CN215227718U - Electrode plate connector and physiological data monitoring system - Google Patents

Abstract

The utility model provides an electrode slice connector (70) for electrocardio and/or breathing parameter measurement cable, includes frame main part (71) and sets up in the frame main part and first centre gripping piece (72) and second centre gripping piece (73) of relative setting, forms the centre gripping space (74) that is used for centre gripping electrode slice (80) jointly between first centre gripping piece (72) and second centre gripping piece (73), and frame main part (71) are held by the fingers and are made centre gripping space (74) increase with centre gripping or release be used for electrocardio and/or breathing parameter measurement cable electrode slice (80). A physiological data monitoring system (100) having an electrode patch connector (70) is also provided.

Description

Electrode plate connector and physiological data monitoring system

Technical Field

The application relates to the technical field of physiological parameter monitoring, in particular to an electrode plate connector for an electrocardiogram and/or respiration parameter measuring cable and a physiological data monitoring system with the electrode plate connector.

Background

In order to realize the collection of the physiological electric signals of the human body, the cable needs to be reliably electrically connected with the electrode plate stuck on the body of the patient, so that the physiological electric signals of the patient collected by the electrode plate are transmitted to the terminal equipment, and then the data is analyzed and processed to obtain the information for judging the state of an illness of the patient.

The electrode connectors commonly used at present are of two types, one type is a snap fastener type, a cavity on the snap fastener connector and an elastic metal wire in the cavity are matched with a male buckle structure of an electrode plate to realize the reliable connection of the electrode connector and an electrode, the front surface of the snap fastener needs to be pressed forcibly when the connector is assembled with the electrode, when the electrode plate is stuck on the body of a patient, the connector is assembled, so that the pain of the patient is easy to generate, especially the old and the infant, muscle or bone injury is easy to generate by the forcible pressing, and medical accidents are caused; the other type is a clamp type electrode connector which has a structure capable of being matched with an electrode plate, a torsion spring, a spring and the like are adopted to drive a clamp to open and close so that the clamp type electrode connector is matched with the electrode plate, and therefore the electrode connector is reliably connected with an electrode.

SUMMERY OF THE UTILITY MODEL

The embodiment of the application discloses an electrode plate connector for an electrocardiogram and/or respiration parameter measuring cable and a physiological data monitoring system, which aim to solve the problems.

The utility model discloses an electrode slice connector for electrocardio and/or breathing parameter measurement cable, including the frame main part with set up in first centre gripping piece and the second centre gripping piece that just relative setting in the frame main part, form the centre gripping space that is used for centre gripping electrode slice jointly between first centre gripping piece and the second centre gripping piece, the frame main part is held between the fingers and is makeed centre gripping space increases with centre gripping or release and be used for the electrode slice of electrocardio and/or breathing parameter measurement cable.

The embodiment of the application discloses a physiological data monitoring system, including parameter measurement cable, anti structure and at least three of defibrillating electrode slice connector, the one end of parameter measurement cable is used for connecting a wearable physiological parameter monitoring devices, parameter measurement cable is from being close to wearable physiological parameter monitoring devices's one end is to keeping away from wearable physiological parameter monitoring devices's one is served and is equipped with in proper order the cluster anti structure of defibrillating with at least three electrode slice connector, electrode slice connector is used for centre gripping electrode slice.

The utility model provides an electrode slice connector and physiological data monitoring system for electrocardio and/or breathing parameter measurement cable, electrode slice connector's outer frame main part is held between the fingers to be out of shape and makes by first centre gripping piece with the second centre gripping piece forms can realize the centre gripping of electrode slice or release when the centre gripping space increases, easy operation, and the portability is good.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a physiological data monitoring system according to an embodiment of the present application.

Fig. 2 is a schematic disassembled view of the physiological data monitoring system shown in fig. 1.

Fig. 3 is a schematic structural diagram of a wearable physiological parameter monitoring device according to an embodiment of the present application.

Fig. 4 is a schematic structural diagram of the wearable physiological parameter monitoring device in the first embodiment of the present application in another direction.

FIG. 5 is a schematic view of the wearable physiological parameter monitoring device of the first embodiment of the present application in a further orientation with the wristband removed.

Fig. 6 is a schematic structural diagram of a wrist band module of a wearable physiological parameter monitoring device according to a first embodiment of the present application.

Fig. 7 is a schematic view of a wearable physiological parameter monitoring device in a second embodiment of the present application, showing a structure in one direction.

Fig. 8 is a schematic structural view of a wearable physiological parameter monitoring device in another direction according to a second embodiment of the present application.

Fig. 9 is a schematic structural view of an electrode sheet connector in the first embodiment of the present application.

Fig. 10 is a schematic structural view of an electrode sheet connector in a second embodiment of the present application.

Fig. 11 is a schematic structural view of an electrode sheet connector in a third embodiment of the present application.

Fig. 12 is a schematic structural view of an electrode sheet connector in a fourth embodiment of the present application.

Fig. 13 is a schematic structural view of an electrode sheet connector in a fifth embodiment of the present application.

Fig. 14 is a schematic structural view of an electrode sheet connector in a sixth embodiment of the present application.

Fig. 15 is a schematic structural diagram of an electrode sheet connector according to another embodiment of the present application.

Fig. 16 is a schematic structural diagram of an electrode sheet connector according to still another embodiment of the present application.

Fig. 17 is a schematic structural view of an electrode sheet connector in a seventh embodiment of the present application.

Fig. 18 is a schematic structural view of an electrode sheet connector in an eighth embodiment of the present application.

Fig. 19 is a schematic structural view of an electrode sheet connector in a ninth embodiment of the present application.

Fig. 20 is a schematic structural view of an electrode sheet connector in a tenth embodiment of the present application.

Fig. 21 is a schematic structural view of an electrode sheet connector in an eleventh embodiment of the present application.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

The terms "first," "second," and the like in the description and claims of the present application and in the above-described drawings are used for distinguishing between different objects and not for describing a particular order. Furthermore, the terms "comprises" and any variations thereof, are intended to cover non-exclusive inclusions. For example, a process, method, system, article, or apparatus that comprises a list of steps or elements is not limited to only those steps or elements listed, but may alternatively include other steps or elements not listed, or inherent to such process, method, article, or apparatus.

