CN114366112A - Physiological data monitoring sensor device and physiological data monitoring equipment - Google Patents

Abstract

The present application discloses a physiological data monitoring sensing device and a physiological data monitoring device. The physiological data monitoring sensing device includes a first lead wire harness and a second lead wire harness. The first lead wire harness includes a main cable, a plurality of A first lead wire and a first junction box, one end of the main cable is connected to a plurality of the first lead wires through the first junction box, and the other end of the main cable is connected with a first connection The first connector is used to connect with the host of the physiological data monitoring device; the second lead wire harness includes a second connector and a plurality of second lead wires, and a plurality of the second lead wires be connected to the second connector, which is electrically connected to the main cable by being detachably connected to the first junction box, or the second connector is used to monitor the physiological data The device's host connection.

Description

Physiological data monitoring sensor device and physiological data monitoring equipment

technical field

The present application relates to the technical field of physiological data monitoring, and in particular, to a physiological data monitoring sensing device and a physiological data monitoring device.

Background technique

Physiological data monitoring refers to the use of physiological data monitoring equipment to collect and monitor a patient's physiological data to understand the patient's health status.

The current physiological data monitoring and sensing devices are usually composed of multiple limb lead wires and multiple chest lead wires, which cannot be disassembled. In emergency scenarios, patients generally do not need to use chest lead wires during transportation, and only need to connect four limb lead wires, especially to quickly obtain the patient's ECG signal, and a few are suspected of having STEMI or chest pain. Only patients with symptoms need to perform ECG monitoring with the chest lead wire. Therefore, when only the limb lead wire is needed, the limb lead wire can be quickly connected, and the monitoring function of the chest lead wire is also required.

Existing physiological data monitoring and sensing devices are generally all-split cables or integrated cables. The whole split cable needs to connect the limb lead wire to the main cable first, and then connect it to the patient. One more connection action takes a long time; the integrated cable needs to find out the required limb lead wire from the physiological data monitoring and sensing device. Connecting the wires and then connecting the patient is time-consuming, and there are many redundant lead wires, which are not good for cable management.

SUMMARY OF THE INVENTION

The application provides a physiological data monitoring sensing device and a physiological data monitoring device, which can monitor the use of the sensing device according to the physiological data, combine the limb lead wire and the chest lead wire, and connect quickly without redundant wires. Cable, convenient for medical staff to operate.

According to a first aspect of the present application, the present application provides a physiological data monitoring sensing device for use in a physiological data monitoring device, including:

The first lead wire harness includes a main cable, a plurality of first lead wires and a first junction box, one end of the main cable is connected to the plurality of first lead wires through the first junction box, The other end of the main cable is connected with a first connector, and the first connector is used for connecting with the host of the physiological data monitoring device;

A second lead wire harness includes a second connector and a plurality of second lead wires, the plurality of second lead wires are connected to the second connector, and are detachably connected to the first junction box It is electrically connected with the main cable, or the second connector is used for connection with the host of the physiological data monitoring device.

In the physiological data monitoring and sensing device of the embodiment of the present application, a wire harness socket is provided on the first junction box, and the second connector is mated and connected to the wire harness socket, so that a plurality of the second leads A wire can be connected to the host of the physiological data monitoring device through the main cable.

In the physiological data monitoring sensing device of the embodiment of the present application, the first junction box includes:

a first casing, the main cable and the first lead wire are respectively connected at both ends of the first casing, and the wire harness socket is arranged on the end face of the first casing adjacent to the main cable .

In the physiological data monitoring sensing device of the embodiment of the present application, the first junction box includes:

a plurality of first conductive terminals for connecting with the second connector;

A first frame, a plurality of the first conductive terminals are fixed on the first frame and connected to the main cable, and the first shell is wrapped around the outside of the first frame to form the wire harness socket.

In the physiological data monitoring and sensing device of the embodiment of the present application, a grid structure is provided on the first frame, and a plurality of the first conductive terminals are correspondingly arranged on each cell in the grid structure, to increase the creepage distance between the plurality of first conductive terminals.

In the physiological data monitoring and sensing device of the embodiment of the present application, the first casing includes a first inner casing and a first outer casing, and the first inner casing is covered on the first frame by injection molding. On the outer side, the first outer casing is coated on the outer side of the first inner casing by injection molding.

In the physiological data monitoring and sensing device of the embodiment of the present application, one of the first junction box and the second connector is provided with a slot structure, and the first junction box and the second connection are The other side of the device is provided with a buckle structure, and the buckle structure is engaged with the slot structure.

In the physiological data monitoring and sensing device of the embodiment of the present application, the latch structure is provided with a claw with a guiding inclined surface, and the clamping claw is fastened to the clamping groove structure through the guiding inclined surface; and/ or,

The snap structure is provided with a pressing portion, and the snap structure is separated from the snap groove structure by pressing the pressing portion.

In the physiological data monitoring and sensing device of the embodiment of the present application, a dust cover is provided on the first junction box, and the dust cover is closed on the wire harness socket.

In the physiological data monitoring sensing device of the embodiment of the present application, the first connector includes a connector housing, a connector skeleton, and a connector terminal fixed on the connector skeleton, and the connector housing covers the Outside the connector frame, the connector terminal is connected to the main cable.

In the physiological data monitoring sensing device of the embodiment of the present application, the host of the physiological data monitoring device is provided with two connection ports, and the first connector and the second connector respectively correspond to the two connection ports connect.

In the physiological data monitoring and sensing device of the embodiment of the present application, the second lead wire harness further includes a second main cable and a second junction box, and a plurality of the second lead wires pass through the second branch wires The box is connected to one end of the second main cable, and the other end of the second main cable is connected to the second connector.

