KR102346600B1 - Guard device through which microcurrent flows - Google Patents

Abstract

The present invention relates to a guard device through which microcurrent flows, which comprises: a guard which is formed of an electrically conductive fiber material; and a microcurrent transfer unit which is detachably coupled to the guard, and is provided with a power terminal part for generating microcurrent. When the microcurrent transfer unit is attached to the guard, the power terminal part allows microcurrent to flow into a user's skin, and the microcurrent transmitted to the user's skin reaches the power terminal part again through the protector.

Description

Guard device through which microcurrent flows

The present invention relates to a guard device through which a microcurrent flows, and in more detail, to a guard device through which a microcurrent flows in which a detachable microcurrent transfer unit is formed.

As a protector used to protect a part of a person's body, various protectors such as a wrist protector for protecting the wrist, an ankle protector for protecting the ankle, and a waist protector for protecting the lower back are used.

Among them, the wrist protector is worn on the wrist, and is used to reduce pain in the wrist or prevent injury when exercising such as tennis.

During tennis exercise, when the amount of impact transmitted through the racquet is concentrated on the wrist at the moment of striking the ball, the wrist protector acts as a buffer.

However, conventional protectors such as wrist guards help to reduce or prevent injuries to the wrist, but there is a problem in that it is insufficient to effectively reduce or prevent damage to the wrist or the like caused by repeated impacts.

Korean Patent Publication No. 2020-0119134

An object of the present invention is to provide a guard device through which a micro-current flows in which a structure capable of improving the function of the guard is formed.

The present invention includes a protector formed of an electrically conductive fiber material, and a microcurrent transfer unit detachably coupled to the protector and provided with a power terminal for generating a microcurrent, and when the microcurrent transfer unit is attached to the protector, the power supply It provides a protector device through which a microcurrent flows, characterized in that the terminal unit flows a microcurrent to the user's skin, and the microcurrent delivered to the user's skin reaches the power terminal again through the protector.

The power terminal unit may be formed of a tourmaline component to generate a microcurrent in a non-charging manner.

The micro-current transfer unit is formed symmetrically with the first transfer unit body and the first transfer unit body in which the power terminal part is installed, and a magnetic member is formed so as to be in contact with or separated from the first transfer unit body by magnetic force. It may include a second transmission unit body and a connecting member for connecting the first transmission unit body and the second transmission unit body.

The micro-current transfer unit includes a fixing clip formed around the power terminal, the power terminal having a concave groove formed on the periphery, and the fixing clip includes a fixing portion surrounding the periphery of the concave groove, and in the fixing portion It may include a clip elastic portion formed in a curved shape to extend to be bent.

The micro-current transfer unit may include a transfer unit body in which the power terminal is installed, and a clamp member hingedly coupled to the transfer unit body.

In the present invention, the positive terminal of the power terminal is formed to protrude from the outer side of the first transmission unit body, and the negative terminal of the power terminal is formed to protrude from the inner side of the first transmission unit body.

A first magnetic force member and a second magnetic force member are formed on both sides of the negative terminal on the inner side of the first transfer unit body, and a third magnetic force member and a fourth magnetic force member are formed in the second transfer unit body, the When the first transmission unit body and the second transmission unit body overlap and a part of the protector is positioned between the first transmission unit body and the second transmission unit body, the first magnetic force member and the fourth magnetic force member are separated by magnetic force When the magnetic force is pulled between the second magnetic force member and the third magnetic force member, the negative terminal may be in contact with the surface of the protector.

The guard may include a copper wire through which current flows.

The first magnetic force member, the second magnetic force member, the third magnetic force member, and the fourth magnetic force member may be formed with a magnetic force protrusion or a magnetic force groove into which the magnetic force protrusion is introduced.

A terminal guide portion may be further formed between the third magnetic force member and the fourth magnetic force member to be positioned around the negative terminal when the first transfer unit body and the second transfer unit body overlap each other.

In the terminal guide part, two terminal guide protrusions may be formed of an electrically conductive member.

A micro-current amplifying unit connected to the two terminal guide protrusions, respectively, and a display unit connected to the micro-current amplifying unit may be formed on the second transfer unit body.

The present invention has an effect of activating the transfer of bio-signals flowing through the wrist while a bio-electric field is formed through a semi-permanent micro-current transfer action that does not require replacement of batteries by applying a micro-current transfer unit to the wrist guard.

