CN216823464U - Physiological data monitoring sensing device, monitor and monitoring system - Google Patents

Abstract

The utility model discloses a physiological data monitoring sensing device, monitor and monitoring system, physiological data monitoring sensing device are used for physiological data monitoring main part, include: a connector; the one-line cable comprises an outer sheath and at least two mutually independent conductors positioned in the outer sheath; a plurality of electrodes, each of which is connected to one of the conductors, and any two of which are connected to different ones of the conductors; the plurality of electrodes connected by the at least two mutually independent conductors are arranged along the length direction of the one-line cable on the same one-line cable. The physiological data monitoring and sensing device provided by the utility model effectively reduces the total cross-section size requirement of the cable; the size requirement of the connector is reduced, the miniaturization setting is facilitated, the total size of the physiological data monitoring and sensing device can be effectively reduced, and the physiological data monitoring and sensing device is convenient to wear.

Description

Physiological data monitoring sensing device, monitor and monitoring system

Technical Field

The utility model relates to a sensor equipment technical field, in particular to physiological data monitoring sensing device, monitor and monitoring system.

Background

At present, along with the demand of monitoring when patients with sub-severe diseases get out of bed after operation is more and more intense, some patients need to monitor physical parameters such as 5-lead electrocardiogram monitoring or 5-lead electrocardiogram plus body temperature. The physical parameters are generally monitored by a physiological data monitoring and sensing device.

With the increasing demands on wearing comfort and ease of use for patients, the miniaturization demand of physiological data monitoring and sensing devices has also increased. The size of the physiological data monitoring and sensing device is reduced, so that the physiological data monitoring and sensing device is convenient to wear. Especially for an electrocardio sensor with 5 lead or more or other electrocardio composite parameter sensors, the requirements on the size and the wearing usability are higher and higher.

Therefore, how to reduce the size and facilitate wearing is a problem to be solved urgently by those skilled in the art.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model provides a physiological data monitoring sensing device to reduce the size, conveniently wear. The utility model also provides a monitor and monitoring system of having above-mentioned physiological data monitoring sensing device.

In order to achieve the above object, the utility model provides a following technical scheme:

a physiological data monitoring sensing device comprising:

a connector;

the one-line cable comprises an outer sheath and at least two mutually independent conductors positioned in the outer sheath;

a plurality of electrodes, each of which is connected to one of the conductors, and any two of which are connected to different ones of the conductors; the plurality of electrodes connected to the conductor of the same one-line cable are arranged at intervals in a length direction of the one-line cable.

The utility model also provides a physiological data monitoring sensing device, include:

a connector;

the one-line cable is connected with the connector and comprises an outer sheath, a shield, a ground wire and a plurality of mutually independent conductors, the shield is positioned in the outer sheath, the ground wire and the plurality of conductors are positioned in the inner space of the shield, and any positions of the ground wire and the shield are electrically connected;

the electrodes are connected with the conductors in a one-to-one correspondence manner; the plurality of electrodes are arranged at intervals along the length direction of the one-line cable.

The utility model also provides a monitor, include:

a physiological data monitoring sensing device as defined in any one of the preceding claims;

and the monitoring main body is in communication connection with the physiological data monitoring and sensing device and is used for basic operation.

The utility model also provides a monitoring system, which comprises a monitoring device and at least two monitoring main bodies which can be worn on the human body, wherein at least one first monitoring main body and at least one second monitoring main body are arranged in the at least two monitoring main bodies;

the first monitoring body is the monitor, and is used for being worn on the trunk of a human body, and the second monitoring body is used for being worn on the limbs of the human body;

the monitoring equipment is ward-level monitoring equipment and/or hospital-level monitoring equipment;

the monitoring equipment at least comprises a first wireless communication module;

the first monitoring body is in wireless communication connection with the second monitoring body, and at least one of the first monitoring body and the second monitoring body comprises a second wireless communication module which is in communication with the first wireless communication module, so that the physiological parameters collected from the first monitoring body and the second monitoring body are transmitted to the monitoring equipment through the second wireless communication module. According to the technical scheme, the physiological data monitoring and sensing device provided by the utility model has the advantages that at least two mutually independent conductors are arranged on the outer sheath to form a linear cable, and compared with the case that each electrode is connected with an independent cable, the total section size requirement of the cable is effectively reduced; because a line formula cable is connected with the connector, consequently, can reduce the size demand of connector, convenient miniaturized setting can effectively reduce physiological data monitoring sensing device's overall size, makes things convenient for wearing of physiological data monitoring sensing device.

The utility model provides a monitor and monitoring system because above-mentioned physiological data monitoring sensing device has above-mentioned technological effect, and monitoring system who has above-mentioned physiological data monitoring sensing device also has same ground technological effect, and here no longer tired one by one.

Drawings

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

Fig. 1 is a first schematic structural diagram of a first physiological data monitoring and sensing device according to an embodiment of the present invention;

fig. 2 is a second schematic structural diagram of the first physiological data monitoring and sensing device according to an embodiment of the present invention;

fig. 3 is a schematic structural diagram of a first physiological data monitoring and sensing device according to an embodiment of the present invention;

fig. 4 is a schematic diagram illustrating a fourth structure of the first physiological data monitoring and sensing device according to an embodiment of the present invention;

fig. 5 is a schematic structural diagram of a fifth structure of a first physiological data monitoring and sensing device according to an embodiment of the present invention;

fig. 6 is a schematic diagram illustrating a sixth structure of the first physiological data monitoring and sensing device according to an embodiment of the present invention;

fig. 7 is a schematic structural diagram of a seventh physiological data monitoring and sensing device according to an embodiment of the present invention;

fig. 8 is an eighth structural schematic diagram of the first physiological data monitoring and sensing device according to an embodiment of the present invention;

fig. 9 is a schematic view of a ninth structure of the first physiological data monitoring and sensing device according to an embodiment of the present invention;

fig. 10 is a schematic view of a tenth configuration of the first physiological data monitoring and sensing device according to the embodiment of the present invention;

fig. 11 is an eleventh structural schematic diagram of the first physiological data monitoring and sensing device according to the embodiment of the present invention;

fig. 12 is a twelfth schematic structural diagram of the first physiological data monitoring and sensing device according to the embodiment of the present invention;

fig. 13 is a schematic view of an electrode distribution of the first physiological data monitoring and sensing device according to the embodiment of the present invention;

fig. 14 is a schematic view of a first structure of a second physiological data monitoring and sensing device according to an embodiment of the present invention;

fig. 15 is a second schematic structural diagram of a second physiological data monitoring and sensing device according to an embodiment of the present invention;

fig. 16 is a schematic structural diagram of a second physiological data monitoring and sensing device according to an embodiment of the present invention;

