WO2025067266A1 - Electrode sleeve for head-mounted energy pod, and head-mounted energy pod - Google Patents

Abstract

An electrode sleeve for a head-mounted energy pod and a head-mounted energy pod. The electrode sleeve is used by being sleeved on an electrode head (40) of the head-mounted energy pod. The electrode sleeve comprises a water-absorbing cloth (10), a connecting sleeve (20), and a fixing assembly (30), wherein the water-absorbing cloth (10) covers an end face of the electrode head (40) and is used for soaking with a conductive liquid to conduct the electrode head (40); the connecting sleeve (20) is connected to the water-absorbing cloth (10) and is arranged around the edge of the water-absorbing cloth (10); the connecting sleeve (20) is arranged on the side of the water-absorbing cloth (10) that comes into contact with the electrode head (40) and wraps around a side surface of the electrode head (40); and the fixing assembly (30) is arranged on the side of the connecting sleeve (20) facing away from the water-absorbing cloth (10) and is used for tightly tying the electrode head (40). By covering the electrode head (40) with the water-absorbing cloth (10) soaked with the conductive liquid, the conducting state between the electrode head (40) and the head of a user can be maintained for transcranial direct-current intervention stimulation. On this basis, the water-absorbing cloth (10) replaces the electrode head (40) to come into contact with the skin of the head of the user, providing a better tactile experience and helping to improve the wearing comfort of the user.

Description

Electrode sleeve for head-mounted energy chamber and head-mounted energy chamber Technical Field

The utility model relates to the technical field of wearable devices, in particular to an electrode sleeve for a head-mounted energy cabin and the head-mounted energy cabin.

Background Art

With the development of science and technology, modern electronic devices are becoming more and more portable. People tend to carry electronic devices with them for easy use at any time. Wearable devices are a popular type of portable device. Wearable devices are not just hardware devices, but also realize powerful functions through software support, data interaction, and cloud interaction, and monitor and influence the user's body in real time.

As a new type of wearable device, the head-mounted energy capsule is worn on the user's head and intervenes in the user's brain waves through transcranial direct current stimulation. Specifically, at least two electrode heads are set on the head-mounted energy capsule to contact the skin of the user's head to form a pathway. When powered on, a specific current passes through the area between the two electrode heads, causing changes in the membrane potential of brain neurons, leading to depolarization and hyperpolarization of neurons, thereby causing changes at the physical level.

However, the electrode head of the existing head-mounted energy capsule has a relatively hard structure and a fixed shape, and when worn, it presses against the user's skin, which can easily cause discomfort.

Therefore, the prior art still needs to be improved and developed.

Utility Model Content

In view of the above-mentioned deficiencies in the prior art, the purpose of the present invention is to provide an electrode cover for a head-mounted energy chamber and a head-mounted energy chamber, aiming to solve the problem of uncomfortable wearing of the electrode head of the existing head-mounted energy chamber.

The technical solution of the utility model is as follows:

An electrode sleeve for a head-mounted energy chamber, the electrode sleeve is mounted on an electrode head of the head-mounted energy chamber for use; wherein the electrode sleeve comprises:

A water-absorbing cloth piece, covering the end surface of the electrode head, used for soaking the conductive liquid to conduct the electrode head;

A connecting sleeve connected to the absorbent cloth block and arranged around the edge of the absorbent cloth block; the connecting sleeve is arranged on the side of the absorbent cloth block that contacts the electrode head and is wrapped around the side of the electrode head; and

The fixing assembly is arranged on a side of the connecting sleeve away from the water-absorbing cloth block and is used to fasten the electrode head.

The electrode sleeve for the head-mounted energy cabin, wherein the connecting sleeve is provided with a fork, one end of the fork extends to the side of the connecting sleeve connected to the absorbent cloth block, and the other end extends to the side of the connecting sleeve connected to the fixing assembly; wherein the width of the fork gradually increases in the direction away from the absorbent cloth block.