In the physiological data monitoring and sensing device according to the embodiment of the present application, RA(R) electrode connectors, LA(L) electrode connectors and LL(F) electrode connectors are correspondingly connected to the plurality of first lead wires , a plurality of second lead wires are correspondingly connected with RL(N) electrode connector, V1(C1) electrode connector, V2(C2) electrode connector, V3(C3) electrode connector, V4(C4) electrode connector , V5 (C5) electrode connector and V6 (C6) electrode connector;

Or, a plurality of the first lead wires are correspondingly connected with RA(R) electrode connectors, LA(L) electrode connectors, LL(F) electrode connectors and RL(N) electrode connectors, The two lead wires are correspondingly connected with V1 (C1) electrode connector, V2 (C2) electrode connector, V3 (C3) electrode connector, V4 (C4) electrode connector, V5 (C5) electrode connector and V6 (C6) electrode connector ) electrode connector;

Or, a plurality of the first lead wires are correspondingly connected with RA(R) electrode connectors, LA(L) electrode connectors, LL(F) electrode connectors, RL(N) electrode connectors and V1(C1) electrode connectors ) electrode connector, a plurality of second lead wires are correspondingly connected with V2 (C2) electrode connector, V3 (C3) electrode connector, V4 (C4) electrode connector, V5 (C5) electrode connector and V6 (C6) electrode connector ) electrode connector.

In the physiological data monitoring and sensing device of the embodiment of the present application, the physiological data monitoring and sensing device further includes a resistor, and the first lead harness and the second lead harness are connected to the physiological data through the resistor. Monitor the device's host connection.

In the physiological data monitoring sensing device of the embodiment of the present application, the resistance includes a resistance RA(R) connected in series with the RA(R) electrode connector, a resistance LA(L) connected in series with the LA(L) electrode connector, A resistor LL(F) in series with the LL(F) electrode connector and a resistor RL(N) in series with the RL(N) electrode connector, the resistors RA(R), LA(L), LL(F) ) and resistor RL(N) are arranged on the first connector or the first junction box.

In the physiological data monitoring sensing device of the embodiment of the present application, the resistors include a resistor V1 (C1) connected in series with the V1 (C1) electrode connector, a resistor V2 (C2) connected in series with the V2 (C2) electrode connector, Resistor V3(C3) in series with V3(C3) electrode connector, resistor V4(C4) in series with V4(C4) electrode connector, resistor V5(C5) in series with V5(C5) electrode connector and V6(C5) in series with V5(C5) electrode connector (C6) Resistor V6 (C6) connected in series with electrode connectors, the resistor V1 (C1), resistor V2 (C2), resistor V3 (C3), resistor V4 (C4), resistor V5 (C5) and resistor V6 (C6) ) is arranged on the first connector, the second connector or the second junction box of the second lead harness.

According to a second aspect of the present application, the present application further provides a physiological data monitoring device, the physiological data monitoring device comprising the above-mentioned physiological data monitoring sensing device and a host, the host and the physiological data monitoring sensing device It is electrically connected through the first connector and/or the second connector.

The technical solutions provided by the embodiments of the present application may include the following beneficial effects: the present application designs a physiological data monitoring sensing device and a physiological data monitoring device, since the second connector on the second lead harness is used to connect with the first The junction box is connected, or the second connector is used to connect with the host of the physiological data monitoring equipment, so that the use of the sensing device can be monitored according to the physiological data, and different combinations of the first lead harness and the second lead harness can be selected. , or the first lead wire harness and the second lead wire harness are used alone, without redundant cables, so that the lead wire harness on the human body can be tidy and convenient for medical staff to operate.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not limiting of the present application.

Description of drawings

In order to explain the technical solutions of the embodiments of the present application more clearly, the following briefly introduces the accompanying drawings used in the description of the embodiments. For those of ordinary skill, other drawings can also be obtained from these drawings without any creative effort.

Figure 1 is a graphical representation of electrode placement on a patient for a physiological data monitoring device;

2 is a schematic structural diagram of a physiological data monitoring device provided by an embodiment of the present application;

3 is an exploded schematic view of the physiological data monitoring device in FIG. 2;

FIG. 4 is an exploded schematic view of the first lead harness in FIG. 2;

Fig. 5 is the exploded schematic diagram of the first connector in Fig. 2;

Fig. 6 is the structural representation of the connector skeleton in Fig. 5;

Fig. 7 is the structural representation of the first junction box in Fig. 2;

Fig. 8 is the exploded schematic diagram of the first junction box in Fig. 2;

Fig. 9 is the structural representation of the first skeleton in Fig. 8;

Fig. 10 is the structural representation of the dust cover in Fig. 7;

Figure 11 is an exploded schematic view of the second lead harness in Figure 2;

Figure 12 is an exploded schematic view of the second connector in Figure 11;

FIG. 13 is a schematic structural diagram of the second housing in FIG. 12;

FIG. 14 is a schematic cross-sectional view of the second connector in FIG. 2 after being connected to the first junction box;

FIG. 15 is a schematic circuit diagram of the physiological data monitoring device in FIG. 2;

Fig. 16 is another schematic circuit diagram of the physiological data monitoring device in Fig. 2;

17 is a schematic structural diagram of a physiological data monitoring device provided by another embodiment of the present application;

FIG. 18 is a schematic diagram of the first lead wire harness in FIG. 17 , wherein the dust cover is in a closed state;

Figure 19 is a schematic diagram of the first lead harness in Figure 17, wherein the dust cover is in an open state;

FIG. 20 is a schematic structural diagram of the second lead harness in FIG. 17;

Figure 21 is a schematic circuit diagram of the physiological data monitoring device in Figure 17;

Fig. 22 is another schematic circuit diagram of the physiological data monitoring device in Fig. 17;

Fig. 23 is another schematic circuit diagram of the physiological data monitoring device in Fig. 17;

Fig. 24 is another schematic circuit diagram of the physiological data monitoring device in Fig. 17;

FIG. 25 is a schematic structural diagram of a physiological data monitoring device provided by yet another embodiment of the present application.