fig. 17 is a schematic diagram illustrating a fourth structure of a second physiological data monitoring and sensing device according to an embodiment of the present invention;

fig. 18 is a schematic structural diagram of a fifth structure of a second physiological data monitoring and sensing device according to an embodiment of the present invention;

fig. 19 is a schematic diagram illustrating a sixth structure of the second physiological data monitoring and sensing device according to the embodiment of the present invention;

fig. 20 is a schematic diagram illustrating a seventh structure of a second physiological data monitoring and sensing device according to an embodiment of the present invention;

fig. 21 is an eighth structural schematic diagram of the second physiological data monitoring and sensing device according to the embodiment of the present invention;

fig. 22 is a schematic view of a ninth structure of the second physiological data monitoring and sensing device according to the embodiment of the present invention;

fig. 23 is a schematic diagram of a tenth configuration of the second physiological data monitoring and sensing device according to the embodiment of the present invention;

fig. 24 is an eleventh structural schematic diagram of a second physiological data monitoring and sensing device according to an embodiment of the present invention;

fig. 25 is a twelfth schematic structural view of a physiological data monitoring and sensing device according to an embodiment of the present invention;

fig. 26 is a schematic view of an electrode distribution of a second physiological data monitoring and sensing device according to an embodiment of the present invention;

fig. 27 is a schematic cross-sectional view of an in-line cable according to an embodiment of the present invention;

fig. 28 is an internal schematic view of an in-line cable according to an embodiment of the present invention;

fig. 29 is a schematic structural view of a monitor according to an embodiment of the present invention;

fig. 30 is a schematic structural diagram of the monitoring system provided by the present invention.

Detailed Description

The utility model discloses a physiological data monitoring sensing device to reduce the size, conveniently wear. The utility model also provides a monitor and monitoring system of having above-mentioned physiological data monitoring sensing device.

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

As shown in fig. 1-26, an embodiment of the present invention provides a physiological data monitoring sensing device for a physiological data monitoring subject. The physiological data monitoring and sensing device comprises a connector 1, a plurality of electrodes and at least two one-line cables connected with the connector 1. The one-line cable comprises an outer sheath and at least two mutually independent conductors positioned in the outer sheath; each electrode is respectively connected with the connecting position of one conductor, and any two electrodes are connected to different conductors; a plurality of electrodes connected to the conductors of the same one-line cable are arranged at intervals along the length direction of the one-line cable.

The embodiment of the utility model provides a physiological data monitoring sensing device, through set up at least two mutually independent conductors in an oversheath, form a line formula cable, compare with each electrode all connects independent cable, effectively reduced the total cross-sectional dimension demand of cable; because a line formula cable is connected with connector 1, consequently, can reduce connector 1's size demand, convenient miniaturized setting can effectively reduce physiological data monitoring sensing device's overall size, makes things convenient for wearing of physiological data monitoring sensing device.

The physiological data monitoring main body can be wearable monitoring equipment, also can be bedside monitoring equipment and the like.

And the plurality of electrodes connected with the conductor of the same one-line cable are arranged at intervals along the length direction of the one-line cable, so that the positions of the plurality of electrodes on the one-line cable can be arranged according to human engineering, the wearing is further convenient, and the management is also convenient.

It will be appreciated that a single wire cable and a plurality of electrodes connected to its conductors combine to form a single wire sensor.

In order to achieve that at least two conductors located in the same outer sheath are independent of each other, each conductor has an independent insulation layer. In addition, a semiconductive layer may be provided outside the insulating layer in order to reduce noise.

For convenience of management, the number of the one-line cables is two, and the two cables are respectively a first one-line cable 2 and a second one-line cable 3. That is, the physiological data monitoring and sensing device includes a connector 1, and a first one-line cable 2 and a second one-line cable 3 connected to the connector 1. Through setting up two collinear cables, make things convenient for the distribution of a plurality of electrodes on the human body, also make things convenient for the arrangement to the physiological data monitoring sensing device who has two collinear cables.

The number of the plurality of electrodes is five, and the electrodes are respectively a right leg electrode 8, a left leg electrode 6, a left arm electrode 5, a right arm electrode 4 and a chest wall electrode 7; namely, the physiological data monitoring and sensing device is a 5-lead electrocardiogram sensor. In the present embodiment, the at least two mutually independent conductors in the first one-line cable 2 include three first electrode conductors, which are connected to any three of the five electrodes in a one-to-one correspondence; at least two mutually independent conductors in the second linear cable 3 comprise two second electrode conductors which are connected in one-to-one correspondence with the remaining two of the five electrodes.

In order to identify the electrode type conveniently, the external marks of any two electrodes of the right leg electrode 8, the left leg electrode 6, the left arm electrode 5, the right arm electrode 4 and the chest wall electrode 7 are different. The external identifier may include a name and a color.

The embodiment of the utility model provides an use "beautiful mark" to lead the sign and done possible deformation scheme as the example, the "european standard" that corresponds the position also has the same deformation scheme, and european standard and beautiful mark corresponding relation are shown as the following table:

TABLE 1 external identification of electrodes

In this embodiment, the connector 1 has a clip for fixing to the neckline of the clothes; the electrode of the first linear cable 2 close to the connector 1 and the electrode of the second linear cable 3 close to the connector 1 are any two of the left arm electrode 5, the right arm electrode 4 and the chest wall electrode 7. Since the connector 1 is located near the neck of the human body, in order to facilitate the electrode arrangement, the electrode of the first one-line cable 2 close to the connector 1 may be any one of the left arm electrode 5, the right arm electrode 4 and the chest wall electrode 7, and the electrode of the second one-line cable 3 close to the connector 1 may be one of the remaining two of the left arm electrode 5, the right arm electrode 4 and the chest wall electrode 7. The positions of the left arm electrode 5, the right arm electrode 4 and the chest wall electrode 7 are close to the neck of a human body compared with the positions of the right leg electrode 8 and the left leg electrode 6, so that the physiological data monitoring and sensing device can be conveniently arranged integrally through the arrangement.

The embodiment of the utility model provides a physiological data monitoring and sensing device, which also comprises a body temperature sensor 9; the at least two mutually independent conductors comprised in the one-wire cable comprise a body temperature sensing conductor connected to the body temperature sensor 9. Through the arrangement, the physiological data monitoring and sensing device can be used for monitoring the body temperature. That is, the physiological data monitoring and sensing device in this embodiment is a combined structure of a 5-lead electrocardiograph sensor and a body temperature sensor.

In a first embodiment, as shown in fig. 1, the physiological data monitoring sensing device comprises a body temperature sensor 9.

The physiological data monitoring and sensing device is provided with a connector 1, a first one-line cable 2 and a second one-line cable 3.