While the specification concludes with claims describing preferred embodiments of the present application, it is to be understood that the above description is made only for the purpose of illustrating the general principles of the present application and is not intended to limit the scope of the present application. The protection scope of the present application shall be subject to the definitions of the appended claims.

Referring to fig. 1, fig. 1 is a schematic structural diagram of a physiological data monitoring system 100 according to an embodiment of the present application. The physiological data monitoring system 100 includes a wearable physiological parameter monitoring device 10, a parameter measurement cable 30, an anti-defibrillation structure 50, at least three electrode patch connectors 70, and a blood oxygen probe 90.

The wearable physiological parameter monitoring device 10 is connected to one end of the parameter measuring cable 30. The anti-defibrillation structure 50 and the at least three electrode pad connectors 70 are sequentially connected in series to the parameter measurement cable 30 from the end close to the wearable physiological parameter monitoring device 10 to the end far from the wearable physiological parameter monitoring device 10. The electrode pad connector 70 is used to clamp the electrode pad 80. Further, in some variations, the parameter measurement cable 30 may be a single cable structure, in which the defibrillation-resistant structure 50 and the at least three electrode pad connectors 70 are serially connected to form a single parameter measurement cable, or a bifurcated cable structure. If the parameter measurement cable 30 has a bifurcated cable structure, the parameter measurement cable 30 includes a main portion and at least three bifurcated portions, one end of the main portion is connected to the wearable physiological parameter monitoring device 10, the other end of the main portion is connected to the at least three bifurcated portions, each bifurcated portion is provided with at least one electrode connector 70, and the defibrillation-resistant structure 50 is disposed at any position on the main portion. The wearable physiological parameter monitoring device 10 is also electrically connected with the blood oxygen probe 90.

In particular, the wearable physiological parameter monitoring device 10 is used for monitoring physiological data signals of a patient by being worn on the wrist of the patient. Each electrode pad connector 70 is adapted to hold an electrode pad 80, and each electrode pad 80 is adapted to be attached to a site on the patient's body to measure a physiological data signal or impedance signal at the site. The anti-defibrillation structure 50 houses a defibrillation protection circuit for protecting the ECG detection system from damage when defibrillation is performed on the patient's heart to restore normal heartbeat if necessary. In this application, the above-mentioned anti-defibrillation structure 50 sets up independently with the above-mentioned wearable physiological parameter monitoring device 10 for the volume of the above-mentioned wearable physiological parameter monitoring device 10 reduces, and portable has also avoided exerting the strong current of the above-mentioned anti-defibrillation structure 50 to cause the interference to the signal in the above-mentioned wearable physiological parameter monitoring device 10 simultaneously.

Referring to fig. 2, in order to fix the physiological data monitoring system 100 on the body of the patient, the physiological data monitoring system 100 is divided into two parts which are detachably connected, specifically, the anti-defibrillation structure 50 is divided into a first defibrillation part 51 and a second defibrillation part 53. The first defibrillation unit 51 and the second defibrillation unit 53 are connected to each other to form the anti-defibrillation structure 50 having a defibrillation function. In this embodiment, the first defibrillation unit 51 and the second defibrillation unit 53 are connected to each other by plugging. The first defibrillation section 51 is also connected to the wearable physiological parameter monitoring device 10 via the parameter measurement cable 30. The second defibrillation unit 53 is also connected to the at least three electrode pad connectors 70 via the parameter measurement cable 30. In an application scenario, when the wearable physiological parameter monitoring device 10 is mounted on the wrist of a patient, the parameter measuring cable 30 and the first defibrillation part 51 connected with the wearable physiological parameter monitoring device 10 are threaded from the inside of the sleeve of the patient to the neck of the patient, and when at least three electrode pad connectors 70 respectively clamp the electrode pads 80 and are attached to the designated parts of the body of the patient, the parameter measuring cable 30 and the second defibrillation part 53 connected with the at least three electrode pad connectors 70 are threaded from the inside of the clothes of the patient to the neck of the patient, and are connected with the first defibrillation part 51, and then the anti-defibrillation structure 50 is clamped on the collar of the patient through the clips arranged on the first defibrillation part 51 and/or the second defibrillation part 53.

Referring to fig. 3, the wearable physiological parameter monitoring device 10 includes a host 11. The host 11 includes a host housing 111 and a control module 113 disposed in the host housing 111. The host 11 further includes a connector 115. The control module 113 is connected to the parameter measurement cable 30 through the connector 115. Thus, the control module 113 can be electrically connected to the external anti-defibrillation structure 50 through the parameter measurement cable 30.

Specifically, the host 11 further includes an ear portion 117. The ear part 117 is provided at a side of the main chassis 111. In the first embodiment, the connector 115 is provided in the ear portion 117.

More specifically, the ear part 117 is provided at a side of one end of the main chassis 111. The control module 113 is disposed at one end of the main housing 311 adjacent to the ear portion 117. The wearable physiological parameter monitoring device 10 further includes a battery 119. The battery 119 is disposed at an end of the main housing 111 away from the ear portion 117. The battery 119 is electrically connected to the control module 113.

More specifically, the ear portion 117 includes a first ear portion 1171 and a second ear portion 1173. The first ear portion 1171 and the second ear portion 1173 are respectively disposed at both sides of the main chassis 111. The above-described connector 115 includes a first connector 1151 and a second connector 1153. The first connector 1151 is disposed in the first ear portion 1171 and is connected to the control module 113 and the blood oxygen probe 90. The second connector 1153 is disposed in the second ear portion 1173 and is connected to both the control module 113 and the parameter measurement cable 30.

More specifically, the first ear portion 1171 is provided with a first connection port 1175. The first connector 1175 is connected to the first connector 1151. Thus, the first connector 1151 is connected to the blood oxygen probe 90 through the first connector 1175.