Description of reference numbers:

100, the first lead wire harness; 200, the second lead wire harness;

10, the first connector; 11, the connector terminal; 12, the connector frame; 121, the terminal mounting hole; 122, the connector card slot; 13, the connector inner shell; 14, the connector shell;

20. Main cable;

30, the first junction box; 31, the junction box body; 311, the first conductive terminal; 312, the first skeleton; 3121, the grid structure; 3141, the card slot structure; 315, the first resistor; 32, the dust cover; 321, the fixed part of the dust cover; 322, the connection part of the dust cover; 323, the dust cover body; 33, the wiring harness socket;

40. The first lead wire; 41. The first electrode connector;

50, the second connector; 51, the second conductive terminal; 52, the second frame; 53, the second shell; 54, the second resistor; 55, the snap structure;

60, the second lead wire; 61, the second electrode connector;

70. The second main cable;

80. The second junction box.

Detailed ways

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present application. Obviously, the described embodiments are part of the embodiments of the present application, not all of the embodiments. Based on the embodiments in the present application, all other embodiments obtained by those of ordinary skill in the art without creative efforts shall fall within the protection scope of the present application.

It should also be understood that the terminology used in the specification of the application herein is for the purpose of describing particular embodiments only and is not intended to limit the application. As used in this specification and the appended claims, the singular forms "a," "an," and "the" are intended to include the plural unless the context clearly dictates otherwise.

In the description of this application, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", " rear, left, right, vertical, horizontal, top, bottom, inside, outside, clockwise, counterclockwise, etc., or The positional relationship is based on the orientation or positional relationship shown in the accompanying drawings, which is only for the convenience of describing the present application and simplifying the description, rather than indicating or implying that the referred device or element must have a specific orientation, be constructed and operated in a specific orientation, Therefore, it should not be construed as a limitation on this application. In addition, the terms "first" and "second" are only used for descriptive purposes, and should not be construed as indicating or implying relative importance or implying the number of indicated technical features. Thus, features defined as "first", "second" may expressly or implicitly include one or more of said features. In the description of the present application, "plurality" means two or more, unless otherwise expressly and specifically defined.

Some embodiments of the present application will be described in detail below with reference to the accompanying drawings. The embodiments described below and features in the embodiments may be combined with each other without conflict.

The physiological data monitoring sensing device of the present application belongs to the physiological parameter monitoring technology, which is used to be fixed to, connected to or attached to one or more parts of the patient's body to measure the physiological data signals of the part. A wearable physiological data monitoring device usually includes a physiological data monitoring sensing device for collecting a patient's physiological data signal and a host for processing, displaying and other operations on the collected physiological data signal.

As shown in FIG. 1 , when the physiological data monitoring device of the embodiment of the present application is used to measure the ECG data of a patient, it is usually used as a sensor on the physiological data monitoring device, that is, an electrode sheet, which is attached to different parts of the human body surface. On the site, one or more of the positions RA(R)/LA(L), V1(C1)-V6(C6), RL(N)/LL(F) as shown in FIG. 1 . Therefore, the electrode pads that need to be used in different emergency scenarios are different. For example, the chest lead wire is generally not required during the transportation of the patient, and only four limb lead wires are connected. If the chest lead wire and the limb lead wire are connected As a non-detachable integrated structure, when only the limb lead wires are connected, six chest lead wires are redundant, which affects the wearing comfort. The embodiment of the present application provides a physiological data monitoring device, the chest lead wire and the limb lead wire are detachably connected, and different combinations of the chest lead wire and the limb lead wire can be selected according to the usage scenario of the physiological data monitoring device, Or the use of chest leads and limb leads alone, without redundant chest leads and limb leads, makes the chest leads or limb leads on the human body clean and convenient for medical staff to operate.

Example 1

As shown in FIGS. 1 to 16 , the physiological data monitoring and sensing device of the present application includes a first lead harness 100 and a second lead harness 200 , and the first lead harness 100 includes a main cable 20 , a plurality of first leads Line 40 and the first junction box 30, one end of the main cable 20 is connected to a plurality of first lead wires 40 through the first junction box 30, and the first junction box 30 plays the role of transition; the main cable 20 The other end is connected with the first connector 10, and the first connector 10 is used for connecting with the host of the physiological data monitoring device. The second lead harness 200 includes a second connector 50 and a plurality of second lead wires 60, the plurality of second lead wires 60 are connected to the second connector 50, and the second connector 50 is connected to the first The junction box is detachably connected to be electrically connected to the main cable, or the second connector 50 is used to connect with the host of the physiological data monitoring device.

Therefore, the physiological data monitoring and sensing device can select different combinations of the first lead harness 100 and the second lead harness 200 according to different usage scenarios, or the first lead harness 100 and the second lead harness 200 individually In use, there is no redundant first lead wire harness 100 and second lead wire harness 200 during use, so that the first lead wire harness 100 and the second lead wire harness 200 on the human body can be neat and tidy, which is convenient for medical care. personnel operation.

Exemplarily, the first lead wire harness 100 is a limb lead wire, and the second lead wire harness 200 is a chest lead wire. It is sufficient to connect the first lead wire harness 100 to the host of the physiological data monitoring device. When the patient arrives at the hospital and needs further diagnosis, the second lead harness 200 is connected to the host of the physiological data monitoring device through the first lead harness 100, or the second lead harness 200 is directly connected to the host of the physiological data monitoring device. connect.

After the above technical solution is adopted, since the first lead wire harness 100 and the second lead wire harness 200 are arranged separately, so as to monitor the usage scene of the sensing device according to the physiological data, the first lead wire harness 100 and the second lead wire harness 200 are selected. Different combinations of the cables, or use the first lead harness 100 or the second lead harness 200 alone to avoid redundancy of the first lead harness 100 or the second lead harness 200, which may cause the problem of cable entanglement, looseness or confusion , which is not conducive to subsequent use and maintenance.

In an optional embodiment, as shown in FIGS. 3 and 4 , the first junction box 30 is provided with a harness socket 33 , and the second connector 50 is mated and connected to the harness socket 33 , so that a plurality of second leads The line 60 can be connected to the host computer of the physiological data monitoring device through the main cable 20 .