The number of the conductors in the first one-line cable 2 is three, and the three conductors are all first electrode conductors; the three first electrode conductors are respectively connected with the right arm electrode 4, the left arm electrode 5 and the left leg electrode 6, and the right arm electrode 4, the left arm electrode 5 and the left leg electrode 6 are sequentially arranged at intervals along the direction of the first one-line cable 2 away from the connector 1.

The conductor in the second linear cable 3 comprises a body temperature sensing conductor connected with a body temperature sensor 9, the conductor in the second linear cable 3 further comprises two second electrode conductors connected with a chest wall electrode 7 and a right leg electrode 8, and the chest wall electrode 7, the right leg electrode 8 and the body temperature sensor 9 are sequentially arranged along the direction of the second linear cable 3 away from the connector 1.

In a second embodiment, as shown in fig. 2, the physiological data monitoring sensing device comprises a body temperature sensor 9.

The physiological data monitoring and sensing device is provided with a connector 1, a first one-line cable 2 and a second one-line cable 3.

The number of the conductors in the first one-line cable 2 is three, and the three conductors are all first electrode conductors; the three first electrode conductors are respectively connected with the left arm electrode 5, the right arm electrode 4 and the left leg electrode 6, and the left arm electrode 5, the right arm electrode 4 and the left leg electrode 6 are sequentially arranged at intervals along the direction of the first one-line cable 2 away from the connector 1.

The conductor in the second linear cable 3 comprises a body temperature sensing conductor connected with a body temperature sensor 9, the conductor in the second linear cable 3 further comprises two second electrode conductors connected with a chest wall electrode 7 and a right leg electrode 8, and the chest wall electrode 7, the right leg electrode 8 and the body temperature sensor 9 are sequentially arranged at intervals along the direction of the second linear cable 3 away from the connector 1.

In a third embodiment, as shown in fig. 3, the physiological data monitoring sensing device comprises a body temperature sensor 9.

The physiological data monitoring and sensing device is provided with a connector 1, a first one-line cable 2 and a second one-line cable 3.

The number of the conductors in the first one-line cable 2 is three, and the three conductors are all first electrode conductors; the three first electrode conductors are respectively connected with the left arm electrode 5, the chest wall electrode 7 and the left leg electrode 6, and the left arm electrode 5, the chest wall electrode 7 and the left leg electrode 6 are sequentially arranged at intervals along the direction of the first one-line cable 2 away from the connector 1.

The conductor in the second first-line cable 3 comprises a body temperature sensing conductor connected with a body temperature sensor 9, the conductor in the second first-line cable 3 further comprises two second electrode conductors connected with a right arm electrode 4 and a right leg electrode 8, and the right arm electrode 4, the right leg electrode 8 and the body temperature sensor 9 are sequentially arranged at intervals along the direction of the second first-line cable 3 far away from the connector 1.

In a fourth embodiment, as shown in fig. 4, the physiological data monitoring sensing device comprises a body temperature sensor 9.

The physiological data monitoring and sensing device is provided with a connector 1, a first one-line cable 2 and a second one-line cable 3.

The number of the conductors in the first one-line cable 2 is three, and the three conductors are all first electrode conductors; the three first electrode conductors are respectively connected with the right arm electrode 4, the chest wall electrode 7 and the left leg electrode 6, and the right arm electrode 4, the chest wall electrode 7 and the left leg electrode 6 are sequentially arranged at intervals along the direction of the first one-line cable 2 away from the connector 1.

The conductor in the second linear cable 3 comprises a body temperature sensing conductor connected with a body temperature sensor 9, the conductor in the second linear cable 3 further comprises two second electrode conductors connected with the left arm electrode 5 and the right leg electrode 8, and the left arm electrode 5, the right leg electrode 8 and the body temperature sensor 9 are sequentially arranged at intervals along the direction of the second linear cable 3 away from the connector 1.

In a fifth embodiment, as shown in fig. 5, the physiological data monitoring sensing device comprises a body temperature sensor 9.

The physiological data monitoring and sensing device is provided with a connector 1, a first one-line cable 2 and a second one-line cable 3.

The number of the conductors in the first one-line cable 2 is three, and the three conductors are all first electrode conductors; the three first electrode conductors are respectively connected with the left arm electrode 5, the chest wall electrode 7 and the right leg electrode 8, and the left arm electrode 5, the chest wall electrode 7 and the right leg electrode 8 are sequentially arranged at intervals along the direction of the first one-line cable 2 away from the connector 1.

The conductor in the second linear cable 3 comprises a body temperature sensing conductor connected with a body temperature sensor 9, the conductor in the second linear cable 3 further comprises two second electrode conductors connected with a right arm electrode 4 and a left leg electrode 6, and the right arm electrode 4, the left leg electrode 6 and the body temperature sensor 9 are sequentially arranged at intervals along the direction of the second linear cable 3 away from the connector 1.

In a sixth embodiment, as shown in fig. 6, the physiological data monitoring sensing device comprises a body temperature sensor 9.

The physiological data monitoring and sensing device is provided with a connector 1, a first one-line cable 2 and a second one-line cable 3.

The number of the conductors in the first one-line cable 2 is three, and the three conductors are all first electrode conductors; the three first electrode conductors are respectively connected with the left arm electrode 5, the right arm electrode 4 and the right leg electrode 8, and the left arm electrode 5, the right arm electrode 4 and the right leg electrode 8 are sequentially arranged at intervals along the direction of the first one-line cable 2 away from the connector 1.

The conductors in the second linear cable 3 comprise a body temperature sensing conductor connected with a body temperature sensor 9, the conductors in the second linear cable 3 further comprise two second electrode conductors connected with the chest wall electrode 7 and the left leg electrode 6, and the chest wall electrode 7, the left leg electrode 6 and the body temperature sensor 9 are sequentially arranged at intervals along the direction of the second linear cable 3 far away from the connector 1.

In a seventh embodiment, as shown in fig. 7, the physiological data monitoring sensing device comprises a body temperature sensor 9.

The physiological data monitoring and sensing device is provided with a connector 1, a first one-line cable 2 and a second one-line cable 3.

The number of the conductors in the first one-line cable 2 is three, and the three conductors are all first electrode conductors; the three first electrode conductors are respectively connected with the right arm electrode 4, the left arm electrode 5 and the right leg electrode 8, and the right arm electrode 4, the left arm electrode 5 and the right leg electrode 8 are sequentially arranged at intervals along the direction of the first one-line cable 2 away from the connector 1.

The conductor in the second linear cable 3 comprises a body temperature sensing conductor connected with a body temperature sensor 9, the conductor in the second linear cable 3 further comprises two second electrode conductors connected with a chest wall electrode 7 and a left leg electrode 6, and the chest wall electrode 7, the left leg electrode 6 and the body temperature sensor 9 are sequentially arranged at intervals along the direction of the second linear cable 3 away from the connector 1.