The electrode sleeve for the head-mounted energy cabin, wherein the fixing component includes an elastic band, a Velcro fleece surface and a Velcro hook surface, the elastic band is arranged around the edge of the connecting sleeve, one end of the elastic band is provided with the Velcro hook surface, and the other end is connected to the Velcro fleece surface, the Velcro fleece surface is fitted with the Velcro hook surface, and is used to tie the elastic band tightly to the electrode head.

The electrode sleeve for the head-mounted energy cabin, wherein the width of the Velcro fleece surface is smaller than the width of the Velcro hook surface.

The electrode sleeve for the head-mounted energy cabin, wherein the elastic band is a rubber band or an elastic band.

The electrode sleeve for the head-mounted energy cabin, wherein the absorbent cloth block has a thickness of 0.3-0.6 mm.

The electrode sleeve for the head-mounted energy cabin, wherein the water-absorbing cloth block is made by cutting wood pulp cotton cloth.

The electrode sleeve for the head-mounted energy cabin, wherein the connecting sleeve is made of polyurethane composite fabric.

The electrode sleeve for the head-mounted energy cabin, wherein one side of the connecting sleeve is sewn and connected to the absorbent cloth block, and the other side is sewn and connected to the fixing assembly.

The present application also discloses a head-mounted energy chamber, which includes an electrode sleeve for a head-mounted energy chamber as described above.

Compared with the prior art, the embodiment of the utility model has the following advantages:

The electrode head cover disclosed by the utility model is used on the electrode head of the head-mounted energy cabin. The absorbent cloth block can be soaked in conductive liquid, such as physiological saline, and the absorbent cloth block is made conductive by soaking in the conductive liquid, so that one side of the absorbent cloth block can be connected to the electrode head, and the other side of the absorbent cloth block can be in contact with the skin of the user's head and also remain conductive. Therefore, after covering the absorbent cloth block, the circuit conductivity of the head-mounted energy cabin can still be maintained, and transcranial direct current intervention can be performed normally.

On the basis of not affecting the normal operation of the head-mounted energy cabin, the electrode head is fastened to the electrode head through a fixing assembly, so that the connecting sleeve and the absorbent cloth block remain stable, avoiding loosening or slipping during use, and improving the stability of the electrode sleeve during use.

In addition, the absorbent cloth itself is made of cloth cut and woven, so it can be soaked in conductive liquid. It has a soft texture and has a good touch when in contact with the user's skin, which is conducive to improving the comfort of wearing.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to more clearly illustrate the embodiments of the utility model or the technical solutions in the prior art, the drawings required for use in the embodiments or the description of the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments recorded in the utility model. For ordinary technicians in this field, other drawings can be obtained based on these drawings without paying creative work.

FIG1 is a schematic structural diagram of an electrode sleeve for a head-mounted energy chamber in the present invention;

FIG2 is a side view of an electrode sleeve for a head-mounted energy chamber in the present invention;

FIG3 is a schematic structural diagram of the electrode sleeve and the electrode head in the present invention in a disassembled state;

FIG. 4 is a schematic structural diagram of the assembly state of the electrode sleeve and the electrode head in the utility model.

Among them, 10, absorbent cloth piece; 20, connecting sleeve; 21, slit; 30, fixing component; 31, elastic band; 32, Velcro fleece surface; 33, Velcro hook surface; 40, electrode head.

DETAILED DESCRIPTION

In order to enable those skilled in the art to better understand the solution of the utility model, the following will be combined with the drawings in the embodiments of the utility model to clearly and completely describe the technical solutions in the embodiments of the utility model. Obviously, the described embodiments are only part of the embodiments of the utility model, not all of the embodiments. Based on the embodiments of the utility model, all other embodiments obtained by ordinary technicians in this field without creative work are within the scope of protection of the utility model.