More specifically, referring to fig. 4, the second ear portion 1173 is provided with a second connection port 1177. The second connection port 1177 is connected to the second connector 1153. Accordingly, the second connector 1153 is connected to the parameter measurement cable 30 through the second connection port 1177.

More specifically, for convenience of insertion, the first connection port 1175 is located on a side of the first ear portion 1171 close to the bottom end of the main chassis 111, and the second connection port 1177 is located on a side of the second ear portion 1173 close to the top end of the main chassis 111.

Referring to fig. 5, the wearable physiological parameter monitoring device 10 further includes a wrist strap module 13. Fig. 5 is a schematic view showing only a part of the structure of the wristband module 13 in the first embodiment. The wrist band module 13 is disposed at one side of the main body 11. The wrist strap module 13 is used to fix the host 11 to the wrist of the patient.

Please refer to fig. 6, which is a schematic structural diagram of the wristband module 13 according to the first embodiment of the present application. The wrist band module 13 may include a holder 131, or the wrist band module 13 may include a wrist band 133. The fixing frame 131 is disposed at one side of the main body 11. The fixing bracket 131 fixes the battery 119 to the main chassis 111. The wrist band 133 is disposed on a side of the fixing frame 131 away from the main body 11. The wrist band 133 is used to fix the main body 11 to the wrist of the patient.

Specifically, in some embodiments, the main chassis 111 has a closed cavity therein for accommodating the control module 113. The battery 119 is disposed on the outer wall of the main chassis 111 and outside the enclosed cavity of the main chassis 111; the battery 119 is held between the main unit 10 and the holder 131 by connecting the holder 131 to the main unit case 111. The battery 119 is detachably fixed on the host 11 through the fixing frame 131, so that the battery can be conveniently detached and installed, and is very convenient.

Specifically, a guide groove 1313 is provided on a side of the fixing frame 131 facing the main body 11. The guide groove 1313 is used to guide the host computer 11 to be mounted on the fixing frame 131. At least one through hole 1311 is symmetrically formed on one side of the fixing frame 131, which is away from the main body 11. The wrist band 133 is fixed to the holder 131 through the at least one through hole 1311. Preferably, the wrist band 133 is a flexible wrist band. The wrist band 133 may be, but not limited to, a silicone tape, a cloth tape, etc.

The wristband module 13 further includes a flexible rubber pad 135. The flexible rubber pad 135 is disposed on a side of the wrist band 133 away from the fixing frame 131. The flexible cushion 135 is adapted to directly contact the skin of the patient to protect the patient's skin.

Please refer to fig. 7 and fig. 8 together, which are schematic structural views of the wearable physiological parameter monitoring device 10a according to the second embodiment of the present application. The wrist band module 13a of the wearable physiological parameter monitoring device 10a is different from the wrist band module 13 in that the wrist band module 13a is integrally provided with the main body 11. The wristband module 13a is directly extended vertically from the ear 117 of the host 11. The first connector 1151 and the second connector 1153 are respectively provided in the wrist band module 13 a.

Specifically, the wristband module 13a includes two wristbands 133 a. The two wrist bands 133a are vertically extended from the first ear portion 1171 and the second ear portion 1173 of the main body 11, and then fastened or adhered to each other to form a ring-shaped band, so that the main body 11 can be fixed to the wrist of the patient.

More specifically, in this embodiment, the first connector 1151 is disposed on a wristband 133a extending from the first ear portion 1171. The second connector 1153 is provided to the wristband 133a extending from the second ear portion 1173. The wristband 133a extending from the first ear portion 1171 is further provided with a first connector 1331 a. The first connector 1331a is connected to the first connector 1151, so that the first connector 1151 is connected to the blood oxygen probe 90 through the first connector 1331 a. The cuff 133a extending from the second ear portion 1173 is also provided with a second connection port 1333 a. The second connection port 1333a is connected to the second connector 1153, and thus the second connector 1153 is connected to the parameter measurement cable 30 through the second connection port 1333 a.

More specifically, the first connection port 1331a is located at a bottom end of the wrist band 133a close to the main body 11, and the second connection port 1333a is located at a top end of the wrist band 133a close to the main body 11.

Referring to fig. 9, fig. 9 is a schematic structural diagram of an electrode tab connector 70 according to a first embodiment of the present application, in which the electrode tab connector 70 is mainly used for an ecg/respiratory parameter measurement cable, the electrode tab connector 70 includes an outer frame body 71 and two clamping tabs disposed inside the outer frame body 71, and the outer frame body 71 is used for connecting with the parameter measurement cable 30. The two clamping pieces are used for clamping the electrocardio-electrode piece 80. Specifically, the electrode tab connector 70 includes an outer frame body 71, and a first clamping piece 72 and a second clamping piece 73 which are disposed in the outer frame body 71 and are opposite to each other. The first clamping piece 72 and the second clamping piece 73 together form a clamping space 74 for clamping the electrode sheet 80. The outer frame body 71 is pinched so that the pinching space 74 is enlarged to pinch or release the electrode sheet 80. Specifically, the outer frame main body 71 is pinched such that the clamping space 74 is increased to allow the electrode tab 80 to be placed into the clamping space 74, and the clamping space 74 is decreased due to the elastic restoring force of the outer frame main body 71 to clamp the electrode tab 80 when pinching of the outer frame main body 71 is stopped. When the electrode sheet 80 needs to be removed from the holding space 74, the outer frame body 71 is held again so that the holding space 74 is enlarged to release the electrode sheet 80 for the measurement of the electrocardiographic and/or respiratory parameters. In some embodiments, the force applied to the outer frame body 71 when the outer frame body 71 is pinched is perpendicular to or opposite to the deformation direction of the clamping space 74, and the following detailed description will be given with respect to specific embodiments.

Specifically, at least one of the first and second clamping pieces 72 and 73 is made of a conductive material to be electrically connected to the parameter measurement cable 30.

Specifically, in one embodiment, the electrode sheet 80 is a disposable electrode sheet. In another embodiment, the electrode pad 80 is a disposable electrocardioelectrode pad.