In an eighth embodiment, as shown in fig. 8, the physiological data monitoring sensing device comprises a body temperature sensor 9.

The physiological data monitoring and sensing device is provided with a connector 1, a first one-line cable 2 and a second one-line cable 3.

The number of the conductors in the first one-line cable 2 is three, and the three conductors are all first electrode conductors; the three first electrode conductors are respectively connected with the right arm electrode 4, the chest wall electrode 7 and the right leg electrode 8, and the right arm electrode 4, the chest wall electrode 7 and the right leg electrode 8 are sequentially arranged at intervals along the direction of the first one-line cable 2 away from the connector 1.

The conductor in the second linear cable 3 comprises a body temperature sensing conductor connected with a body temperature sensor 9, the conductor in the second linear cable 3 further comprises two second electrode conductors connected with the left arm electrode 5 and the left leg electrode 6, and the left arm electrode 5, the left leg electrode 6 and the body temperature sensor 9 are sequentially arranged at intervals along the direction of the second linear cable 3 away from the connector 1.

In a ninth embodiment, as shown in fig. 9, the physiological data monitoring sensing device comprises a body temperature sensor 9.

The physiological data monitoring and sensing device is provided with a connector 1, a first one-line cable 2 and a second one-line cable 3.

The number of the conductors in the first one-line cable 2 is three, and the three conductors are all first electrode conductors; the three first electrode conductors are respectively connected with the left arm electrode 5, the right leg electrode 8 and the left leg electrode 6, and the left arm electrode 5, the right leg electrode 8 and the left leg electrode 6 are sequentially arranged at intervals along the direction of the first one-line cable 2 away from the connector 1.

The conductor in the second linear cable 3 comprises a body temperature sensing conductor connected with a body temperature sensor 9, the conductor in the second linear cable 3 further comprises two second electrode conductors connected with the right arm electrode 4 and the chest wall electrode 7, and the right arm electrode 4, the chest wall electrode 7 and the body temperature sensor 9 are sequentially arranged at intervals along the direction of the second linear cable 3 away from the connector 1.

In a tenth embodiment, as shown in fig. 10, the physiological data monitoring sensing device comprises a body temperature sensor 9.

The physiological data monitoring and sensing device is provided with a connector 1, a first one-line cable 2 and a second one-line cable 3.

The number of the conductors in the first one-line cable 2 is three, and the three conductors are all first electrode conductors; the three first electrode conductors are respectively connected with the left arm electrode 5, the left leg electrode 6 and the right leg electrode 8, and the left arm electrode 5, the left leg electrode 6 and the right leg electrode 8 are sequentially arranged at intervals along the direction of the first one-line cable 2 away from the connector 1.

The conductor in the second linear cable 3 comprises a body temperature sensing conductor connected with a body temperature sensor 9, the conductor in the second linear cable 3 further comprises two second electrode conductors connected with the right arm electrode 4 and the chest wall electrode 7, and the right arm electrode 4, the chest wall electrode 7 and the body temperature sensor 9 are sequentially arranged at intervals along the direction of the second linear cable 3 away from the connector 1.

In an eleventh embodiment, as shown in fig. 11, the physiological data monitoring sensing device comprises a body temperature sensor 9.

The physiological data monitoring and sensing device is provided with a connector 1, a first one-line cable 2 and a second one-line cable 3.

The number of the conductors in the first one-line cable 2 is three, and the three conductors are all first electrode conductors; the three first electrode conductors are respectively connected with the right arm electrode 4, the left leg electrode 6 and the right leg electrode 8, and the right arm electrode 4, the left leg electrode 6 and the right leg electrode 8 are sequentially arranged at intervals along the direction of the first one-line cable 2 away from the connector 1.

The conductor in the second linear cable 3 comprises a body temperature sensing conductor connected with a body temperature sensor 9, the conductor in the second linear cable 3 further comprises two second electrode conductors connected with the left arm electrode 5 and the chest wall electrode 7, and the left arm electrode 5, the chest wall electrode 7 and the body temperature sensor 9 are sequentially arranged at intervals along the direction of the second linear cable 3 away from the connector 1.

In a twelfth embodiment, as shown in fig. 12, the physiological data monitoring sensing device comprises a body temperature sensor 9.

The physiological data monitoring and sensing device is provided with a connector 1, a first one-line cable 2 and a second one-line cable 3.

The number of the conductors in the first one-line cable 2 is three, and the three conductors are all first electrode conductors; the three first electrode conductors are respectively connected with the right arm electrode 4, the right leg electrode 8 and the left leg electrode 6, and the right arm electrode 4, the right leg electrode 8 and the left leg electrode 6 are sequentially arranged at intervals along the direction of the first one-line cable 2 away from the connector 1.

The conductor in the second linear cable 3 comprises a body temperature sensing conductor connected with a body temperature sensor 9, the conductor in the second linear cable 3 further comprises two second electrode conductors connected with the left arm electrode 5 and the chest wall electrode 7, and the left arm electrode 5, the chest wall electrode 7 and the body temperature sensor 9 are sequentially arranged at intervals along the direction of the second linear cable 3 away from the connector 1.

As shown in fig. 13, the body temperature sensor 9 is positioned at the armpit of the human body, the right leg electrode 8, the left leg electrode 6, the left arm electrode 5, the right arm electrode 4 and the chest wall electrode 7 are positioned at the corresponding parts of the human body, and the connector 1 is positioned at the neck of the human body.

In the thirteenth embodiment, as shown in fig. 14, the physiological data monitoring and sensing device does not include the body temperature sensor 9, i.e., the physiological data monitoring and sensing device is a 5-lead electrocardiograph.

The physiological data monitoring and sensing device is provided with a connector 1, a first one-line cable 2 and a second one-line cable 3.

The number of the conductors in the first one-line cable 2 is three, and the three conductors are all first electrode conductors; the three first electrode conductors are respectively connected with the right arm electrode 4, the left arm electrode 5 and the left leg electrode 6, and the right arm electrode 4, the left arm electrode 5 and the left leg electrode 6 are sequentially arranged at intervals along the direction of the first one-line cable 2 away from the connector 1.

The conductors in the second linear cable 3 include two second electrode conductors connected to the chest wall electrode 7 and the right leg electrode 8, wherein the chest wall electrode 7 and the right leg electrode are sequentially arranged at intervals in a direction in which the second linear cable 3 is away from the connector 1.

In the fourteenth embodiment, as shown in fig. 15, the physiological data monitoring and sensing device does not include the body temperature sensor 9, i.e., the physiological data monitoring and sensing device is a 5-lead electrocardiograph.