Referring to Figures 1, 2 and 3, in one embodiment of the utility model application, an electrode sleeve for a head-mounted energy cabin is disclosed, and the electrode sleeve is used on the electrode head 40 of the head-mounted energy cabin; wherein the electrode sleeve includes an absorbent cloth block 10, a connecting sleeve 20 and a fixing assembly 30, wherein the absorbent cloth block 10 is covered on the end surface of the electrode head 40 for soaking in a conductive liquid to conduct the electrode head 40; the connecting sleeve 20 is connected to the absorbent cloth block 10 and is arranged around the edge of the absorbent cloth block 10; the connecting sleeve 20 is arranged on the side of the absorbent cloth block 10 that contacts the electrode head 40 and is wrapped around the side of the electrode head 40; the fixing assembly 30 is arranged on the side of the connecting sleeve 20 away from the absorbent cloth block 10 for tightening the electrode head 40.

The electrode head 40 disclosed in this embodiment is put on the electrode head 40 of the head-mounted energy cabin for use. The absorbent cloth block 10 can be soaked in a conductive liquid, such as saline. The absorbent cloth block 10 is made conductive by soaking in the conductive liquid, so that one side of the absorbent cloth block 10 can be connected to the electrode head 40, and the other side of the absorbent cloth block 10 can be in contact with the skin of the user's head and also remain conductive. Therefore, after covering the absorbent cloth block 10, the circuit conductivity of the head-mounted energy cabin can still be maintained, and transcranial direct current intervention can be performed normally.

On the basis of not affecting the normal operation of the head-mounted energy capsule, the electrode head 40 is fastened to the electrode head 40 through the fixing assembly 30, so that the connecting sleeve 20 and the absorbent cloth block 10 remain stable, avoiding loosening or slipping during use, and improving the stability of the electrode sleeve during use.

In addition, the absorbent cloth block 10 itself is made of cloth cut and woven, so it can be soaked in conductive liquid. It has a soft texture and has a good touch when in contact with the user's skin, which is conducive to improving the comfort of wearing.

As shown in FIG. 1 , as an implementation of this embodiment, a fork 21 is disclosed on the connecting sleeve 20, one end of the fork 21 extends to the side of the connecting sleeve 20 connected to the absorbent cloth block 10, and the other end extends to the side of the connecting sleeve 20 connected to the fixing assembly 30; wherein the width of the fork 21 gradually increases in the direction away from the absorbent cloth block 10.

The electrode sleeve disclosed in this embodiment is used on the electrode head 40 as an auxiliary material of the head-mounted energy cabin. When the user directly uses the electrode head 40 for current intervention stimulation, the electrode sleeve is not needed. During use, if the user feels that the electrode head 40 is uncomfortable in contact with the skin, the electrode sleeve can be put on.

As shown in Figures 3 and 4, during the assembly process, the connecting sleeve 20 of the electrode sleeve should be covered on the side wall of the electrode head 40. In order to reduce friction during the assembly process, a fork 21 is provided on the connecting sleeve 20. Then, during assembly, the connecting sleeve 20 can be slightly opened to facilitate the smooth sleeve installation of the electrode head 40; then, when fixing, the connecting sleeve 20 can be tightened to reduce the fork 21, so that the connecting sleeve 20 is tightened on the side wall of the electrode head 40 and fits tightly, so that the absorbent cloth block 10 will not loosen, that is, it will not separate from the electrode head 40, thereby maintaining the circuit conduction during use and maintaining normal transcranial current intervention stimulation; finally, it is tied tightly with the fixing component 30 to achieve the effect of firmly connecting the electrode head 40 and the electrode sleeve, so as to improve the stability of the head-mounted energy cabin.

In summary, in this embodiment, the forked opening 21 is provided on the connecting sleeve 20 to facilitate assembly and disassembly of the electrode sleeve and the electrode head 40 , and after assembly, the connecting sleeve 20 and the electrode head 40 are in close contact, which is convenient for improving the connection stability.