Specifically, the outer frame body 71 is made of a flexible material. In one embodiment, the outer frame body 71 has an outer circumference of one of a circular shape, an oval shape and a waist shape, similar to a square ring structure. The inner circumference of the outer frame body 71 is formed in one of a circular shape, an oval shape, and a waist shape. For example, as shown in fig. 9, 10, and 14 to 19, the outer side and the inner side of the outer frame main body 71 are waist-shaped. As shown in fig. 11, the outer side of the outer frame body 71 is a horizontal oval shape, and the inner side is a circular shape. As shown in fig. 12, the outer side and the inner side of the outer frame body 71 are both horizontally elliptical. As shown in fig. 13, the outer side and the inner side of the outer frame body 71 are vertically elliptical. It is understood that, in other embodiments, the outer side and the inner side of the outer frame main body 71 may also have other suitable shapes, and are not limited herein. The longest line segment that passes through the center on the longitudinal section of the outer frame main body 71 and ends at the edge of the longitudinal section is the major axis of the outer frame main body 71, and the shortest line segment that passes through the center on the longitudinal section of the outer frame main body 71 and ends at the edge of the longitudinal section is the minor axis of the outer frame main body 71.

Specifically, referring to fig. 9 again, the outer frame body 71 includes a first side wall 711 and a second side wall 712 disposed opposite to each other. The outer frame body 71 further includes a first connecting wall 713 and a second connecting wall 714 which are oppositely disposed. The first connecting wall 713 is connected to one end of the first side wall 711 and the second side wall 712. The second connecting wall 714 is connected to the other ends of the first side wall 711 and the second side wall 712 to form a ring-shaped outer frame body 71. The first side wall 711, the first connecting wall 713, the second side wall 712, and the second connecting wall 714 are corresponding structures as indicated by reference numerals in the drawings, and the mouth-shaped outer frame body 71 defined by the first side wall 711, the first connecting wall 713, the second side wall 712, and the second connecting wall 714 may be divided into two parts, namely, a first side part and a second side part. The outer frame body 71 has a first side portion and a second side portion which are disposed opposite to each other, and the two holding pieces are disposed on opposite sides of the first side portion and the second side portion, respectively. The two clamping pieces are oppositely arranged to form a containing space (namely, a clamping space 74). The storage space (i.e., the holding space 74) is used for storing and holding the electrocardiograph electrode sheet 80. When the outer frame body 71 is pinched and the distance between the first side portion and the second side portion is reduced, the receiving space is increased to release the electrocardiograph pads 80.

Specifically, the outer frame body 71 includes a first suspending arm 75 and a second suspending arm 76 extending from the first side wall 711 and the second side wall 712, respectively. The first holding piece 72 is provided at a side of the distal end of the first cantilever 75 facing the second cantilever 76. The second holding piece 73 is provided at a side of the distal end of the second arm 76 facing the first arm 75. The first and second clamping pieces 72 and 73 form the above-described clamping space 74 therebetween. When the first side wall 711 and the second side wall 712 are pinched and the outer frame body 71 is deformed, the pinching space 74 formed between the first pinching piece 72 and the second pinching piece 73 is increased to pinch or release the electrode sheet 80.

For convenience of description, the first direction 200 and the second direction 300 are specifically defined. The first direction 200 is a direction from the first connecting wall 713 to the second connecting wall 714. The second direction 300 is a direction from the first sidewall 711 to the second sidewall 712. The first direction 200 and the second direction 300 are perpendicular to each other.

Specifically, the first arm 75 and the second arm 76 each have an L shape. The first arm 75 includes a first arm 751 and a first bent portion 753 provided at a free end of the first arm 751. The first bending portion 753 has a half-moon shape. The second suspension 76 includes a second arm portion 761 and a second bent portion 763 provided at a free end of the second arm portion 761. The second bending portion 763 is substantially half-moon shaped. The first arm 751 and the second arm 761 are spaced apart from each other in the first direction 200, and their projected portions in the second direction 300 overlap each other. The first bent portion 753 is bent from the end of the first arm 751 and extends toward the second arm 761. The second bent portion 763 is bent from the end of the second arm 761 and extends toward the first arm 751. The first clamping piece 72 is disposed on a side of the first bent portion 753 facing the second bent portion 763. The second clamping piece 73 is disposed on a side of the second bent portion 763 facing the first bent portion 753. The first bent portion 753 and the second bent portion 763 form the holding space 74 therebetween.

Specifically, in the present embodiment, the opposite ends of the first clamping piece 72 and the second clamping piece 73 are half-moon-shaped, and the arc radii of the half-moon-shapes are equal. The clamping space 74 formed between the first clamping piece 72 and the second clamping piece 73 is thus circular. The shapes of the end portions of the first holding piece 72 and the second holding piece 73 in the present application refer to shapes in which the first holding piece 72 and the second holding piece 73 are projected in a direction perpendicular to the extending direction thereof.

Optionally, a notch 7111 is disposed on the first side wall 711. The gap 7111 is located between the first cantilever 75 and the first connecting wall 713. A projection 7113 is provided on a side of the first suspension 75 facing the first side wall 711. When the outer frame body 71 is in a natural state, the protrusion 7113 has a movable gap from the first sidewall 711 in the first direction 200. In one embodiment, the dimension of the protrusion 7113 in the first direction 200 is a half of the distance between the first arm 751 and the first connecting wall 713 in a natural state. When the first side wall 711 and the second side wall 712 are pinched such that the distance therebetween is reduced, the projection 7113 prevents the first side wall 711 and the second side wall 712 from being deformed too much.

Alternatively, the first connecting wall 713 and the second connecting wall 714 may be provided at outer sides thereof with connecting posts 715, respectively. Each connecting post 715 is used for electrical connection with the parameter measurement cable 30. Specifically, at least one of the first and second clamping pieces 72 and 73 is electrically connected to the parameter measuring cable 30 through the connection post 715.

In some of the modified embodiments, as in each of fig. 9, 10, 13, 14 and 15, the two clamping pieces may each have an L shape, and an O-shaped receiving space (i.e., a clamping space 74) is formed between the two clamping pieces.