The physiological data monitoring and sensing device is provided with a connector 1, a first one-line cable 2 and a second one-line cable 3.

The number of the conductors in the first one-line cable 2 is three, and the three conductors are all first electrode conductors; the three first electrode conductors are respectively connected with the left arm electrode 5, the right arm electrode 4 and the left leg electrode 6, and the left arm electrode 5, the right arm electrode 4 and the left leg electrode 6 are sequentially arranged at intervals along the direction of the first one-line cable 2 away from the connector 1.

The conductors in the second linear cable 3 include two second electrode conductors connected to the chest wall electrode 7 and the right leg electrode 8, wherein the chest wall electrode 7 and the right leg electrode 8 are sequentially arranged at intervals along the direction in which the second linear cable 3 is far away from the connector 1.

In the fifteenth embodiment, as shown in fig. 16, the physiological data monitoring and sensing device does not include the body temperature sensor 9, i.e., the physiological data monitoring and sensing device is a 5-lead electrocardiograph.

The physiological data monitoring and sensing device is provided with a connector 1, a first one-line cable 2 and a second one-line cable 3.

The number of the conductors in the first one-line cable 2 is three, and the three conductors are all first electrode conductors; the three first electrode conductors are respectively connected with the left arm electrode 5, the chest wall electrode 7 and the left leg electrode 6, and the left arm electrode 5, the chest wall electrode 7 and the left leg electrode 6 are sequentially arranged at intervals along the direction of the first one-line cable 2 away from the connector 1.

The conductors in the second linear cable 3 include two second electrode conductors connected to the right arm electrode 4 and the right leg electrode 8, wherein the right arm electrode 4 and the right leg electrode 8 are sequentially arranged at intervals in a direction in which the second linear cable 3 is away from the connector 1.

In a sixteenth embodiment, as shown in fig. 17, the physiological data monitoring sensing device does not include the body temperature sensor 9, i.e. the physiological data monitoring sensing device is a 5-lead electrocardiograph.

The physiological data monitoring and sensing device is provided with a connector 1, a first one-line cable 2 and a second one-line cable 3.

The number of the conductors in the first one-line cable 2 is three, and the three conductors are all first electrode conductors; the three first electrode conductors are respectively connected with the right arm electrode 4, the chest wall electrode 7 and the left leg electrode 6, and the right arm electrode 4, the chest wall electrode 7 and the left leg electrode 6 are sequentially arranged at intervals along the direction of the first one-line cable 2 away from the connector 1.

The conductors in the second linear cable 3 include two second electrode conductors connected to the left arm electrode 5 and the right leg electrode 8, wherein the left arm electrode 5 and the right leg electrode 8 are sequentially arranged at intervals along a direction in which the second linear cable 3 is away from the connector 1.

In the seventeenth embodiment, as shown in fig. 18, the physiological data monitoring sensing device does not include the body temperature sensor 9, i.e., the physiological data monitoring sensing device is a 5-lead electrocardiograph sensor.

The physiological data monitoring and sensing device is provided with a connector 1, a first one-line cable 2 and a second one-line cable 3.

The number of the conductors in the first one-line cable 2 is three, and the three conductors are all first electrode conductors; the three first electrode conductors are respectively connected with the right arm electrode 4, the chest wall electrode 7 and the right leg electrode 8, and the right arm electrode 4, the chest wall electrode 7 and the right leg electrode 8 are sequentially arranged at intervals along the direction of the first one-line cable 2 away from the connector 1.

The conductors in the second linear cable 3 include two second electrode conductors connected to the left arm electrode 5 and the left leg electrode 6, wherein the left arm electrode 5 and the left leg electrode 6 are sequentially arranged at intervals in a direction in which the second linear cable 3 is away from the connector 1.

In the eighteenth embodiment, as shown in fig. 19, the physiological data monitoring and sensing device does not include the body temperature sensor 9, i.e., the physiological data monitoring and sensing device is a 5-lead cardioelectric sensor.

The physiological data monitoring and sensing device is provided with a connector 1, a first one-line cable 2 and a second one-line cable 3.

The number of the conductors in the first one-line cable 2 is three, and the three conductors are all first electrode conductors; the three first electrode conductors are respectively connected with the right arm electrode 4, the left arm electrode 5 and the right leg electrode 8, and the right arm electrode 4, the left arm electrode 5 and the right leg electrode 8 are sequentially arranged at intervals along the direction of the first one-line cable 2 away from the connector 1.

The conductors in the second linear cable 3 include two second electrode conductors connected to the chest wall electrode 7 and the left leg electrode 6, wherein the chest wall electrode 7 and the left leg electrode 6 are sequentially arranged at intervals in a direction in which the second linear cable 3 is away from the connector 1.

As shown in fig. 20, in the nineteenth embodiment, the physiological data monitoring sensing device does not include the body temperature sensor 9, i.e., the physiological data monitoring sensing device is a 5-lead electrocardiograph.

The physiological data monitoring and sensing device is provided with a connector 1, a first one-line cable 2 and a second one-line cable 3.

The number of the conductors in the first one-line cable 2 is three, and the three conductors are all first electrode conductors; the three first electrode conductors are respectively connected with the right arm electrode 4, the left arm electrode 5 and the right leg electrode 8, and the right arm electrode 4, the left arm electrode 5 and the right leg electrode 8 are sequentially arranged at intervals along the direction of the first one-line cable 2 away from the connector 1.

The conductors in the second linear cable 3 include two second electrode conductors connected to the chest wall electrode 7 and the left leg electrode 6, wherein the chest wall electrode 7 and the left leg electrode 6 are sequentially arranged at intervals along a direction of the second linear cable 3 away from the connector 1.

As shown in fig. 21, in the twentieth embodiment, the physiological data monitoring sensing device does not include the body temperature sensor 9, i.e., the physiological data monitoring sensing device is a 5-lead electrocardiograph.

The physiological data monitoring and sensing device is provided with a connector 1, a first one-line cable 2 and a second one-line cable 3.

The number of the conductors in the first one-line cable 2 is three, and the three conductors are all first electrode conductors; the three first electrode conductors are respectively connected with the left arm electrode 5, the chest wall electrode 7 and the right leg electrode 8, and the left arm electrode 5, the chest wall electrode 7 and the right leg electrode 8 are sequentially arranged at intervals along the direction of the first one-line cable 2 away from the connector 1.

The conductors in the second linear cable 3 include two second electrode conductors connected to the right arm electrode 4 and the left leg electrode 6, wherein the right arm electrode 4 and the left leg electrode 6 are sequentially arranged at intervals in a direction in which the second linear cable 3 is away from the connector 1.