As shown in Figures 1 and 3, as another implementation of this embodiment, the fixing component 30 is disclosed to include an elastic band 31, a Velcro fleece surface 32 and a Velcro hook surface 33. The elastic band 31 is arranged around the edge of the connecting sleeve 20. One end of the elastic band 31 is provided with the Velcro hook surface 33, and the other end is connected to the Velcro fleece surface 32. The Velcro fleece surface 32 is fitted with the Velcro hook surface 33, so as to tie the elastic band 31 tightly to the electrode head 40.

The fixing assembly 30 disclosed in this embodiment is connected to the connecting sleeve 20 and is used to be tied to the electrode head 40, so as to achieve stability after the electrode sleeve and the electrode head 40 are assembled. An elastic band 31 is provided as a main body, which is arranged around the edge of the connecting sleeve 20. When in use, the elastic band 31 can be tightened by pulling the Velcro fur surface 32. When the Velcro fur surface 32 is attached to the Velcro hook surface 33, the elastic band 31 is kept in a tightened state so as to be stably tied to the side wall of the electrode head 40.

In addition, in this embodiment, the Velcro fur surface 32 and the Velcro hook surface 33 are used in combination, so that the fixing function of the fixing component 30 can be adjusted at any time. When the Velcro fur surface 32 and the Velcro hook surface 33 are fitted, the connecting sleeve 20 is tightened, so that the split opening 21 is tightened, and the electrode sleeve is stably sleeved on the electrode head 40; when the Velcro fur surface 32 is torn off, the elastic band 31 retracts, the connecting sleeve 20 loses its restraining force, and the split opening 21 automatically opens, so that the inner wall of the connecting sleeve 20 is separated from the side wall of the electrode head 40, which is convenient for removing the electrode sleeve. It can be seen that fixing with Velcro is convenient for disassembly, which is convenient for users to use, replace, repair or clean the electrode sleeve at any time.

Specifically, as another implementation of this embodiment, it is disclosed that the width of the Velcro fleece surface 32 is smaller than the width of the Velcro hook surface 33. The Velcro hook surface 33 disclosed in this embodiment has a larger width, which is convenient for connection with the Velcro fleece surface 32, and is conducive to all positions on the Velcro fleece surface 32 being fitted with the Velcro hook surface 33, thereby achieving a good connection effect. Specifically, the Velcro fleece surface 32 has a width of 8 mm, and the Velcro hook surface 33 has a width of 10 mm. At this time, when the Velcro fleece surface 32 is fitted, it can float up and down by about 1 mm, and can be completely fitted to the Velcro hook surface 33, without worrying about the problem of small fitting area and unstable connection.

Specifically, as another implementation of this embodiment, it is disclosed that the elastic band 31 is a rubber band or an elastic band. The elastic band 31 disclosed in this embodiment is connected to the connecting sleeve 20 and is used to be tied to the electrode head 40, so it has flexibility and elasticity. It can achieve the binding effect by being set as a rubber band or an elastic band. It should be noted that in this embodiment, only the types of elastic bands 31 are listed, but the protection scope of the utility model is not limited to this. As long as other types of elastic bands 31 can achieve the technical effects disclosed in this application, as an equivalent replacement of the concept of the utility model, they should also be within the scope of protection of this application.

Specifically, as another implementation of this embodiment, the thickness of the absorbent cloth block 10 is disclosed to be 0.3-0.6 mm. The absorbent cloth block 10 disclosed in this embodiment is used to soak the conductive solution to conduct the electrode head 40. The thickness of the absorbent cloth block 10 should not be too thick. If it exceeds 0.6 mm, more physiological saline is required to soak both sides of the absorbent cloth block 10, which is enough to conduct the electrode head 40 and the user's skin. In the actual operation process, if the physiological saline is soaked on the absorbent cloth block 10, if there is too much physiological saline, it is affected by gravity. During use, the physiological saline may continue to flow to the user's scalp, affecting the user's experience. The thickness of the absorbent cloth block 10 should not be too thin. If it is less than 0.3 mm, the user may still feel the hardness of the electrode head 40 when wearing the head-mounted energy cabin, so the problem of uncomfortable wearing cannot be solved.