Referring to fig. 10, fig. 10 is a schematic structural diagram of an electrode sheet connector 70a in a second embodiment of the present application. Unlike the first embodiment, in the second embodiment, the outer and inner sides of the outer frame body 71 of the electrode pad connector 70b are waist-shaped, and the electrode pad connector 70a further includes a third clamping piece 77. The third clamping piece 77 is disposed on the side of the first arm 751 facing the second arm 761, the third clamping piece 77 is located between the first bent portion 753 and the second bent portion 763, and the first clamping piece 72, the second clamping piece 73, and the third clamping piece 77 together form the clamping space 74.

Further, in the present embodiment, the first clamping piece 72, the second clamping piece 73 and the third clamping piece 77 are half-moon-shaped, and the arc radii of the half-moon-shaped are equal. The clamping space 74 formed between the first, second and third clamping pieces 72, 73 and 77 is substantially circular.

Referring to fig. 11, fig. 11 is a schematic structural diagram of an electrode plate connector 70b in a third embodiment of the present application. Unlike the first embodiment, in the third embodiment, the outer side of the outer frame body 71 of the electrode tab connector 70b is formed in a horizontal oval shape, and the inner side is formed in a circular shape. The first and second cantilevers 75b and 76b of the electrode pad connector 70b are in a straight shape. The first arm 75b and the second arm 76b are disposed to be opposed to each other at a distance and are aligned in the second direction 300. The first and second holding pieces 72 and 73 are provided at opposite ends of the first and second cantilevers 75b and 76b, respectively. The opposite sides of the first side wall 711 and the second side wall 712 are respectively formed with a grip 78. When the two nipping portions 78 are nipped such that the first and second connecting walls 713 and 714 are arcuate in the second direction 300 and the distance between the nipping portions 78 of the first and second side walls 711 and 712 is reduced, the first and second nipping pieces 72 and 73 are spaced apart from each other such that the nip space 74 formed by the first and second nipping pieces 72 and 73 is increased to nip or release the electrode tab 80.

Specifically, in the present embodiment, the first clamping piece 72 and the second clamping piece 73 are half-moon-shaped, and the arc radii of the half-moon-shapes are equal. The clamping space 74 formed between the first clamping piece 72 and the second clamping piece 73 is thus substantially circular.

Further, in the present embodiment, the holding portion 78 is stepped to facilitate the user to hold. The first arm 75b, the second arm 76b, and the two holding portions 78 are located on the long axis of the outer frame body 71.

Referring to fig. 12, fig. 12 is a schematic structural view of an electrode plate connector 70c according to a fourth embodiment of the present application. Unlike the third embodiment, in the fourth embodiment, both the outer side and the inner side of the outer frame body 71 of the electrode tab connector 70c are horizontally elliptical, the outer frame body 71 includes a first cantilever 75c and a second cantilever 76c extending from the first connection wall 713 and the second connection wall 714, respectively, the first cantilever 75c and the second cantilever 76c are in a straight shape, the first cantilever 75c and the second cantilever 76c are disposed opposite to each other at an interval, and the first cantilever 75c, the second cantilever 76c and the two connection posts are located on the same straight line 715 in the first direction 200. The first and second holding pieces 72 and 73 are provided at opposite ends of the first and second cantilevers 75c and 76c, respectively. When the first and second side walls 711 and 712 are pinched and deformed, the first and second pinching pieces 72 and 73 are separated from each other, so that the pinching space 74 is increased, and the electrode sheet 80 is pinched or released.

Specifically, in the present embodiment, the first cantilever 75c and the second cantilever 76c are located on the short axis of the outer frame body 71.

Specifically, in the present embodiment, the first clamping piece 72 and the second clamping piece 73 are half-moon-shaped, and the arc radii of the half-moon-shapes are equal. The clamping space 74 formed between the first clamping piece 72 and the second clamping piece 73 is thus substantially circular.

Referring to fig. 13, fig. 13 is a schematic structural diagram of an electrode plate connector 70d according to a fifth embodiment of the present application. Unlike the first embodiment, in the fifth embodiment, both the outer side and the inner side of the outer frame main body 71 of the electrode tab connector 70d are vertically oval. The first and second clamping pieces 72d and 73d of the electrode tab connector 70d are respectively extended from the first and second side walls 711 and 712 to be in an L shape, and the clamping space 74 is formed between the ends of the first and second clamping pieces 72d and 73 d.

Specifically, the first clamping piece 72d includes a first clamping body 721 and a first clamping portion 723 provided at a free end of the first clamping body 721. Wherein the first clamping portion 723 is substantially half moon shaped. The second clamping piece 73d includes a second clamping body 731 and a second clamping portion 733 provided at a free end of the second clamping body 731. The second clamping portion 733 has a half-moon shape. The first and second clamping bodies 721 and 731 are spaced apart from each other in the first direction 200, and their projected portions in the second direction 300 overlap each other. The first clamping portion 723 is bent from the end of the first clamping body 721 and extends toward the second clamping body 731. The second clamping portion 733 is bent from the end of the second clamping body 731 and extends toward the first clamping body 721. Accordingly, the clamping space 74 is formed between the first clamping portion 723 and the second clamping portion 733. The first and second side walls 711 and 712 are pinch-deformed such that the clamping space 74 formed between the first and second clamping pieces 72d and 73d is increased to clamp or release the electrode sheet 80. Further, the first holding piece 72d and the second holding piece 73d are made of a conductive material, such as copper.

Referring to fig. 14, fig. 14 is a schematic structural view of an electrode plate connector 70e in a sixth embodiment of the present application. Unlike the fifth embodiment, in the sixth embodiment, both the outside and the inside of the outer frame body 71 of the electrode tab connector 70e are waist-shaped. The electrode pad connector 70e further includes a first cantilever 75e and a second cantilever 76 e. The first arm 75e extends from the first side wall 711 toward the second side wall 712, is located on a side of the first holding piece 72e away from the second holding piece 73e, and is connected to the first holding piece 72 e. The first cantilever 75e assists in supporting the first clamping piece 72 e. Accordingly, the first clamping piece 72e has better clamping strength under the auxiliary support of the first cantilever 75 e. The second suspending arm 76e extends from the second side wall 712 toward the first side wall 711, is located on a side of the second holding piece 73 away from the first holding piece 72, and is connected to the second holding piece 73 e. The second cantilever 76e assists in supporting the second holding piece 73 e. Accordingly, the second clamping piece 73e has better clamping strength under the auxiliary support of the second cantilever 76 e.