In a twenty-first embodiment, as shown in fig. 22, the physiological data monitoring sensing device does not include the body temperature sensor 9, i.e., the physiological data monitoring sensing device is a 5-lead electrocardiograph.

The physiological data monitoring and sensing device is provided with a connector 1, a first one-line cable 2 and a second one-line cable 3.

The number of the conductors in the first one-line cable 2 is three, and the three conductors are all first electrode conductors; the three first electrode conductors are respectively connected with the right arm electrode 4, the right leg electrode 8 and the left leg electrode 6, and the right arm electrode 4, the right leg electrode 8 and the left leg electrode 6 are sequentially arranged at intervals along the direction of the first one-line cable 2 away from the connector 1.

The conductors in the second linear cable 3 include two second electrode conductors connected to the left arm electrode 5 and the chest wall electrode 7, wherein the left arm electrode 5 and the chest wall electrode 7 are sequentially arranged at intervals along the direction of the second linear cable 3 away from the connector 1.

In a twenty-second embodiment, as shown in fig. 23, the physiological data monitoring sensing device comprises a body temperature sensor 9, i.e. the physiological data monitoring sensing device is a 5-lead electrocardiograph.

The physiological data monitoring and sensing device is provided with a connector 1, a first one-line cable 2 and a second one-line cable 3.

The number of the conductors in the first one-line cable 2 is three, and the three conductors are all first electrode conductors; the three first electrode conductors are respectively connected with the right arm electrode 4, the left leg electrode 6 and the right leg electrode 8, and the right arm electrode 4, the left leg electrode 6 and the right leg electrode 8 are sequentially arranged at intervals along the direction of the first one-line cable 2 away from the connector 1.

The conductors in the second linear cable 3 include two second electrode conductors connected to the left arm electrode 5 and the chest wall electrode 7, wherein the left arm electrode 5 and the chest wall electrode 7 are sequentially arranged at intervals along the direction of the second linear cable 3 away from the connector 1.

In a twenty-third embodiment, as shown in fig. 24, the physiological data monitoring and sensing device does not include the body temperature sensor 9, i.e., the physiological data monitoring and sensing device is a 5-lead cardioelectric sensor.

The physiological data monitoring and sensing device is provided with a connector 1, a first one-line cable 2 and a second one-line cable 3.

The number of the conductors in the first one-line cable 2 is three, and the three conductors are all first electrode conductors; the three first electrode conductors are respectively connected with the left arm electrode 5, the left leg electrode 6 and the right leg electrode 8, and the left arm electrode 5, the left leg electrode 6 and the right leg electrode 8 are sequentially arranged at intervals along the direction of the first one-line cable 2 away from the connector 1.

The conductors in the second linear cable 3 include two second electrode conductors connected to the right arm electrode 4 and the chest wall electrode 7, wherein the right arm electrode 4 and the chest wall electrode 7 are sequentially arranged at intervals along the direction of the second linear cable 3 away from the connector 1.

In a twenty-fourth embodiment, as shown in fig. 25, the physiological data monitoring sensing device includes no body temperature sensor 9, i.e., the physiological data monitoring sensing device is a 5-lead electrocardiograph.

The physiological data monitoring and sensing device is provided with a connector 1, a first one-line cable 2 and a second one-line cable 3.

The number of the conductors in the first one-line cable 2 is three, and the three conductors are all first electrode conductors; the three first electrode conductors are respectively connected with the left arm electrode 5, the right leg electrode 8 and the left leg electrode 6, and the left arm electrode 5, the right leg electrode 8 and the left leg electrode 6 are sequentially arranged at intervals along the direction of the first one-line cable 2 away from the connector 1.

The conductors in the second linear cable 3 include two second electrode conductors connected to the right arm electrode 4 and the chest wall electrode 7, wherein the right arm electrode 4 and the chest wall electrode 7 are sequentially arranged at intervals along the direction of the second linear cable 3 away from the connector 1.

As shown in fig. 26, the right leg electrode 8, the left leg electrode 6, the left arm electrode 5, the right arm electrode 4, and the chest wall electrode 7 are located at corresponding positions of the human body, and the connector 1 is located at the neck of the human body.

In this embodiment, the second wire cable 3 of the physiological data monitoring and sensing device includes a body temperature sensing conductor. That is, in the present embodiment, the number of the conductors in the first inline cable 2 is three, and all of the three conductors are the first electrode conductors; when the body temperature sensor 9 is an NTC (negative temperature coefficient) sensor, two body temperature sensing conductors are required, and therefore, the number of the conductors in the second wire cable 3 is four, two of the conductors are second electrode conductors, and the other two conductors are body temperature sensing conductors.

For convenience of use and ease of manufacture, the body temperature sensor 9 is located at the end of the in-line cable remote from the connector 1, i.e. the end of the in-line cable. Of course, embodiments in which the body temperature sensor 9 is disposed at other locations are not excluded.

In view of the need to further reduce the overall cross-sectional size of the cable, the in-line cable further comprises a shield and a ground wire common to at least two mutually independent conductors disposed in the outer sheath; the shield and the ground wire are electrically connected. It will be appreciated that the shield may be a hollow cylindrical structure, the shield being located within the outer jacket, and all conductors and ground wires of the in-line cable being located within the shield. The shield and ground wires may be conductively connected to the connector 1 or a card of a host.

Wherein the voids within the shield may be filled with a filler.

The embodiment of the utility model provides a physiological data monitoring sensing device who still provides, reach the one-line cable of being connected with connector 1 including connector 1, a plurality of electrode. The one-line cable comprises an outer sheath, a shield, a ground wire and a plurality of mutually independent conductors, wherein the shield is positioned in the outer sheath, the ground wire and the plurality of conductors are positioned in the inner space of the shield, and the ground wire and any position of the shield are electrically connected. The electrodes are connected with the conductors in a one-to-one correspondence manner. Wherein the plurality of electrodes are arranged at intervals along the length direction of the one-line cable. When a plurality of electrodes are arranged on a single-wire cable, the shield needs to be opened so that the conductors in the shield can be led out and connected with the electrodes in a one-to-one correspondence manner. As shown in fig. 27 and 28, since the ground wire 200 is electrically connected to any position of the shield 100, when it is necessary to lead the conductor 300 (wire) in the shield 100 out of the shield 100, it is necessary to cut a part of the shield 100, and the function of the shield 100 can be secured even when the ground wire 200 is connected.

As above, the physiological data monitoring and sensing device provided by the embodiment of the present invention forms a linear cable by disposing a plurality of mutually independent conductors in an outer sheath, and effectively reduces the total cross-sectional size requirement of the cable compared with the case where each electrode is connected with an individual cable; because a line formula cable is connected with connector 1, consequently, can reduce connector 1's size demand, convenient miniaturized setting can effectively reduce physiological data monitoring sensing device's overall size, makes things convenient for wearing of physiological data monitoring sensing device.