In addition, from a manufacturing perspective, fabrics that are too thin require high production technology and are difficult to manufacture; fabrics that are too thick waste materials, so being too thin or too thick will increase production costs.

Specifically, as another implementation of this embodiment, the absorbent cloth block 10 is disclosed to be made of wood pulp cotton cloth. Wood pulp cotton is made from lignin and wood cellulose in natural wood, and is a natural fiber with high toughness and elasticity and high temperature resistance; it does not contain chemical fibers, so it is non-irritating to the skin. In addition, wood pulp cotton has very good water absorption, can expand rapidly after absorbing water, has a soft texture, and has very good water retention, and will not easily seep water; wood pulp cotton will harden after drying, which can prevent bacteria from growing, and will not mold after drying; in addition, wood pulp cotton can be automatically degraded and rotted after being discarded after use, and no harmful gases are emitted when burned, so it is a pure natural and harmless product.

In general, the absorbent cloth block 10 in this embodiment is made of wood pulp cotton cloth, which has excellent water absorption and water locking properties, which is conducive to achieving the effect of long-lasting and stable connection between the electrode head 40 and the user's skin, and is not easy to breed bacteria when used in an alternating dry and wet environment, which is convenient for improving the cleanliness of the electrode sleeve and extending the service life of the electrode sleeve.

Specifically, as another implementation of this embodiment, the connection sleeve 20 is disclosed to be cut and made of polyurethane composite fabric. The polyurethane composite fabric has good softness, good waterproofness, comfortable touch, and long service life. As the connecting part of the electrode sleeve, it can be stably fitted with the electrode head 40, so that the absorbent cloth block 10 is more fitted to the electrode head 40 and maintains a tight connection.

Specifically, as another implementation of this embodiment, one side of the connecting sleeve 20 is sewed and connected to the water-absorbing cloth block 10, and the other side is sewed and connected to the fixing assembly 30. The water-absorbing cloth block 10, the connecting sleeve 20 and the fixing assembly 30 disclosed in this embodiment can all be made of soft materials, so they can be connected together by sewing. The connection method is simple, but the connection effect is good, so as to make the entire electrode sleeve lightweight.

As another embodiment of the present application, a head-mounted energy capsule is disclosed, which includes an electrode sleeve for a head-mounted energy capsule as described above. The head-mounted energy capsule disclosed in this embodiment can use the electrode sleeve as an auxiliary material. When a user uses the head-mounted energy capsule, if the electrode head 40 feels uncomfortable touching the head, the electrode sleeve can be put on to obtain a more comfortable touch and enhance the comfort of use.

In summary, the present application discloses an electrode sleeve for a head-mounted energy cabin, wherein the electrode sleeve is sleeved on the electrode head 40 of the head-mounted energy cabin for use; wherein the electrode sleeve comprises an absorbent cloth block 10, a connecting sleeve 20 and a fixing assembly 30, wherein the absorbent cloth block 10 is coated on the end surface of the electrode head 40 for soaking in a conductive liquid to conduct the electrode head 40; the connecting sleeve 20 is connected to the absorbent cloth block 10 and is arranged around the edge of the absorbent cloth block 10; the connecting sleeve 20 is arranged on the side of the absorbent cloth block 10 in contact with the electrode head 40 and is wrapped around the side of the electrode head 40; the fixing assembly 30 is arranged on the side of the connecting sleeve 20 away from the absorbent cloth block 10 for tightening the electrode head 40. The electrode head 40 disclosed in this embodiment is used when it is sleeved on the electrode head 40 of the head-mounted energy cabin. One side of the absorbent cloth block 10 can be connected to the electrode head 40, and the other side of the absorbent cloth block 10 can be in contact with the skin of the user's head and also remain conductive. Therefore, after the absorbent cloth block 10 is coated, the circuit of the head-mounted energy cabin can still be maintained, and the transcranial direct current intervention can be performed normally. On the basis of not affecting the normal operation of the head-mounted energy cabin, the electrode head 40 is tied to the electrode head 40 by the fixing component 30, so that the connecting sleeve 20 and the absorbent cloth block 10 are both kept stable, avoiding loosening or slipping during use, and improving the stability of the electrode sleeve during use. In addition, the absorbent cloth block 10 itself is made of cloth cut and woven, so it can be soaked in conductive liquid, and it has a soft texture and has a good touch when in contact with the user's skin, so it is conducive to improving the comfort of wearing and use.