Exemplarily, as shown in FIGS. 3 and 4 , the wire harness socket 33 is provided on one end face of the first junction box 30 , and the second connector 50 is a wire harness plug matched with the wire harness socket 33 . When the second lead wire 60 needs to be used in the emergency scene, the host computer of the monitoring device can be realized through the cooperation of the wire harness plug on the second lead wire 60 and the wire harness socket 33 . When the second lead wire 60 does not need to be used, the connection between the second lead wire 60 and the harness socket 33 can be released to avoid redundancy of the second lead wire 60 and avoid the second lead wire 60 being entangled, loose or confused , which is conducive to subsequent use and maintenance.

In an optional embodiment, as shown in FIG. 3 to FIG. 10 , the first junction box 30 is provided with a dust cover 32 , and the dust cover 32 covers the wire harness socket 33 for protecting the wire harness socket 33 The first conductive terminal inside is to prevent external liquid or dust from entering the harness socket 33 .

Exemplarily, the dust cover 32 includes a dust cover body 323, a dust cover connecting portion 322 and a dust cover fixing portion 321, and the dust cover body 323 is connected to the dust cover fixing portion 321 through the dust cover connecting portion 322, The dust cover fixing part 321 can be movably installed on the main cable 20, and the dust cover body 323 has a flange matching the size of the wire harness socket 33, so that the dust cover body 323 can be connected to the wire harness socket 33 through the flange. , so as to prevent external liquid or dust from entering the harness socket 33 .

In an optional embodiment, as shown in FIG. 7 to FIG. 9 , the first junction box 30 includes a junction box body 31 , and the junction box body 31 includes a first casing, and the first casing is in the longitudinal direction. The opposite ends are respectively provided with a mesh tail structure, and the mesh tail structure is wrapped around the outside of the main cable 20 or the plurality of first lead wires 40 . In this embodiment, the wire harness socket 33 is arranged on another end face of the first housing, for example, the wire harness socket 33 is arranged on the end face of the first housing adjacent to the main cable 20 or the first lead wire 40, and the structure is simple , the design is reasonable, which is convenient for the arrangement of the cables inside the first junction box 30 and the first conductive terminals in the harness socket 33 .

In an optional embodiment, the first junction box 30 further includes a first skeleton 312 and a plurality of first conductive terminals 311, and the plurality of first conductive terminals 311 are used to realize the connection between the second connector 50 and the first junction Electrical connection of the box 30 . The plurality of first conductive terminals 311 are fixed on the first frame 312 and connected to the main cable 20 , and the first casing is wrapped around the outside of the first frame 312 to form the harness socket 33 .

In an optional embodiment, a grid structure 3121 is provided on the first frame 312, and a plurality of first conductive terminals 311 are correspondingly provided on each cell in the grid structure 3121, so as to increase a plurality of first conductive terminals Creepage distance between terminals 311.

Exemplarily, each cell in the grid structure 3121 is provided with a terminal penetration hole 3122 , and the first conductive terminal 311 is penetrated through the terminal penetration hole 3122 . The first conductive terminal 311 can be a Pogo Pin, the second connector 50 is electrically connected to the first junction box 30 through the Pogo pin, and the Pogo Pin is arranged in the grid structure 3121 to increase the path stroke. Increase the creepage distance between Pogo Pins, so as to increase the voltage or current level of the first junction box 30 .

In an optional embodiment, the first shell includes a first inner shell 313 and a first outer shell 314 , the first inner shell 313 is covered on the outside of the first frame 312 by injection molding, and the first outer shell 313 By covering the outside of the first inner casing 313 by injection molding, the assembly process of the first casing is simplified, and not only the first conductive terminals 311 on the first frame 312 can be protected, but also the first junction box can be protected. The external structure of 30 is uniquely designed to improve the market competitiveness of the product.

In an optional embodiment, one of the first junction box 30 and the second connector 50 is provided with a snap structure, and the other of the first junction box 30 and the second connector 50 is provided with a snap structure , the buckle structure is connected with the card slot structure.

Exemplarily, as shown in FIG. 7 to FIG. 14 , the first junction box 30 is provided with a slot structure 3141 , the slot structure 3141 is located on both sides of the first outer shell 314 , and the second connector 50 is provided with a slot structure 3141 . The snap structure 55 matched with the snap structure 3141 enables the second connector 50 to be connected to the first junction box 30 through the cooperation of the snap structure 55 and the snap structure 3141 .

In an optional embodiment, the latching structure 55 is provided with a latching claw 551 having a guiding inclined surface 553, and the latching claw 551 is quickly fastened to the latching groove structure 3141 through the guiding inclined surface 553; and/or, the latching structure 55 The pressing portion 552 provided thereon enables the snap structure 55 to be separated from the slot structure 3141 by operating the pressing portion 552 .

Exemplarily, the claws 551 and the pressing parts 552 are respectively disposed at both ends of the clasps 55, and the middle part of the claws 55 is connected with the first outer casing 314 to form a cantilever structure, which not only ensures that the claws 551 are in the clasps When the slot structure 3141 is opened, it can be automatically opened. When the second connector 50 and the first junction box 30 are buckled in place, the claw 551 is just locked at the position of the slot structure 3141 to realize self-locking. When the second connector 50 needs to be separated from the first junction box 30 , the pressing portion 552 can be pressed to separate the clamping claw 551 from the clamping groove structure 3141 .

In an optional embodiment, as shown in FIG. 11 to FIG. 13 , the second connector 50 includes a second housing 53 , a second frame 52 and a plurality of second conductive terminals 51 , and the plurality of second conductive terminals 51 It is fixed on the second frame 52, the second shell 53 is wrapped on the outside of the second frame 52, and a plurality of second lead wires 60 are arranged on the second shell 53 and are connected with the second conductive terminals 51 correspondingly, so that The plurality of second lead wires 60 can be electrically connected to the first junction box 30 through the second connector 50 .