And the plurality of electrodes are arranged at intervals along the length direction of the one-line cable, so that the positions of the plurality of electrodes on the one-line cable can be arranged according to human engineering, the wearing is further convenient, and the management is also convenient.

In this embodiment, the number of the electrodes and the conductors may be three, and thus, the physiological data monitoring and sensing device is a 3-lead electrocardiograph sensor.

The embodiment of the utility model provides a monitoring facilities is still provided, including physiological data monitoring sensing device and monitoring main part. The physiological data monitoring and sensing device is any one of the physiological data monitoring and sensing devices; the monitoring main body is in communication connection with the physiological data monitoring and sensing device and is used for basic operation.

The embodiment of the utility model provides a monitoring facilities because above-mentioned physiological data monitoring sensing device has above-mentioned technological effect, the monitoring system who has above-mentioned physiological data monitoring sensing device also has the same technological effect, no longer tired up one by one here.

In the first embodiment, the monitoring body is a wearable monitoring body which is directly connected with the connector 1 of the physiological data monitoring and sensing device and is worn on the human body; the wearable monitoring main body comprises a wearable connector and a monitoring host which is detachably arranged on the wearable connector; the physiological data monitoring and sensing device is connected with the wearable connector.

As shown in fig. 29, the connector 1 of the physiological data monitoring sensing device may have a mounting groove to the monitoring main body 400, and the monitoring main body 400 may be detachably disposed in the mounting groove of the connector 1.

In a second embodiment, the monitoring body is a wearable monitoring body for wearing on a human body; the connector 1 of the physiological data monitoring and sensing device is in wireless communication connection with the monitoring main body.

As shown in fig. 30, an embodiment of the present invention further provides a monitoring system, which includes a monitoring device and at least two monitoring devices wearable on a human body, wherein the at least two monitoring devices include at least one first monitoring device 110 and at least one second monitoring device 210. That is, there are at least two monitoring devices wearable on the human body, and the monitoring devices wearable on the human body include at least one first monitoring device 110 and at least one second monitoring device 210.

The first monitoring device 110 is any one of the monitoring devices described above, and is adapted to be worn on the torso of a human body, and the second monitoring device 210 is adapted to be worn on the limbs of the human body.

The wearing positions of the limbs of the human body can include arms, legs, wrists, ankles and the like, and are determined according to actual needs, and are not particularly limited herein.

Wherein, the monitoring device is a ward monitoring device 310 and/or a hospital monitoring device 410; the monitoring equipment at least comprises a first wireless communication module;

the first monitoring device 110 is in wireless communication with the second monitoring device 210, and at least one of the first monitoring device 110 and the second monitoring device 210 includes a second wireless communication module in communication with the first wireless communication module, so as to transmit the physiological parameters collected from the first monitoring device 110 and the second monitoring device 210 to the monitoring device through the second wireless communication module.

The embodiment of the utility model provides a monitoring system because above-mentioned monitor and monitoring system have above-mentioned technological effect, the monitoring system who has above-mentioned monitoring facilities or monitoring facilities also has the same ground technological effect, no longer tired one by one here.

It is understood that the first monitoring device 110 is a monitoring device worn on the torso of the human body, and therefore, the physiological data monitoring sensing device of the first monitoring device 110 may be an electrocardiograph sensor or other electrocardiographic composite parameter sensor with 5 lead or more. The connector 1 of the physiological data monitoring and sensing device is preferably arranged at the position of the trunk of the human body, such as the neck or the chest. In order to facilitate the installation of the connector 1 of the physiological data monitoring sensing device, it is preferable that the connector 1 of the physiological data monitoring sensing device is provided at the neckline of the human body, that is, the connector 1 of the physiological data monitoring sensing device is provided near the neck of the human body. In some embodiments, the first monitoring device 110 may be a parameter sensor including any two of an electrocardiogram parameter, a body temperature parameter, and a tissue oxygenation parameter. The various parameter sensors may be located at any of the plurality of sensors of the first monitoring device 110 shown in fig. 1-25. When the sensor is an electrocardio parameter sensor, the position of the sensor is generally set according to the medical universal electrocardio measuring position and distance shown in the figure 13; when a tissue oximetry sensor is used, the sensor is typically positioned in a location that facilitates measurement of either of the renal/muscular regions; in the case of a body temperature sensor, it is typically disposed at the end of a one-wire cable as shown in fig. 13. It should be understood that the position setting of the sensors of the respective parameters is not limited thereto, and may be arranged according to actual needs.

It can be understood that, since the first monitoring device 110 is in wireless communication connection with the second monitoring device 210, the monitoring device having the second wireless communication module can be used as a primary monitoring device, the primary monitoring device can be used as a HUB (multi-port repeater) in a human body local area network, and can transmit data such as physiological parameters to the outside. That is, the second wireless communication module of the main monitoring device is in communication connection with the first wireless communication module of the monitoring device, so that the corresponding physiological parameters acquired by the first monitoring device 110 and the second monitoring device 210 from the patient are timely transmitted to the monitoring device through the main monitoring device, so that the monitoring device can analyze the physical condition of the patient according to the physiological parameters, and provide the analysis result to the medical staff for the medical staff to take corresponding measures; or the main monitoring equipment completes partial or all physiological parameter analysis locally and sends the analysis result to the monitoring equipment so that medical personnel can take corresponding measures.

In another embodiment, the first monitoring device 110 and the second monitoring device 210 may both be used as the main monitoring device, that is, the first monitoring device 110 and the second monitoring device 210 both include a second wireless communication module for communicating with the first wireless communication module. Through the above arrangement, the first monitoring device 110 and the second monitoring device 210 can transmit data such as physiological parameters to the monitoring device independently and separately, and do not need to transmit the data together through a main monitoring device.

Of course, the two embodiments can be flexibly converted and implemented, and are not limited thereto.

The ward monitoring device 310 and the hospital monitoring device 410 are both remote devices, and the remote devices may be one or more of a bedside monitoring device, a central station, a flat panel display terminal, and the like. The remote device is convenient for a guardian such as a doctor or a nurse to monitor the user. In this embodiment, the ward-level monitoring device 310 may be a bedside monitor. The yard monitoring apparatus 410 may be a central station of a hospital.