As shown, the first cantilever 75e and the first clamping piece 72e form a step-like clamping piece structure. The second cantilever 76e and the second clamping piece 73e form a stepped clamping piece structure. The electrocardioelectrode plate 80 is correspondingly provided with an inverted step. Thus, when the ECG electrode pads 80 are clamped by the clamping pad structures, the inverted steps of the ECG electrode pads 80 are engaged with the steps of the clamping pad structures, so that the ECG electrode pads 80 are stably clamped between the two clamping pads.

Specifically, the electrode sheet connector 70e further includes connection posts 715 disposed at both ends of the outer side of the outer frame body 71. The connecting post 715 is used to connect to the parameter measurement cable 30.

Referring to fig. 15, fig. 15 is a schematic structural diagram of an electrode plate connector 70k according to another embodiment of the present application. The electrode tab connector 70k is different from the electrode tab connector 70e in that the first arm 75k has a shape corresponding to the shape of the first holding piece 72e, and is also substantially L-shaped, and specifically includes a straight wall and a bent portion. The second arm 76k is shaped to fit the second holding piece 73e, and is substantially L-shaped, and includes a straight wall and a bent part

Referring to fig. 16, fig. 16 is a schematic structural diagram of an electrode plate connector 70m according to another embodiment of the present application. Unlike the electrode pad connector 70k, the electrode pad connector 70m has only one connection post 715. It is understood that the number of the connection posts 715 may be one if only one end of the electrode pad connector 70m is required to be connected to the parameter measuring cable 30.

Referring to fig. 17, fig. 17 is a schematic structural view of an electrode plate connector 70f in a seventh embodiment of the present application. Unlike the fifth embodiment, in the seventh embodiment, both the outside and the inside of the outer frame body 71 of the electrode tab connector 70f are waist-shaped. The electrode tab connector 70f includes a first clamping piece 72f and an arcuate arm 725f connecting the first clamping piece 72f and the second side wall 712, thereby allowing the first clamping piece 72 to have a better clamping strength.

Specifically, the first clamping piece 72f is a sheet-shaped piece, and a clamping notch 727 for clamping the electrode sheet 80 and a relief notch 729 for relieving from the second clamping piece 73f are formed on a side facing the second clamping piece 73 f. Wherein, the holding gap 727 is communicated with the abdicating gap 729, and the holding gap 727 is approximately semicircular. The second holding piece 73f has an L-shape. The second clamping piece 73f includes a second clamping body 731 and a second clamping portion 733 provided at a free end of the second clamping body 731. The second clamping portion 733 is located in the receding notch 729 and forms the clamping space 74 together with the clamping notch 727, for fixedly clamping the electrode sheet 80.

Optionally, the electrode pad connector 70 further includes a connection arm 726f connecting the arcuate arm 725f and the second side wall 712.

Accordingly, when the first side wall 711 and the second side wall 712 are pinch-deformed, the arcuate arm 725f is also deformed to move the first clamping piece 72f and the second clamping piece 73f away from each other, so that the clamping space 74 formed by the first clamping piece 72f and the second clamping piece 73f is enlarged, and the electrode sheet 80 clamped and fixed is released.

Alternatively, the first sidewall 711 may be provided with a pressing slip prevention groove 7115 f. The pressing skidproof pattern 7115f can be, but is not limited to, one or a combination of a convex strip, a convex point and a concave groove, and is used for skidproof function when the first side wall 711 and the second side wall 713 are pinched. The press slip-preventing pattern 7115f is also applicable to other embodiments.

Referring to fig. 18, fig. 18 is a schematic structural view of an electrode sheet connector 70g in an eighth embodiment of the present application. Unlike the seventh embodiment, in the eighth embodiment, the first and second clamping pieces 72g and 73g of the electrode tab connector 70g protrude from the first and second side walls 711 and 712, respectively, to face each other and overlap each other. The first holding piece 72g and the second holding piece 73g are respectively in the shape of a sheet. The first clamping piece 72g is provided with a first clamping hole 721 g. The second clamping piece 73g is provided with a second clamping hole 731 g. When the outer frame body 71 is in a natural state, only a part of the areas of the first holding holes 721g and the second holding holes 731g overlap, and a gap where the first holding holes 721g and the second holding holes 731g are staggered is a holding space 74 for fixedly holding the electrode sheet 80. The first and second side walls 711 and 712 are held such that the first and second clamping pieces 72g and 73g move toward each other until the first and second clamping holes 721g and 731g overlap, thereby releasing the electrode tab 80.

Specifically, in the present embodiment, the first holding hole 721g is a horseshoe-shaped hole. The second clamping hole 731g is a circular hole. When the outer frame body 71 is in a natural state and only a part of the areas of the first holding hole 721g and the second holding hole 731g overlap each other, the overlapping area between the first holding hole 721g and the second holding hole 731g is circular.

Alternatively, the electrode pad connector 70g further includes a first fixing block 725g disposed on the first sidewall 711 for fixing the first clamping piece 72 g. Further, in one embodiment, the number of the first fixing blocks 725g is two, and the two fixing blocks are respectively located at two sides of the first clamping piece 72 g. Accordingly, the auxiliary fixing of the first clamping piece 72g is achieved by the two first fixing blocks 725 g.

Further, the electrode pad connector 70g further includes a first guide strip 727g disposed on the first sidewall 711 for guiding the first clamping piece 72 g. Further, in one embodiment, the first guide strips 727g are two and are respectively located at two sides of the first clamping piece 72 g. Accordingly, the auxiliary guide of the first clamping pieces 72g is achieved by the two first guide strips 727 g.