The structure of the second skeleton 52 is substantially the same as that of the first skeleton 312, and a grid structure is also provided thereon, and a plurality of second conductive terminals 51 are correspondingly arranged on each cell in the grid structure to increase the Creepage distance between the plurality of second conductive terminals 51 .

In an optional embodiment, as shown in FIGS. 4 to 6 , the first connector 10 includes a connector housing, a connector frame 12 and a connector terminal 11 , and the connector terminal 11 is fixed on the connector frame 12 , the connector housing is wrapped on the outside of the connector skeleton 12, and the connector terminal 11 is connected with the main cable 20, so that the first lead harness 100 can be connected to the physiological data monitoring device through the connector terminal 11 on the first connector 10 host connection.

The connector housing includes a connector inner shell 13 and a connector outer shell 14, the connector frame 12 is provided with a terminal mounting hole 121 and a connector slot 122, and the connector terminal 11 is mounted in the terminal mounting hole 121. When the connector 10 is connected to the fixing button on the host through the connector slot 122, the connector terminal 11 is electrically connected to the host, so that the signal of the host can be transmitted to the first lead wire 40 and/or the first lead wire 40 and/or the first lead wire 40 through the main cable 20. Two lead wire 60.

In an optional embodiment, as shown in FIG. 1 to FIG. 16 , the first electrode connectors 41 are correspondingly connected to the plurality of first lead wires 40 , and the first electrode connectors 41 are correspondingly connected to the plurality of second lead wires 60 . Two-electrode connector 61, wherein the first electrode connector 41 may include RA(R) electrode connector, LA(L) electrode connector, LL(F) electrode connector, RL(N) electrode connector, V1( Several electrode connections of C1) electrode connector, V2 (C2) electrode connector, V3 (C3) electrode connector, V4 (C4) electrode connector, V5 (C5) electrode connector and V6 (C5) electrode connector The second electrode connector 61 can be RA (R) electrode connector, LA (L) electrode connector, LL (F) electrode connector, RL (N) electrode connector, V1 (C1) electrode connector , V2 (C2) electrode connector, V3 (C3) electrode connector, V4 (C4) electrode connector, V5 (C5) electrode connector and V6 (C6) electrode connector and several remaining electrode connector combinations.

Exemplarily, the first electrode connector 41 includes RA(R) electrode connector, LA(L) electrode connector and LL(F) electrode connector, and the second electrode connector 61 includes RL(N) electrode connector, V1 (C1) electrode connector, V2 (C2) electrode connector, V3 (C3) electrode connector, V4 (C4) electrode connector, V5 (C5) electrode connector and V6 (C6) electrode connector. The number of the first lead wires 40 is three, the number of the second lead wires 60 is seven, and the three first lead wires 40 are connected to the RA(R) electrode connector, the LA(L) electrode connector and the LL(F) electrode connector. ) electrode connectors are connected in one-to-one correspondence, and the seven second lead wires 60 are connected to the RL (N) electrode connector, V1 (C1) electrode connector, V2 (C2) electrode connector, V3 (C3) electrode connector, V4 (C4) electrode connector, V5 (C5) electrode connector and V6 (C6) electrode connector are connected correspondingly.

Alternatively, the first electrode connector 41 includes RA(R) electrode connector, LA(L) electrode connector, LL(F) electrode connector and RL(N) electrode connector, and the second electrode connector 61 includes V1( C1) electrode connector, V2 (C2) electrode connector, V3 (C3) electrode connector, V4 (C4) electrode connector, V5 (C5) electrode connector and V6 (C6) electrode connector. The number of the first lead wires 40 is four, the number of the second lead wires 60 is six, and the six first lead wires 40 are connected to the RA (R) electrode connector, the LA (L) electrode connector, the LL (F ) electrode connector and RL (N) electrode connector are connected in one-to-one correspondence, and the six second lead wires 60 are connected with V1 (C1) electrode connector, V2 (C2) electrode connector, V3 (C3) electrode connector, V4 (C4) electrode connector, V5 (C5) electrode connector and V6 (C6) electrode connector are connected correspondingly.

Alternatively, the first electrode connector 41 includes an RA(R) electrode connector, an LA(L) electrode connector, an LL(F) electrode connector, an RL(N) electrode connector, and a V1(C1) electrode connector. Two-electrode connectors 61 include V2 (C2) electrode connectors, V3 (C3) electrode connectors, V4 (C4) electrode connectors, V5 (C5) electrode connectors, and V6 (C6) electrode connectors. The number of the first lead wires 40 is five, the number of the second lead wires 60 is five, and the five first lead wires 40 are connected to the RA(R) electrode connector, LA(L) electrode connector, LL (F) The electrode connector, the RL (N) electrode connector and the V1 (C1) electrode connector are connected in one-to-one correspondence, and the five second lead wires 60 are connected with the V2 (C2) electrode connector and the V3 (C3) electrode connector connector, V4 (C4) electrode connector, V5 (C5) electrode connector and V6 (C6) electrode connector are connected correspondingly.

In general, the lead wire connected to the RA(R) electrode connector is called the RA(R) limb lead wire, the lead wire connected to the LA(L) electrode connector is called the LA(L) limb lead wire, and the lead wire connected to the RL( The lead wire of the N) electrode connector is called the RL(N) limb lead wire, the lead wire connected to the LL(F) electrode connector is called the LL(F) limb lead wire, and the lead wire connected to the V1(C1) electrode connector is called the LL(F) limb lead wire. The lead wire is called the V1 (C1) chest lead wire, the lead wire connected to the V2 (C2) electrode connector is called the V2 (C2) chest lead wire, and the lead wire connected to the V3 (C3) electrode connector is called the V3 ( C3) chest lead wire, the lead wire connected to the V4 (C4) electrode connector is called the V4 (C4) chest lead wire, and the lead wire connected to the V5 (C5) electrode connector is called the V5 (C5) chest lead wire , the lead wire connected to the V6 (C6) electrode connector is called the V6 (C6) chest lead wire.