Figure 1 (a) is a schematic perspective view showing a first embodiment of the present invention a guard device through which a microcurrent flows, Figure 1 (b) is a schematic cross-sectional view showing the portion AA' in Figure 1 (a).
Figure 2 (a) is a schematic plan view showing the micro-current transfer unit used in Figure 1, Figure 2 (b) is a schematic bottom view showing the micro-current transfer unit used in Figure 1, Figure 2 (c) ) is a schematic side view showing the microcurrent transmitting unit used in FIG. 1, (d) of FIG. 2 is a schematic side view showing the folded state of the microcurrent transmitting unit in FIG. 2(c).
Figure 3 (a) is a schematic front view showing a second embodiment of the protector device through which a microcurrent flows according to the present invention, and Fig. 3 (b) is a schematic side view showing a third embodiment of the protector device through which a microcurrent flows according to the present invention. to be.
Figure 4 (a) is a schematic front view showing a first modified example of the micro-current transfer unit, Figure 4 (b) is a schematic cross-sectional view showing B-B' in Figure 4 (a), Figure 4 ( c) is a schematic perspective view showing that the first modified example of the microcurrent transfer unit is applied to a wrist guard, and (d) of FIG. 4 is a schematic cross-sectional view showing C-C' in FIG.
Fig. 5 (a) is a schematic front view showing a second modified example of the microcurrent transmitting unit, Fig. 5 (b) is a schematic side view showing a second modified example of the microcurrent transmitting unit, Fig. 5 (c) is a schematic perspective view showing that the second modified example of the microcurrent transfer unit is applied to a wrist guard, and FIG. 5 (d) is a schematic cross-sectional view showing D-D' in FIG.
Figure 6 (a) is a schematic plan view showing a third modified example of the microcurrent transfer unit, Figure 6 (b) is a schematic bottom view showing a third modified example of the microcurrent transfer unit, Figure 6 (c) ) is a schematic side view showing a third modified example of the microcurrent transmitting unit, (d) of FIG. 6 is a schematic side view showing that the third modified example of the microcurrent transmitting unit is applied to one side of the wrist guard.

Hereinafter, various embodiments of the present invention will be described with reference to specific embodiments shown in the accompanying drawings. Differences in the embodiments are to be understood in a complex way as they are not mutually exclusive, and without departing from the spirit and scope of the present invention, specific shapes, structures and characteristics described in relation to the embodiments may differ from other embodiments. can be implemented as

The position or arrangement of individual components according to embodiments of the present invention is to be understood as a combination of the drawings as being changeable, and like reference numerals in the drawings may refer to the same or similar functions throughout various aspects, including length and area; Thickness and the like may be exaggerated for convenience of description.

It is assumed that each unit, module, part, member, or arbitrary structure in which sub-elements are not described includes or can contain conventional sub-elements for each assigned function, limited to the sub-elements or detailed structures shown in the drawings. don't

It should be understood that components shown but whose description is omitted as a general description are inherent in the detailed description of the embodiments.

Figure 1 (a) is a schematic perspective view showing a first embodiment of the present invention a guard device through which a microcurrent flows, Figure 1 (b) is a schematic cross-sectional view showing a portion AA' in Figure 1 (a), Fig. Figure 2 (a) is a schematic plan view showing the micro-current transfer unit used in Figure 1, Figure 2 (b) is a schematic bottom view showing the micro-current transfer unit used in Figure 1, Figure 2 (c) is a schematic side view showing the microcurrent transmitting unit used in FIG. 1, (d) of FIG. 2 is a schematic side view showing the folded state of the microcurrent transmitting unit in FIG. 2(c).

The first embodiment of the present invention, the protector device 100 through which a microcurrent flows is a wrist protector 110 formed of an electrically conductive fiber material through which current can flow, and the wrist protector 110 is detachably coupled to the microcurrent. It includes a microcurrent transfer unit 130 that can be generated.

The wrist guard 110 includes a metal material such as copper wire through which an electric current flows.

The cloth of the wrist protector 110 is formed by mixing a general fiber material 112 with a copper yarn 114 that is an electrically conductive material. If necessary, it is also possible to form the wrist protector 110 so that current can flow through a treatment method such as applying an electrically conductive material such as copper or silver powder to the wrist protector 110 formed of an elastic cloth material.

