PL70468Y1 - Textile electrode - Google Patents

Abstract

The subject of the application is a textile electrode consisting of a conductive fabric layer (1) and an elastic filling (2). On the edges of the conductive fabric layer (1) there is a border (3) made of a non-conductive and elastic material. The border (3) is located on the top and bottom sides of the conductive fabric layer (1). Around the edges of the conductive fabric layer (1) there is a trim (4) made of a conductive thread.

Description

PL 70 468 Y1 2 Description of the design The subject of the utility model is a textile electrode intended for use in ECG examinations, especially those performed using a special suit. To conduct an ECG examination, it is necessary to record electrical impulses emitted by the heart. These signals are captured using electrodes placed on the patient's skin in designated locations. Currently, there are many types of electrodes used in ECG examinations. Gel electrodes are the most popular. They provide good signal quality due to the use of a gel, which ensures good electrical conductivity. The gel has adhesive properties, allowing the electrodes to self-adhesively adhere to the skin and do not require additional elements to secure them to the designated location on the patient's body. They are flexible, allowing them to adapt well to the body's shape. These electrodes can be used when the patient is in a resting position or in motion. They can be used repeatedly, but their lifespan is limited by the durability of the gel. A disadvantage of this type of electrode is the need for special skin preparation for proper attachment. Another disadvantage is that they cause skin irritation, making them unsuitable for long-term, continuous use. Another common solution is dry plate electrodes. Made of hard metal, they cannot adapt to the patient's body shape. Therefore, they are primarily used in studies when the patient is in a resting position. A variation of plate electrodes are those offered by Orbital Research Inc. These electrodes are equipped with protrusions on their surface that act as a measuring element. The protrusions increase the interaction between the skin and the electrode by mechanically connecting them. This provides a better signal compared to standard plate electrodes. These electrodes can be used for long-term ECG measurements. The disadvantage of these electrodes, similar to standard plate electrodes, is that they are hard and do not conform to the patient's body shape. Therefore, they cause significant discomfort for the patient during long-term measurements. Non-contact electrodes are also used in ECG tests. An example of this type of electrode is the sensor offered by Plessey. This type of sensor allows for the measurement of signals through clothing and can be used for long-term use. However, the signals recorded by these electrodes are of poor quality and are mainly used for heart rate measurement. In recent years, textile electrodes have become increasingly popular. Most are dry electrodes – no gel or liquid is used to improve electrical conductivity. Due to their construction, these electrodes can adapt to the patient's body shape. Textile electrodes can be used when the patient is in a resting position or in motion. These electrodes are often placed in special garments designed to collect ECG signals during the patient's daily activities. In the case of the simplest textile electrodes, they are also used in sportswear for heart rate monitoring. Polish patent application P.390850 discloses a solution for a textile electrode designed specifically for electrostimulation. The electrode comprises a layer of a textile product made of electrically conductive fibers, attached by an electrically conductive thread to a layer of an electrically conductive textile product made of non-conductive fibers. The electrode is attached to the inner surface of a piece of clothing or a textile headband. A filler is placed between the electrically conductive layer and the layer of flexible textile product made of non-conductive fibers. Furthermore, the textile layer made of electrically conductive fibers is equipped with leads for power sources made of electrically conductive fibers. US patent application US2013172722 discloses a textile electrode for measuring electrical signals from the body. The electrode comprises, from the side where the electrode is applied to the body: a conductive material, a material base to support the conductive material, and a layer of evaporation-reducing material that limits fluid evaporation from the textile electrode. The electrode also comprises a fluid-absorbing material or gel used to improve electrical conductivity. Another U.S. patent application, US2011288394, describes textile electrodes comprising a fabric region having a stretchable, non-conductive yarn and an electrically conductive region having a stretchable, electrically conductive yarn. The electrodes may have a textured or ribbed design. When the electrodes are placed on clothing, they can be used to monitor biophysical signals such as heart rate. According to the invention, the electrodes may be used as a wristband for remote monitoring of a patient's cardiac functions. In such a case, the wristband