Among them, the RA(R) electrode connector is pasted on the right arm, the LA(L) electrode connector is pasted on the left arm, the RL(N) electrode connector is pasted on the right leg, and the LL(F) electrode connector is pasted on the right leg. The position of the electrode connector is the left leg, the position of the V1 (C1) electrode connector is the fourth intercostal space of the right sternal border, the position of the V2 (C2) electrode connector is the fourth intercostal space of the left sternal border, and the position of V3 (C3) The electrode connector is pasted at the midpoint of the connecting line between the V2 (C2) electrode connector and the V4 (C4) electrode connector, and the V4 (C4) electrode connector is pasted at the intersection of the left midclavicular line and the fifth intercostal space. The position where the V5 (C5) electrode connector is pasted is at the same level as the left anterior axillary line and the V4 (C4) electrode connector, and the position where the V6 (C6) electrode connector is pasted is the left mid-axillary line and the V4 (C4) electrode connector at the same level, For details, please refer to FIG. 1 .

In an optional embodiment, the physiological data monitoring sensing device further includes resistors disposed at different positions, and the first lead wire harness 100 and the second lead wire harness 200 are connected to the host of the physiological data monitoring device via the resistor. Exemplarily, the resistors include a first resistor 315 and a second resistor 54, the number of the first resistors 315 is equal to the number of the first electrode connectors 41, the number of the second resistors 54 is equal to the number of the second electrode connectors 61, Each first electrode connector 41 can be connected to a host connection of a physiological data monitoring device via a first resistor 315 in series therewith, and each second electrode connector 61 can be connected to a physiological data monitoring device via a second resistor 54 in series therewith The host of the device is connected, wherein the first resistor 315 and the second resistor 54 are mainly used for anti-defibrillation.

In an optional embodiment, the first resistor 315 includes a resistor RA(R) connected in series with the RA(R) electrode connector, a resistor LA(L) connected in series with the LA(L) electrode connector, and a resistor LA(L) connected in series with the LA(L) electrode connector. ) a resistor LL(F) in series with the electrode connector and a resistor RL(N) in series with the RL(N) electrode connector, where resistor RA(R), resistor LA(L), resistor LL(F) and resistor RL (N) is provided on the first connector 10 or the first junction box 30 .

In an optional embodiment, the second resistor 54 includes a resistor V1 (C1) connected in series with the V1 (C1) electrode connector, a resistor V2 (C2) connected in series with the V2 (C2) electrode connector, and a resistor V2 (C2) connected in series with the V3 (C3) electrode connector. ) resistor V3 (C3) connected in series with electrode connector, resistor V4 (C4) connected in series with electrode connector V4 (C4), resistor V5 (C5) connected in series with electrode connector V5 (C5), and resistor V5 (C5) connected in series with electrode connector V6 (C6) The resistor V6 (C6) is connected in series with the connector, wherein the resistor V1 (C1), the resistor V2 (C1), the resistor V3 (C3), the resistor V4 (C4), the resistor V5 (C5) and the resistor V6 (C6) are set in the first on a connector 10 or a second connector 50 .

Exemplarily, as shown in FIG. 15 , the resistor RA(R), the resistor LA(L), the resistor LL(F) and the resistor RL(N) are arranged on the first junction box 30, and the first casing is covered on the first junction box 30. Resistor RA(R), Resistor LA(L), Resistor LL(F), and Resistor RL(N) outside the resistor RA(R), Resistor LA(L), Resistor LL(F), and Resistor RL(N) ) to protect. Resistor V1 (C1), resistor V2 (C2), resistor V3 (C3), resistor V4 (C4), resistor V5 (C5) and resistor V6 (C6) are arranged on the first connector 10, and the connector housing is covered on the first connector 10. Resistor V1(C1), Resistor V2(C2), Resistor V3(C3), Resistor V4(C4), Resistor V5(C5) and Resistor V6(C6) ), resistor V3 (C3), resistor V4 (C4), resistor V5 (C5) and resistor V6 (C6) for protection.

Exemplarily, as shown in FIG. 16, the resistor RA(R), the resistor LA(L), the resistor LL(F) and the resistor RL(N) are arranged on the first junction box 30, and the first housing is covered on the first junction box 30. Resistor RA(R), Resistor LA(L), Resistor LL(F), and Resistor RL(N) outside the resistor RA(R), Resistor LA(L), Resistor LL(F), and Resistor RL(N) ) to protect. Resistor V1 (C1), resistor V2 (C2), resistor V3 (C3), resistor V4 (C4), resistor V5 (C5) and resistor V6 (C6) are arranged on the second connector 50, and the second shell is covered on the second connector 50. Resistor V1(C1), Resistor V2(C2), Resistor V3(C3), Resistor V4(C4), Resistor V5(C5) and Resistor V6(C6) ), resistor V3 (C3), resistor V4 (C4), resistor V5 (C5) and resistor V6 (C6) for protection.

Embodiment 2

As shown in FIG. 17 to FIG. 23 , the structure of the physiological data monitoring and sensing device in this embodiment is basically the same as that of the physiological data monitoring and sensing device in the above-mentioned first embodiment, and the difference is the second lead in this embodiment. The wiring harness 200 further includes a second main cable 70 and a second junction box 80, wherein a plurality of second lead wires 60 are connected to one end of the second main cable 70 through the second junction box 80, and the second main cable 70 The other end is connected to the second connector 50 , and the second connector 50 is connected to the first junction box 30 . In addition, the position where the second connector 50 is connected to the first junction box 30 is different from the position where the second connector 50 is connected to the first junction box 30 in the first embodiment. In this embodiment, the second connector 50 is connected to the side of the first junction box 30, while the second connector 50 of the above-mentioned first embodiment is connected to the front of the first junction box 30. For details, please refer to FIG. 17 to shown in Figure 20.

Among them, the resistance V1 (C1), the resistance V2 (C2), the resistance V3 (C3), the resistance V4 (C4), the resistance V5 (C5) and the resistance V6 (C6) are arranged in the first connector 10, the second connector 50 or on the second junction box 80.