Further, the first guide 727g is located at a side of the first fixing block 725g away from the first clamping piece 72 g. Therefore, the arrangement between the two first guide strips 727g and the two first fixing blocks 725g is more reasonable, and the fixing and supporting effects are better.

Further, the length of the first guide strip 727g is adapted to the length of the first clamping body 721 g.

Alternatively, the electrode pad connector 70g further includes a second fixing block 735g disposed on the second sidewall 712 and fixing the second clamping piece 73 g. Further, the number of the second fixing blocks 735g is two, and the two fixing blocks are respectively located at two sides of the second clamping piece 73 g. Accordingly, the auxiliary fixing of the second clamping piece 73g is achieved by the two second fixing blocks 735 g.

Further, in the eighth embodiment, the electrode tab connector 70g further includes a pressing anti-slip pattern 7131g provided on the second sidewall 713, for anti-slip function when the first sidewall 711 and the second sidewall 713 are pinched.

Referring to fig. 19, fig. 19 is a schematic structural view of an electrode plate connector 70h in a ninth embodiment of the present application. Unlike the eighth embodiment, in the ninth embodiment, the electrode pad connector 70h further includes a first arcuate arm 723h connecting the first clamping piece 72g and the second side wall 712. Alternatively, the electrode pad connector 70h further includes a second arcuate arm (not shown) connecting the second clamping pad 73g and the first sidewall 711.

Unlike the eighth embodiment, in the ninth embodiment, the two first guide bars 727g are omitted, and the electrode tab connector 70h further includes a second guide bar 737h provided at the second side wall 712 to guide the second clamping piece 73 g. Further, two second guide bars 737h are provided and are respectively disposed at both sides of the second clamping piece 73 g.

Further, the second guide bar 737h is positioned at a side of the second fixing block 735g away from the second clamping piece 73 g.

Further, in this embodiment, the length of the second guide bar 737h is adapted to the length of the second clamping body 731 g.

Further, in the ninth embodiment, the first side wall 711 of the electrode tab connector 70h is provided with a pressing anti-slip pattern 7115h for anti-slip function when the first side wall 711 and the second side wall 713 are pinched.

Referring to fig. 20, fig. 20 is a schematic structural view of an electrode plate connector 70i in a tenth embodiment of the present application. Unlike the ninth embodiment, in the tenth embodiment, the notch 7111i is provided at the junction of the first side wall 711 and the first connecting wall 713, so that the pinching force for deforming the first side wall 711 and the second side wall 713 is made smaller by pinching, and the operation of clamping and releasing the electrode sheet 80 is made easier.

Referring to fig. 21, fig. 21 is a schematic structural diagram of an electrode plate connector 70j according to an eleventh embodiment of the present application. Unlike the first embodiment, in the eleventh embodiment, the electrode pad connector 70j includes two parallel first cantilevers 75j extending from the first side wall 711, and one second cantilever 76j extending from the second side wall 712. The second suspension arm 76j is located between the two first suspension arms 75j in the first direction 200. The first engaging portions 751j are provided on the sides of the two first arms 75j facing each other. The second fitting portion 761j is provided on each side of the end of the second cantilever 76 j. Each first mating portion 751j is disposed in mating relation with a corresponding second mating portion 761 j. The first and second holding pieces 72 and 73 are respectively provided on opposite sides of the two first cantilevers 75 j.

Specifically, the first mating portion 751j and the second mating portion 761j are mating slopes, respectively. The first and second sidewalls 711 and 713 are pinched so that the second engaging portion 761j moves along the engaging slope to increase the distance between the first and second clamping pieces 72 and 73, thereby clamping or releasing the electrode sheet 80.

Specifically, the first holding piece 72 and the second holding piece 73 are respectively half-moon shaped.

Alternatively, a notch 7131j is provided at a position where the first connecting wall 713 and the second connecting wall 712 meet, so that a pinching force for deforming the first connecting wall 711 and the second connecting wall 713 by pinching is smaller, and an operation of pinching and releasing the electrode sheet 80 is easier.

The utility model provides an electrode slice connector and physiological data monitoring system, electrode slice connector include the frame main part with set up in first holding piece and the second holding piece that just set up relatively in the frame main part, form the centre gripping space that is used for the centre gripping electrode slice jointly between first holding piece and the second holding piece, the frame main part is held between the fingers and is makeed the centre gripping space increase is with centre gripping or release electrode slice, easy operation, and the portability is good. The anti-defibrillation structure is independent of the wearable physiological parameter monitoring device, the high current of the anti-defibrillation structure cannot influence the function of the wearable physiological parameter monitoring device, and the wearable physiological parameter monitoring device can be thinner and is better in portability.

In addition, in order to fix the physiological data monitoring system on the body of the patient conveniently, the physiological data monitoring system is divided into two parts which can be spliced together, namely, the anti-defibrillation structure is divided into a first defibrillation part and a second defibrillation part. The first defibrillation part and the second defibrillation part are connected with each other to form an anti-defibrillation structure with a defibrillation function. The first defibrillation part is also connected with the wearable physiological parameter monitoring device through a parameter measurement cable. The second defibrillation part is also connected with at least three electrode plate connectors through a parameter measurement cable, so that the operation is simpler.

In the above embodiments, the descriptions of the respective embodiments have respective emphasis, and for parts that are not described in detail in a certain embodiment, reference may be made to related descriptions of other embodiments.

The foregoing detailed description of the embodiments of the present application has been presented to illustrate the principles and embodiments of the present application, and the above description of the embodiments is only provided to help understand the method and the core concept of the present application; meanwhile, for a person skilled in the art, according to the idea of the present application, there may be variations in the specific embodiments and the application scope, and in summary, the content of the present specification should not be construed as a limitation to the present application.

Claims (20)

1. The utility model provides an electrode slice connector for electrocardio and/or breathing parameter measurement cable, includes the frame main part and set up in the frame main part and relative first centre gripping piece and the second centre gripping piece that sets up, form the centre gripping space that is used for centre gripping electrode slice jointly between first centre gripping piece and the second centre gripping piece, the frame main part makes when being held by the fingers the centre gripping space increase with centre gripping or release be used for the measuring electrode slice of electrocardio and/or breathing parameter, the frame main part includes relative first lateral wall and the second lateral wall that sets up, first centre gripping piece and the second centre gripping piece is followed respectively first lateral wall and the second lateral wall is gone up and is stretched out in opposite directions.