The microcurrent transfer unit 130 includes a first transfer unit body 150 , a connecting member 170 extending from the first transfer unit body 150 , and a first transfer unit extending from the connecting member 170 . and a second transmission unit body 190 formed symmetrically with the unit body 150 .

The first transmission unit body 150 has a power terminal 210 formed of a tourmaline component to generate a microcurrent in a non-charging manner is installed in the center, and specifically, power is supplied to the outer portion 288 of the first transmission unit body. The positive terminal 212 of the terminal unit 210 is formed to protrude, and the negative terminal 214 of the power terminal unit 210 is installed to the inner side 290 of the first transmission unit body to protrude.

A first magnetic member 230 and a second magnetic member 240 are formed on both sides of the first transmission unit body inner side 290 with the negative terminal 214 as a center.

The connection member 170 is formed of an elastic rubber material to connect the first transmission unit body 150 and the second transmission unit body 190, and a plurality of concave portions 172 are formed at regular intervals to form the first When the transmission unit body 150 and the second transmission unit body 190 are folded to overlap each other, they are easily folded by the recess 172 .

The second transmission unit body 190 has a third magnetic force member 330 on the second transmission unit body inner side 310 in contact with the first transmission unit body inner side 290 when folded with the first transmission unit body 150 and A fourth magnetic member 350 is formed.

When the first transmission unit body 150 and the second transmission unit body 190 overlap each other, the first magnetic member 230 is joined to the fourth magnetic member 350 by magnetic force, and the second magnetic member Reference numeral 240 is joined to the third magnetic member 330 by magnetic force.

When the microcurrent transfer unit 130 is applied to one end of the wrist guard 110 as shown in FIG. 1 (b), the first transfer unit body 150 and the second transfer unit body 190 overlap between the wrist It has a shape that surrounds a part of the protector 110 . That is, a portion of the wrist guard 110 overlaps between the first transmission unit body 150 and the second transmission unit body 190 at one end of the wrist protector 110 so that the first transmission unit body 150 and the second transmission unit body 150 are overlapped. 2 is located between the transfer unit body 190, the first magnetic force member 230 and the fourth magnetic force member 350 is pulled by magnetic force, the second magnetic force member 240 and the third magnetic force The members 330 are pulled by magnetic force, and the negative terminal 214 is in contact with the surface of the wrist guard 110 .

At this time, the plus terminal 212 flows a microcurrent while in contact with the skin of the user's wrist, and the microcurrent transmitted to the user's wrist is transmitted to the wrist protector 110 through the user's wrist, and the wrist protector ( After reaching the negative terminal 214, the microcurrent delivered to 110) is circulated again through the positive terminal 212 to form a biological electric field, thereby activating the transmission of biological signals flowing through the wrist.

The microcurrent is safe because the amount of current is 5 to 90 microamperes, which is similar to the bioelectric current of 10 microamperes.

In a state in which the micro-current transfer unit 130 is not inserted into the wrist guard 110 , current does not flow, so the wrist guard 110 may be used as a general compression wrist guard 110 .

The power terminal 210 of the micro-current transfer unit 130 uses natural tourmaline to re-arrange electrical particles and can be used semi-permanently without additional charging.

As described above, the present invention applies the micro-current transfer unit 130 to the wrist protector 110 so that the bio-electric field is formed through the semi-permanent micro-current transfer action that does not require replacement of batteries, and the transfer of bio-signals flowing to the wrist. The activation effect is generated.

The bioelectricity used to activate the transmission of the biosignal functions to transmit an electric signal to our body through nerve fibers, and it instantly transmits a command from the cerebrum to the big toe, or makes the head stand tall while watching a horror movie. do.

When there is a problem with the function of transmitting nerves in the brain, there is a paralysis in which the bioelectricity does not occur or the muscles cannot move due to an error. When a microscopic current of a size similar to that of bioelectricity flows through the body, the cells are activated, speeding up wound healing, and controlling pain.

The magnitude of the bioelectricity varies depending on the state of health, and in general, as muscle activity decreases with age, the bioelectricity also decreases. In addition, if a bone is broken or injured by an external shock, the flow of electric current is cut off and does not flow properly.

If a microcurrent is passed here, ion exchange between cells becomes active and recovery is accelerated, and if anion is intentionally generated, it attracts more cations than usual to help cells regenerate and relieve pain.