It should be noted that, in the absence of conflict, the embodiments and features in the embodiments of the present application may be combined with each other.

It should be noted that the present invention takes the electrode cover for a head-mounted energy cabin as an example to introduce the specific structure and working principle of the present invention, but the application of the present invention is not limited to the electrode cover for a head-mounted energy cabin, and can also be applied to the production and use of other similar workpieces.

It should be understood that the present invention is not limited to the precise structure described above and shown in the drawings, and various modifications and changes can be made without departing from the scope thereof. The scope of the present invention is limited only by the appended claims.

The above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Any modifications, equivalent substitutions, improvements, etc. made within the spirit and principles of the present utility model should be included in the protection scope of the present utility model.

Claims (10)

An electrode sleeve for a head-mounted energy chamber, the electrode sleeve is sleeved on the electrode head of the head-mounted energy chamber for use; the electrode sleeve is characterized in that the electrode sleeve comprises: A water-absorbing cloth piece, covering the end surface of the electrode head, used for soaking the conductive liquid to conduct the electrode head; A connecting sleeve connected to the absorbent cloth block and arranged around the edge of the absorbent cloth block; the connecting sleeve is arranged on the side of the absorbent cloth block that contacts the electrode head and is wrapped around the side of the electrode head; and The fixing assembly is arranged on a side of the connecting sleeve away from the water-absorbing cloth block and is used to fasten the electrode head. According to the electrode sleeve for a head-mounted energy cabin according to claim 1, it is characterized in that a fork is provided on the connecting sleeve, one end of the fork extends to the side of the connecting sleeve connected to the absorbent cloth block, and the other end extends to the side of the connecting sleeve connected to the fixing assembly; wherein the width of the fork gradually increases in the direction away from the absorbent cloth block. The electrode cover for a head-mounted energy cabin according to claim 2 is characterized in that the fixing component includes an elastic band, a Velcro fleece surface and a Velcro hook surface, the elastic band is arranged around the edge of the connecting sleeve, one end of the elastic band is provided with the Velcro hook surface, and the other end is connected to the Velcro fleece surface, the Velcro fleece surface is fitted with the Velcro hook surface, and is used to tie the elastic band tightly to the electrode head. The electrode sleeve for a head-mounted energy cabin according to claim 3 is characterized in that the width of the Velcro fleece surface is smaller than the width of the Velcro hook surface. The electrode sleeve for a head-mounted energy cabin according to claim 3 is characterized in that the elastic band is a rubber band or an elastic band. The electrode sleeve for a head-mounted energy cabin according to claim 1 is characterized in that the thickness of the water-absorbing cloth block is 0.3-0.6 mm. The electrode sleeve for a head-mounted energy cabin according to claim 1 is characterized in that the absorbent cloth block is made of wood pulp cotton cloth. The electrode sleeve for a head-mounted energy cabin according to claim 1 is characterized in that the connecting sleeve is made of polyurethane composite fabric. The electrode sleeve for a head-mounted energy cabin according to claim 1 is characterized in that one side of the connecting sleeve is sewn to the absorbent cloth block, and the other side is sewn to the fixing assembly. A head-mounted energy chamber, characterized in that it comprises an electrode sleeve for a head-mounted energy chamber as described in any one of claims 1 to 9.