Exemplarily, as shown in FIG. 21 , the resistor RA(R), the resistor LA(L), the resistor LL(F) and the resistor RL(N) are arranged on the first junction box 30, and the first housing is covered on the first junction box 30. Resistor RA(R), Resistor LA(L), Resistor LL(F), and Resistor RL(N) outside the resistor RA(R), Resistor LA(L), Resistor LL(F), and Resistor RL(N) ) to protect. Resistor V1 (C1), resistor V2 (C2), resistor V3 (C3), resistor V4 (C4), resistor V5 (C5) and resistor V6 (C6) are arranged in the second junction box 80, and the second junction box 80 The casing is wrapped on the outside of resistor V1 (C1), resistor V2 (C2), resistor V3 (C3), resistor V4 (C4), resistor V5 (C5) and resistor V6 (C6). ), resistor V2 (C2), resistor V3 (C3), resistor V4 (C4), resistor V5 (C5) and resistor V6 (C6) for protection.

Alternatively, as shown in FIG. 22 , the resistor RA(R), the resistor LA(L), the resistor LL(F) and the resistor RL(N) are arranged on the first junction box 30 , and the first housing covers the resistor RA (R), resistor LA(L), resistor LL(F), and resistor RL(N) outside of resistor RA(R), resistor LA(L), resistor LL(F), and resistor RL(N) Protect. Resistor V1 (C1), resistor V2 (C2), resistor V3 (C3), resistor V4 (C4), resistor V5 (C4) and resistor V6 (C6) are arranged on the first connector 10, and the connector housing is covered on the first connector 10. Resistor V1(C1), Resistor V2(C2), Resistor V3(C3), Resistor V4(C4), Resistor V5(C5) and Resistor V6(C6) ), resistor V3 (C3), resistor V4 (C4), resistor V5 (C5) and resistor V6 (C6) for protection.

Alternatively, as shown in FIG. 23, the resistor RA(R), the resistor LA(L), the resistor LL(F) and the resistor RL(N) are provided on the first connector 10, and the connector housing is wrapped around the resistor RA( R), resistor LA(L), resistor LL(F) and resistor RL(N) outside to protect resistor RA(R), resistor LA(L), resistor LL(F) and resistor RL(N) . Resistor V1 (C1), resistor V2 (C2), resistor V3 (C3), resistor V4 (C4), resistor V5 (C5) and resistor V6 (C6) are arranged in the second junction box 80, and the second junction box 80 The casing is wrapped on the outside of resistor V1 (C1), resistor V2 (C2), resistor V3 (C3), resistor V4 (C4), resistor V5 (C5) and resistor V6 (C6). ), resistor V2 (C2), resistor V3 (C3), resistor V4 (C4), resistor V5 (C5) and resistor V6 (C6) for protection.

Alternatively, as shown in FIG. 24, the resistor RA(R), the resistor LA(L), the resistor LL(F) and the resistor RL(N) are arranged on the first junction box 30, and the connector housing is wrapped around the resistor RA (R), resistor LA(L), resistor LL(F), and resistor RL(N) outside of resistor RA(R), resistor LA(L), resistor LL(F), and resistor RL(N) Protect. Resistors V1 ( C1 ), V2 ( C2 ), V3 ( C3 ), V4 ( C4 ), V5 ( C5 ) and V6 ( C6 ) are provided on the second electrode connector 61 .

Embodiment 3

As shown in FIG. 25 , the structure of the physiological data monitoring and sensing device in this embodiment is basically the same as that of the physiological data monitoring and sensing device in the above-mentioned first embodiment, the difference is that the second connector 50 in this embodiment has the same structure. The structure is the same as that of the first connector 10 , wherein the host of the physiological data monitoring device is provided with two connection ports, and the first connector 10 and the second connector 50 are respectively connected to the two connection ports correspondingly.

Embodiment 4

The present application also provides a physiological data monitoring device, which includes the above-mentioned physiological data monitoring sensing device and a host, wherein the host and the physiological data monitoring sensing device are connected through the first connector 10 and/or the second connection The device 50 is electrically connected.

In the description of this application, it should be noted that, unless otherwise expressly specified and limited, the terms "installed", "connected" and "connected" should be understood in a broad sense, for example, it may be a fixed connection or a detachable connection connected, or integrally connected. It can be a mechanical connection or an electrical connection. It can be directly connected, or indirectly connected through an intermediate medium, and it can be the internal communication between two elements or the interaction relationship between the two elements. For those of ordinary skill in the art, the specific meanings of the above terms in this application can be understood according to specific situations.

In this application, unless otherwise expressly specified and defined, a first feature "on" or "under" a second feature may include direct contact between the first and second features, or may include the first and second features Not directly but through additional features between them. Also, the first feature being "above", "over" and "above" the second feature includes the first feature being directly above and obliquely above the second feature, or simply means that the first feature is level higher than the second feature. The first feature is "below", "below" and "below" the second feature includes the first feature being directly below and diagonally below the second feature, or simply means that the first feature has a lower level than the second feature.

The above disclosure provides many different implementations or examples for implementing different structures of the present application. To simplify the disclosure of the present application, the components and arrangements of specific examples are described above. Of course, they are only examples and are not intended to limit the application. Furthermore, this application may repeat reference numerals and/or reference letters in different instances for the purpose of simplicity and clarity, and does not in itself indicate a relationship between the various embodiments and/or arrangements discussed. In addition, this application provides examples of various specific processes and materials, but one of ordinary skill in the art will recognize the application of other processes and/or the use of other materials.

In the description of this specification, reference to the terms "one embodiment," "some embodiments," "exemplary embodiment," "example," "specific example," or "some examples", etc., is meant to incorporate the embodiments A particular feature, structure, material, or characteristic described or exemplified is included in at least one embodiment or example of the present application. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

Although the embodiments of the present application have been shown and described, those of ordinary skill in the art will appreciate that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present application, The scope of the application is defined by the claims and their equivalents.