It is a scientifically proven fact that the microcurrent increases the production of ATP (adenosine triphosphate) and improves blood circulation, and it is possible to expect a weight loss effect by increasing metabolism as well as recovering from muscle fatigue.

The current flowing in tourmaline, a tourmaline, is a weak current of 5 to 90 microamperes, and it is the most suitable current for the human body.

The wrist protector 110 is a 99.9% antibacterial fabric that contains copper yarn to prevent various harmful bacteria, and the microcurrent transfer unit 130 can be easily removed after replacing the wrist protector 110 . It can also be used for the replacement wrist strap 110 .

Figure 3 (a) is a schematic front view showing a second embodiment of the protector device through which a microcurrent flows according to the present invention, and Fig. 3 (b) is a schematic side view showing a third embodiment of the protector device through which a microcurrent flows according to the present invention. to be.

The second embodiment of the present invention, the protector device 100 through which a microcurrent flows, is a knee protector 400 formed of a fiber material through which current can flow, and is detachably coupled to the knee protector 400 to provide a permanent microcurrent It includes a microcurrent transfer unit 130 that can be generated.

The knee protector 400 is formed in a shape that can wrap the knee, and an auxiliary strap 420 is additionally formed to support the knee.

The microcurrent transfer unit 130 is the same as the microcurrent transfer unit 130 of the first embodiment, and is used by being inserted into the upper side of the knee protector 400 .

The third embodiment of the present invention, the protector device 100 through which a microcurrent flows, is detachably coupled to the ankle protector 500 formed of a fiber material through which electric current can flow, and the ankle protector 500 to provide a permanent microcurrent. It includes a microcurrent transfer unit 130 that can be generated.

The ankle protector 500 is formed in a shape that can wrap the ankle, and is formed in a shape that can be worn like a sock.

The micro-current transfer unit 130 is the same as the micro-current transfer unit 130 of the first embodiment, and is used by being inserted into the upper side of the ankle protector 500 .

As described above, the protector device 100 through which the microcurrent flows according to the present invention can also be used for knees or ankles.

Figure 4 (a) is a schematic front view showing a first modified example of the micro-current transfer unit, Figure 4 (b) is a schematic cross-sectional view showing B-B' in Figure 4 (a), Figure 4 ( c) is a schematic perspective view showing that the first modified example of the microcurrent transfer unit is applied to a wrist guard, and (d) of FIG. 4 is a schematic cross-sectional view showing C-C' in FIG.

A first modified example 598 of the microcurrent transfer unit includes a power terminal part 210 formed of a tourmaline component, and a fixed clip part 600 formed by rotating a wire in a clip shape around the power terminal part 210 a plurality of times. include

The power terminal unit 210 includes a body portion 620 having a concave groove 610 formed around it, a positive terminal 212 formed on one side of the body portion 620, and the other side of the body portion 620 formed on the other side. A negative terminal 214 is included.

The fixing clip part 600 is inserted into the concave groove 610 of the body part 620 and is extended from the body fixing part 630 and the body fixing part 630 surrounding the periphery of the body part 620 . It includes a clip elastic portion 640 formed in the form of being bent gradually away from the center of the body portion 620 on the same plane as the body portion (620).

In a state in which the user wears the wrist protector 110 , the power terminal unit 210 is attached to the wrist protector by slightly elastically deforming the clip elastic portion 640 of the fixing clip unit 600 so that the plus terminal 212 is in contact with the skin. (110) When the deformation of the elastic clip portion 640 is removed after being drawn inside, the elastic clip portion 640 is elastically restored and the first modified example 598 of the microcurrent transfer unit on one side of the wrist guard 110 is is fixed

In this state, the current generated from the positive terminal 212 flows through the human body to the hand guard and is transferred to the negative terminal 214 to activate the bioelectricity of the wrist.

Fig. 5 (a) is a schematic front view showing a second modified example of the microcurrent transmitting unit, Fig. 5 (b) is a schematic side view showing a second modified example of the microcurrent transmitting unit, Fig. 5 (c) is a schematic perspective view showing that the second modified example of the microcurrent transfer unit is applied to a wrist guard, and FIG. 5 (d) is a schematic cross-sectional view showing D-D' in FIG.

