), for the electrode yarn and lead-out electrode yarn 141, the circuit board It can be easily soldered to the connection pattern 201 of (200).

Therefore, the electrically conductive fiber 140 for measuring biosignals that can be soldered according to the present invention can be easily used in biosignal measuring devices or sensors.

As described above, the present invention has been described with reference to an embodiment shown in the drawings, but this is merely illustrative, and various modifications and equivalent embodiments can be made by those skilled in the art. You will understand.

Therefore, the true scope of protection of the present invention should be determined only by the appended claims.

100. Measuring pad
110. Base member
120. First adhesive member
120a. Second adhesive member
130. Metal mesh member
140. Electrically conductive fiber
141. Withdrawal electrode thread
150. Protective member
200. Circuit board
201. Connection pattern

Claims (7)

A base member, a first adhesive member attached to an upper surface of the base member, a metal mesh member attached to an upper surface of the adhesive member, a second adhesive member attached to an upper surface of the metal mesh member, and the second adhesive a measuring pad including electrically conductive fibers attached to the upper surface of the member and a protective member provided on the upper surface of the electrically conductive fibers;
A circuit board provided in a connection pattern for soldering electrode threads drawn from the electrode threads of the electrically conductive fiber,
A biosignal measuring device equipped with a solderable electrically conductive fiber, wherein the electrode yarn and the lead-out electrode yarn are made of a metal material having a melting point higher than a soldering temperature. According to paragraph 1,
The second adhesive member is formed by penetrating the first adhesive member through the metal mesh member. According to paragraph 1,
A biosignal measuring device equipped with a solderable electrically conductive fiber, wherein the base member and the protective member are made of an insulating member. According to paragraph 1,
A biosignal measuring device equipped with a solderable electrically conductive fiber, wherein the metal mesh member is made of a copper mesh. According to paragraph 1,
The electrically conductive fiber is woven with composite conductive yarns as warp and weft yarns, and is made of electrode yarns woven with warp and weft yarns at regular intervals between the composite conductive yarns,
A biosignal measuring device equipped with a solderable electrically conductive fiber, wherein the electrode yarn and the lead-out electrode yarn contain Cu. According to paragraph 1,
The composite challenger,
fiber yarn as the core;
Including a conductive layer coated on the outside of the fiber yarn,
A biosignal measuring device equipped with a solderable electrically conductive fiber, wherein the fiber yarn contains polyamide (PA), and the conductive layer contains silver (Ag). According to paragraph 1,
A biosignal measuring device equipped with a solderable electrically conductive fiber, wherein the first and second adhesive members include a hot melt adhesive.