Claims (17)

1. A physiological data monitoring sensing device for a physiological data monitoring apparatus, comprising:

the first lead wire harness comprises a main cable, a plurality of first lead wires and a first junction box, one end of the main cable is connected with the plurality of first lead wires through the first junction box, the other end of the main cable is connected with a first connector, and the first connector is used for being connected with a host of the physiological data monitoring equipment;

the second leads the pencil, including second connector and many second lead the line, many the second lead the line with the second connector is connected, the second connector through with first branch box can dismantle the connection and with the main cable electricity is connected, or the second connector be used for with physiological data monitoring facilities's host computer is connected.

2. The physiological data monitoring sensing device according to claim 1, wherein a harness socket is provided on the first junction box, and the second connector is connected to the harness socket in a fitting manner, so that the plurality of second lead wires can be connected to a host of the physiological data monitoring apparatus through the main cable.

3. The physiological data monitoring sensing device of claim 2, wherein the first junction box comprises:

the wire harness socket is arranged on the end face of the first shell adjacent to the main cable.

4. The physiological data monitoring sensing device of claim 3, wherein the first junction box comprises:

a plurality of first conductive terminals for connection with the second connector;

the first framework is fixed on the first framework and connected with the main cable, and the first shell wraps the outer side of the first framework to form the wire harness socket.

5. The physiological data monitoring and sensing device according to claim 4, wherein a grid structure is disposed on the first frame, and a plurality of the first conductive terminals are correspondingly disposed on each unit cell in the grid structure to increase a creepage distance between the plurality of first conductive terminals.

6. The physiological data monitoring and sensing device according to claim 4, wherein the first housing comprises a first inner housing and a first outer housing, the first inner housing is coated on the outer side of the first framework by injection molding, and the first outer housing is coated on the outer side of the first inner housing by injection molding.

7. The physiological data monitoring sensing device according to claim 1, wherein one of the first junction box and the second connector is provided with a card slot structure, and the other of the first junction box and the second connector is provided with a snap structure, and the snap structure is snapped with the card slot structure.

8. The physiological data monitoring and sensing device according to claim 7, wherein the locking structure is provided with a claw having a guiding inclined surface, and the claw is locked on the locking groove structure through the guiding inclined surface; and/or the presence of a gas in the gas,

the buckle structure is provided with a pressing part, and the buckle structure is separated from the clamping groove structure by pressing the pressing part.

9. The physiological data monitoring and sensing device of claim 2, wherein a dust cover is disposed on the first junction box, and the dust cover covers the junction box.

10. The physiological data monitoring and sensing device according to claim 1, wherein the second connector comprises a second housing, a second frame and a second conductive terminal fixed on the second frame, the second housing covers the outside of the second frame, and the second conductive terminal is correspondingly connected with the plurality of second lead wires.

11. The physiological data monitoring sensing device of claim 1, wherein the first connector comprises a connector housing, a connector frame, and connector terminals fixed to the connector frame, the connector housing is wrapped outside the connector frame, and the connector terminals are connected to the main cable.

12. The physiological data monitoring sensing device of claim 1, wherein the second lead harness further comprises a second main cable and a second junction box, a plurality of the second lead wires being connected to one end of the second main cable through the second junction box, the other end of the second main cable being connected to the second connector.

13. The physiological data monitoring and sensing device according to any one of claims 1 to 12, wherein a ra (r) electrode connector, a la (l) electrode connector, and a ll (f) electrode connector are connected to a plurality of the first lead lines, and a rl (n) electrode connector, a V1(C1) electrode connector, a V2(C2) electrode connector, a V3(C3) electrode connector, a V4(C4) electrode connector, a V5(C5) electrode connector, and a V6(C6) electrode connector are connected to a plurality of the second lead lines;

or, a plurality of first lead wires are correspondingly connected with an RA (R) electrode connector, an LA (L) electrode connector, an LL (F) electrode connector and an RL (N) electrode connector, and a plurality of second lead wires are correspondingly connected with a V1(C1) electrode connector, a V2(C2) electrode connector, a V3(C3) electrode connector, a V4(C4) electrode connector, a V5(C5) electrode connector and a V6(C6) electrode connector;

or, a ra (r) electrode connector, a la (l) electrode connector, a ll (f) electrode connector, a rl (n) electrode connector and a V1(C1) electrode connector are correspondingly connected to the plurality of first lead lines, and a V2(C2) electrode connector, a V3(C3) electrode connector, a V4(C4) electrode connector, a V5(C5) electrode connector and a V6(C6) electrode connector are correspondingly connected to the plurality of second lead lines.

14. The physiological data monitoring sensing device of claim 13, further comprising a resistor, wherein the first lead beam and the second lead beam are connected to a host of the physiological data monitoring device via the resistor.

15. The physiological data monitoring sensing device of claim 14, wherein the resistances comprise a resistance ra (r) in series with ra (r) electrode connector, a resistance la (l) in series with la (l) electrode connector, a resistance ll (f) in series with ll (f) electrode connector, and a resistance rl (n) in series with rl (n) electrode connector, the resistances ra (r), la (l), ll (f), and rl (n) being disposed on the first connector or first junction box.

16. The physiological data monitoring sensing device of claim 14, wherein said resistances comprise a resistance V1(C1) in series with a V1(C1) electrode connector, a resistance V2(C2) in series with a V2(C2) electrode connector, a resistance V3(C3) in series with a V3(C3) electrode connector, a resistance V4(C4) in series with a V4(C4) electrode connector, a resistance V5(C5) in series with a V5(C5) electrode connector, and a resistance V6(C6) in series with a V6(C6) electrode connector, said resistances V1(C1), V2(C2), V2(C2), and V2(C2) being disposed on said first, second, or third wire harness connector.

17. A physiological data monitoring apparatus, comprising the physiological data monitoring sensing device according to any one of claims 1 to 16 and a host, wherein the host is electrically connected with the physiological data monitoring sensing device through the host connector.

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