The second modified example 655 of the microcurrent transmission unit includes a transmission unit body 660 formed in the form of a thin plate in a rectangular shape, and a power terminal 210 formed of a tourmaline component embedded in the transmission unit body 660 and , and a clamp member 676 hinged to the transfer unit body (660).

The power terminal part 210 is embedded in the delivery unit body 660, and the positive terminal 212 of the power terminal part 210 is formed to protrude from one side portion 672 of the transmission unit body, and the other side portion 674 of the transmission unit body has a protruding shape. The negative terminal 214 of the power terminal unit 210 is formed to protrude.

A clamp member 676 is located on the other side portion 674 of the transmission unit body where the negative terminal 214 is located, and the clamp member 676 is a hinge shaft 678 connected to the transmission unit body 660, and, It includes a clamp body 680 bent around the hinge shaft 678 and an elastic member 682 such as a spring formed between the rear end of the clamp body 680 and the transmission unit body 660 .

When the rear end of the clamp body 680 is pressed, the front end of the clamp body 680 about the hinge shaft 678 along with elastic deformation of the elastic member 682 is lifted from the other side portion 674 of the transmission unit body.

When the second modified example 655 of the micro-current transfer unit is worn on one side of the wrist guard 110 using the clamp member 676, a current flows from the positive terminal 212 and passes through the wrist to the wrist guard 110 ) and then transferred to the negative terminal 214 .

Figure 6 (a) is a schematic plan view showing a third modified example of the microcurrent transfer unit, Figure 6 (b) is a schematic bottom view showing a third modified example of the microcurrent transfer unit, Figure 6 (c) ) is a schematic side view showing a third modified example of the microcurrent transmitting unit, (d) of FIG. 6 is a schematic side view showing that the third modified example of the microcurrent transmitting unit is applied to one side of the wrist guard.

The third modified example 700 of the microcurrent transmission unit is a form in which some components are added to the first transmission unit body 150 and the second transmission unit body 190 in the microcurrent transmission unit 130 of FIG. 2 , The added part will be mainly explained.

A third modified example 700 of the microcurrent transfer unit includes a first transfer unit body 150 , a connecting member 170 extending from the first transfer unit body 150 , and extending from the connecting member 170 . and a second transmission unit body 190 formed symmetrically with the first transmission unit body 150 .

In the first transmission unit body 150, the power terminal part 210 formed of tourmaline component is embedded in the center, and the positive terminal 212 of the power terminal part 210 protrudes from the outer part 288 of the first transmission unit body, The negative terminal 214 of the power terminal part 210 is formed to protrude from the inner portion 290 of the first transmission unit body.

A first magnetic force member 230 and a second magnetic force member 250 are formed on both sides of the first transmission unit body inner side 290 around the negative terminal 214 .

A first magnetic force projection 812 is formed on the first magnetic member 230 , and a second magnetic force projection 814 is formed on the second magnetic force member 250 .

The second transmission unit body 190 has a third magnetic force member 330 on the second transmission unit body inner side 310 in contact with the first transmission unit body inner side 290 when folded with the first transmission unit body 150 and The fourth magnetic member 350 and the terminal guide 820 formed between the third magnetic member 330 and the fourth magnetic member 350 are formed.

A third magnetic force groove 822 into which the second magnetic force protrusion 814 is introduced is formed in the third magnetic force member 330 , and the first magnetic force protrusion 812 is introduced into the fourth magnetic force member 350 . A fourth magnetic groove 824 is formed.

The formation positions of the second magnetic force projection 814 and the third magnetic force groove 822 may be opposite to each other, and the formation positions of the first magnetic force projection 812 and the fourth magnetic force groove 824 may also be opposite to each other. have.

When the first transfer unit body 150 and the second transfer unit body 190 are overlapped with each other, the first magnetic force member 230 is joined to the fourth magnetic force member 350 by magnetic force, and the first magnetic force protrusion ( 812) is inserted into the fourth magnetic force groove 824 to form a shape coupling structure in addition to the bonding force by magnetic force, and the second magnetic force member 250 is also joined to the third magnetic force member 330 by magnetic force and the second magnetic force member The two magnetic protrusions 814 are introduced into the third magnetic grooves 822 to form a geometrical coupling structure in addition to the coupling force due to magnetic force, thereby strengthening the coupling structure.