consists of two material layers with an integrated electrode. The portion of the wristband in contact with the skin includes a conductive region formed as a continuous ring or strip. In another embodiment, the electrodes may be used as part of an infant's clothing. In this case, they are located in the body region and optionally in another area. The purpose of the utility model is to create a textile electrode intended for ECG measurements that can be used by the patient continuously for at least several days during their daily activities, while also accurately recording the electrical signals emitted by the heart. The textile electrode according to the utility model, consisting of a layer of conductive fabric and a flexible filling, is characterized in that the edges of the conductive fabric layer are surrounded by a rim made of a non-conductive and flexible material. The rim is located on the top and bottom of the conductive fabric layer. A border made of conductive thread extends around the edges of the conductive fabric layer. Preferably, the border is covered by a border. The width of the border is between 3 and 5 mm. The thickness of the rim on the top of the conductive fabric layer is 1 to 2 mm, while the thickness of the rim on the bottom of the conductive fabric layer is 0.5 to 1 mm. The rim is made of silicone or neoprene. The flexible filling is a 5 to 10 mm thick polyurethane sponge. The electrode is square-shaped, measuring 40 by 40 mm. The advantage of the textile electrode, as shown in the utility model, is that it is lightweight and flexible, making it comfortable to use. The electrode is a dry electrode – no special gel or liquid is required to ensure good signal quality. This significantly eliminates the risk of skin irritation at the electrode site. Thanks to these features, the electrode is suitable for applications requiring continuous, multi-day recording of ECG signals during the patient's daily activities. Another advantage of the solution presented in the utility model is the electrode's good adhesion to the patient's body, achieved by using a border around its edges. This eliminates the risk of interrupted or distorted signals. The subject of the utility model is presented in the drawing, where Fig. 1 shows the textile electrode in an axonometric view, and Fig. 2 shows the electrode in cross-section. According to the solution, the textile electrode presented in the model comprises a layer of conductive fabric 1 and a flexible filling 2. The conductive fabric layer 1 is a fabric made of 63% cotton, 35% silver, and 2% spandex. On the edges of the conductive fabric layer 1 is a rim 3 made of a non-conductive, flexible material. As shown, rim 3 can be made of medical-grade silicone or neoprene. These materials are non-conductive, flexible, and adhere well to the skin. Rim 3 is located on the top and bottom of the conductive fabric layer 1. The thickness of the rim on the top of the conductive fabric layer 1 is 1.5 mm, while on the bottom of the conductive fabric layer 1 is 0.5 mm. The width of rim 3 is 5 mm. The edges of the conductive fabric 1 are permanently connected to rim 3, embedded in the material from which the rim is made. This makes the electrode durable and prevents damage from continuous, long-term wear. The edges of the conductive fabric are connected to the rim 3 so that the conductive fabric layer 1 bulges in the central part of the electrode. This creates a space for the filler 2. Filler 2 is a 5- to 10-mm-thick polyurethane sponge saturated with silver colloids, which acts as a disinfectant. The sponge presses the conductive material against the patient's skin, ensuring the electrode properly collects electrical signals emitted by the heart. The use of the sponge provides flexibility and softness, eliminating pressure from the electrode on the subject's body. To collect electrical signals captured by the conductive fabric, a conductive thread trim 4 extends around the edges of the conductive fabric layer 1. This trim is located approximately 4 mm from the electrode edge. The end of the hem 4 is a fragment of conductive thread located under the filler 2. This free fragment of conductive thread enables the electrode to be connected to a wire running to the device recording the heart's electrical signals. The conductive thread is made of X2CrNiMo17-12-2/1.4404 steel. The hem 4 is covered by a rim 3, both on the top and bottom sides of the conductive fabric layer 1. The insulating properties of the material from which the rim 2 is made ensure that the electrical signals collected by the conductive thread are isolated from interference. The electrode has a rectangular shape, measuring 40 by 40 mm. According to the model, the electrode does not have a bottom layer that would enclose the electrode from below, hold the filling 2, or that would serve to attach the electrode, for example, to clothing designed specifically for measuring cardiac electrical activity. The electrode that is the subject of the application does not have this element, as it is intended to be placed in sets of several pieces on a layer of flexible, non-conductive material, which can then be mounted on clothing designed for ECG measurements. PL PL PL PL PL PL PL

Claims (1)

1.