2. The electrode pad connector of claim 1, wherein at least one of the first and second clamping pads is made of an electrically conductive material to electrically connect with a parameter measurement cable.

3. The electrode pad connector of claim 2, wherein the outer frame body further comprises a first connecting wall and a second connecting wall disposed opposite to each other, the first connecting wall being connected to one end of the first side wall and the second side wall, and the second connecting wall being connected to the other end of the first side wall and the second side wall.

4. The electrode pad connector of claim 3, wherein the outer frame body includes first and second cantilever arms respectively projecting from the first and second side walls, the first clamping piece is disposed at a side of a distal end of the first cantilever arm facing the second cantilever arm, and the second clamping piece is disposed at a side of a distal end of the second cantilever arm facing the first cantilever arm.

5. The electrode tab connector of claim 4, wherein the first cantilever comprises a first arm body and a first bent portion provided at a free end of the first arm body, an end portion of the first bent portion away from the first arm body constitutes a distal end of the first cantilever, the second cantilever comprises a second arm body and a second bent portion provided at a free end of the second arm body, the first arm body and the second arm body are spaced apart from each other in a first direction, and projections in a second direction at least partially coincide, the first bent portion is bent from the distal end of the first arm body and extends toward the second arm body, the second bent portion is bent from the distal end of the second arm body and extends toward the first arm body, the first clamping piece is provided at a side of the first bent portion facing the second bent portion, the second clamping piece is provided at a side of the second bent portion facing the first bent portion, wherein the first direction and the second direction are perpendicular to each other.

6. The electrode pad connector of claim 5, further comprising a third clamping tab disposed on a side of the first arm body facing the second arm body, the third clamping tab being located between the first and second bent portions, the first, second and third clamping tabs collectively forming the clamping space therebetween.

7. The electrode pad connector of claim 6, wherein the first, second and third clamping tabs are each half-moon shaped.

8. The electrode sheet connector of claim 4, wherein a notch is formed in the first side wall, the notch is located between the first cantilever and the first connecting wall, a protrusion is formed on one side of the first cantilever, which faces the first side wall, and when the outer frame body is in a natural state, a movable gap is formed between the protrusion and the first side wall in the first direction.

9. The electrode pad connector of claim 4, wherein the first and second cantilever arms are located on the same line in a second direction, the first and second clamping pieces are respectively provided on opposite ends of the first and second cantilever arms, and the first and second side walls are pinched such that the first and second connecting walls are arcuate in the second direction and a clamping space formed between the first and second clamping pieces increases as a distance between the first and second side walls decreases.

10. The electrode sheet connector of claim 9, wherein opposite sides of the first side wall and the second side wall are respectively provided with a holding portion, the holding portions are step-shaped, and the first cantilever, the second cantilever and the two holding portions are located on a long axis of the outer frame main body.

11. The electrode pad connector of claim 3, wherein the outer frame body includes a first cantilever and a second cantilever projecting from the first connection wall and the second connection wall, respectively, in opposition, the first cantilever and the second cantilever being located on a same straight line in a first direction, the first clamping piece and the second clamping piece being provided on opposite ends of the first cantilever and the second cantilever, respectively; the first side wall and the second side wall are pinched such that a pinching space formed between the first pinching piece and the second pinching piece is increased.

12. The electrode pad connector of claim 11, wherein the first and second cantilever arms are located on a short axis of the outer frame body.

13. The electrode pad connector of claim 3, wherein the clamping space is formed between the distal ends of the first and second clamping tabs.

14. The electrode tab connector of claim 3, wherein the first clamping piece and the second clamping piece are arranged to be overlapped up and down, a first clamping hole is formed in the first clamping piece, a second clamping hole is formed in the second clamping piece, only a part of areas of the first clamping hole and the second clamping hole are overlapped when the outer frame main body is in a natural state, and the first side wall and the second side wall are clamped so that the first clamping piece and the second clamping piece move towards each other until the first clamping hole and the second clamping hole are overlapped for clamping and releasing the electrode tab.

15. The electrode pad connector of claim 3, wherein the electrode pad connector comprises two parallel first cantilevers extending from the first side wall, and a second cantilever extending from the second side wall, the second cantilever being located between the two first cantilevers in the first direction, the first engaging portions being provided on opposite sides of distal ends of the two first cantilevers, the second engaging portions being provided on opposite sides of distal ends of the second cantilevers, each first engaging portion being disposed to mate with a corresponding second engaging portion, and the first clamping piece and the second clamping piece being disposed on opposite sides of the two first cantilevers.

16. The electrode tab connector of any one of claims 3 to 15, wherein the outer side of the outer frame body is one of circular, oval, and kidney-shaped, and the inner side of the outer frame body is one of circular, oval, and kidney-shaped.

17. The electrode sheet connector of any one of claims 3 to 15, wherein the first side wall and/or the second side wall is provided with press anti-slip patterns, and the press anti-slip patterns are one or a combination of raised strips, raised points and grooves.

18. Electrode pad connector according to any one of claims 3 to 15, characterized in that the first and/or the second connecting wall is provided with connecting posts, each for connection with a parameter measuring cable.

19. A physiological data monitoring system, comprising a parameter measuring cable, an anti-defibrillation structure and at least three electrode pad connectors according to any one of claims 1 to 18, wherein one end of the parameter measuring cable is used for connecting a wearable physiological parameter monitoring device, the anti-defibrillation structure and the at least three electrode pad connectors are sequentially arranged in series on the parameter measuring cable from one end close to the wearable physiological parameter monitoring device to one end far away from the wearable physiological parameter monitoring device, and the electrode pad connectors are used for clamping electrode pads.

20. The physiological data monitoring system of claim 19 wherein the parameter measurement cable is an inline parameter measurement cable.

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