The terminal guide part 820 has two semi-circular arc-shaped terminal guide protrusions 826 and 828 facing each other, and is formed of an electrically conductive member.

In addition, the second transfer unit body 190 has a microcurrent amplifier 840 connected to the two terminal guide projections 826 and 828 of the terminal guide portion 820, respectively, and the microcurrent amplifier 840). A display unit 842 connected to is formed.

The first terminal guide protrusion 826 of the terminal guide protrusions 826 and 828 transfers a portion of the current transferred from the wrist guard 110 to the minus terminal 214 to the microcurrent amplifier 840, and the terminal Among the guide protrusions 826 and 828 , the second terminal guide protrusion 828 serves to transfer the current transmitted from the microcurrent amplifier 840 to the minus terminal 214 .

The microcurrent amplifying unit 840 is formed of a transistor that amplifies the microcurrent transmitted through the first terminal guide protrusion 826 .

The display unit 842 is formed of an element such as an LED that can be operated with the current amplified by the microcurrent amplifying unit 840, and serves to allow the user to recognize that the microcurrent is being operated.

In addition, the terminal guide portion 820 is positioned around the negative terminal 214 when the first transmission unit body 150 and the second transmission unit body 190 overlap with the negative terminal 214 is It acts to more accurately contact the wrist guard 110 .

The present invention is more stably fixed when the third modified example 700 of the microcurrent transmission unit is applied to the wrist guard 110 through the third modified example 700 of the microcurrent transmission unit, and the negative terminal 214 An effect of being able to accurately contact the wrist guard 110 is generated, and an effect of allowing the user to recognize that a micro-current is being operated through the display unit 842 is generated.

Although the embodiments of the present invention have been described as above, based on this, those of ordinary skill in the art can add components within the scope that does not depart from the essential technical spirit of the present invention described in the claims The present invention may be variously modified and changed by change, deletion or addition, and this is also included within the scope of the present invention.

100: protector device through which a microcurrent flows 110: wrist protector
130: micro-current transfer unit 150: first transfer unit body
170: connection member 172: concave portion
190: second transmission unit body 210: power terminal part
230: first magnetic member 250: second magnetic member
288: first transmission unit body outer portion 290: first transmission unit body inner portion
330: third magnetic member 350: fourth magnetic member
400: knee protector 500: ankle protector

Claims (6)

A protector formed of an electrically conductive fiber material,
It is detachably coupled to the guard and includes a micro-current transmission unit provided with a power terminal for generating micro-current,
When the microcurrent transfer unit is attached to the protector, the power terminal unit sends a microcurrent to the user's skin, and the microcurrent transmitted to the user's skin reaches the power terminal again through the protector,
The microcurrent transfer unit is
a first transmission unit body in which the power terminal part is installed;
a second transmission unit body formed symmetrically with the first transmission unit body and having a magnetic force member that can be contacted or separated from the first transmission unit body by magnetic force; and
and a connecting member connecting the first transfer unit body and the second transfer unit body,
A first terminal of the power terminal unit is formed to protrude on the outer side of the first transmission unit body,
A second terminal of the power terminal unit is formed to protrude on the inner side of the first transmission unit body,
A first magnetic force member and a second magnetic force member are formed on both sides of the first transmission unit body on both sides around the second terminal,
A third magnetic member and a fourth magnetic member are formed on the second transmission unit body,
When the first transfer unit body and the second transfer unit body overlap and the protector is positioned between the first transfer unit body and the second transfer unit body, the first magnetic force member and the fourth magnetic force member are separated by magnetic force is pulled, and when the second magnetic force member and the third magnetic force member are pulled by magnetic force, the second terminal is in contact with the surface of the protector through which a microcurrent flows.
The method according to claim 1,
The power terminal unit is formed of tourmaline components to generate a microcurrent in a non-charging manner.
delete 3. The method according to claim 2,
The micro-current transfer unit includes a fixing clip formed around the power terminal,
A concave groove is formed around the power terminal part,
The fixing clip part
a fixing part surrounding the periphery of the concave groove;
and a clip elastic part extending from the fixing part to be bent in a curved shape.
3. The method according to claim 2,
The micro-current transfer unit is
a transmission unit body in which the power terminal part is installed;
A guard device through which a microcurrent flows, characterized in that it includes a clamp member hingedly coupled to the transfer unit body.
delete

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