In this embodiment, since the first monitoring device 110 is a monitoring device worn on the torso of the human body, and the first monitoring device 110 is any one of the monitoring devices described above, the connector 1 of the physiological data monitoring and sensing device of the first monitoring device 110 is disposed at the neck opening of the human body, that is, the connector 1 of the physiological data monitoring and sensing device is disposed near the neck of the human body. Because the fastness of the connector 1 of the fixed physiological data monitoring and sensing device at the neckline of the human body is not high, the second wireless communication module is preferably only arranged in the second monitoring equipment 210 worn at the four limbs of the human body, so that the size of the first monitoring equipment 110 is reduced, and the first monitoring equipment 110 is more convenient to wear.

In this embodiment, the types of the physiological parameters monitored by the first monitoring device 110 and the second monitoring device 210 may include blood oxygen, electrocardiogram, blood pressure, respiration, body temperature, and the like, which is not limited thereto.

Preferably, the number of the first monitoring device 110 and the second monitoring device 210 is one, and the first monitoring device 110 and the second monitoring device 210 are in wireless communication connection; the first monitoring device 110 is an electrocardiograph monitoring device, and the second monitoring device 210 is a blood oxygen monitoring device. That is, the blood oxygen monitoring device (second monitoring device 210) may be worn on the wrist or ankle of the patient at the location of the extremity to monitor the blood oxygen parameters of the patient. The electrocardiograph monitoring device (the first monitoring device 110) can be fixed on the clothes (such as the collar or the front garment piece) of the patient by means of a clip or the like, or can be directly attached to the skin of the patient, so as to monitor the electrocardiograph parameters of the patient.

In this embodiment, since the second wireless communication module is only disposed in the second monitoring device 210 worn on four limbs of the human body, the blood oxygen monitoring device (the second monitoring device 210) is used as a main monitoring device, and the blood oxygen monitoring device can transmit the obtained blood oxygen parameters and the obtained electrocardiograph parameters of the electrocardiograph monitoring device (the first monitoring device 110) to the ward-level monitoring device 310 and/or the hospital-level monitoring device 410.

In other embodiments, a second wireless communication module is disposed in each of the ecg monitoring device (the first monitoring device 110) and the blood oxygen monitoring device (the second monitoring device 210), and the blood oxygen monitoring device can transmit the obtained blood oxygen parameters to the ward monitoring device 310 and/or the hospital monitoring device 410. The cardiac monitoring device may transmit the acquired cardiac parameters to the ward-level monitoring device 310 and/or the yard-level monitoring device 410.

Furthermore, the ward monitoring device 310 and the ward monitoring device 410 may implement data transmission and receive and transmit control commands by way of wireless communication connection, so as to implement remote medical monitoring.

It is understood that the manner of Wireless Communication connection includes WMTS (Wireless Medical Telemetry Services), WLAN (Wireless Local Area Network), bluetooth, NFC (Near Field Communication), etc., without limitation. In the present specification, the embodiments are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (13)

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

a connector (1);

at least two in-line cables connected with the connector (1), wherein each in-line cable comprises an outer sheath and at least two mutually independent conductors positioned in the outer sheath;

a plurality of electrodes, each of which is connected to one of the conductors, and any two of which are connected to different ones of the conductors; the plurality of electrodes connected by the at least two mutually independent conductors are arranged along the length direction of the one-line cable on the same one-line cable.

2. The physiological data monitoring and sensing device according to claim 1, wherein the number of the one-line cables is two, and the two are a first one-line cable (2) and a second one-line cable (3).

3. The physiological data monitoring sensing device of claim 2, wherein the number of the plurality of electrodes is five, namely a right leg electrode (8), a left leg electrode (6), a left arm electrode (5), a right arm electrode (4) and a chest wall electrode (7);

at least two mutually independent conductors in the first one-to-one cable (2) comprise three first electrode conductors, and the three first electrode conductors are correspondingly connected with any three electrodes in the five electrodes one by one; at least two mutually independent conductors in the second linear cable (3) comprise two second electrode conductors, and the two second electrode conductors are correspondingly connected with the rest two electrodes in the five electrodes one by one.

4. Physiological data monitoring sensing device according to claim 3, wherein the connector (1) has a clip for securing to a garment;

the first one-line cable (2) is close to the electrode of the connector (1) and the second one-line cable (3) is close to the electrode of the connector (1) and is any two of the left arm electrode (5), the right arm electrode (4) and the chest wall electrode (7).

5. Physiological data monitoring sensing device according to any of claims 1 to 4, further comprising a body temperature sensor (9);

at least two mutually independent conductors included in the one-wire cable comprise body temperature sensing conductors connected with the body temperature sensor (9).

6. The physiological data monitoring sensing device according to claim 2, wherein the first in-line cable (2) comprises three electrodes spaced apart along the length of the first in-line cable (2), and the second in-line cable (3) comprises two electrodes spaced apart along the length of the second in-line cable (3) and a body temperature sensing conductor, wherein the body temperature sensing conductor is located at the end of the second in-line cable (3).

7. Physiological data monitoring sensing device according to claim 5, wherein the body temperature sensor (9) is located at an end of the in-line cable remote from the connector (1).

8. A physiological data monitoring and sensing device according to any one of claims 1 to 4, 6 and 7, wherein said in-line cable further comprises a shield and ground wire common to at least two mutually independent said conductors disposed in said outer sheath;

the shield and the ground wire are electrically connected.

9. A physiological data monitoring sensing device, comprising:

a connector (1);

the one-line cable is connected with the connector (1), and comprises an outer sheath, a shield, a ground wire and a plurality of mutually independent conductors, wherein the shield is positioned in the outer sheath, the ground wire and the plurality of conductors are positioned in the inner space of the shield, and any positions of the ground wire and the shield are electrically connected;

the electrodes are connected with the conductors in a one-to-one correspondence manner; the plurality of electrodes are arranged at intervals along the length direction of the one-line cable and are used for respectively measuring at least two physiological parameters.

10. The physiological data monitoring sensing device of claim 9 wherein the physiological parameters include at least two of an electrocardiogram parameter, a body temperature parameter, and a tissue oximetry parameter.

11. A monitor, comprising:

the physiological data monitoring sensing device of any one of claims 1-10;

and the monitoring main body is in communication connection with the physiological data monitoring and sensing device and is used for basic operation.

12. The monitor as claimed in claim 11, wherein the monitoring body is a wearable monitoring body directly connected with the connector (1) of the physiological data monitoring and sensing device and adapted to be worn on a human body;

the wearable monitoring main body comprises a wearable connector and a monitoring host which is detachably arranged on the wearable connector;

the physiological data monitoring and sensing device is connected with the wearable connector.

13. A monitoring system is characterized by comprising a monitoring device and at least two monitoring bodies wearable on a human body, wherein at least one first monitoring body and at least one second monitoring body are arranged in the at least two monitoring bodies;

the first monitoring body is the monitor of claim 11 or 12, which is adapted to be worn at the torso of a human body, and the second monitoring body is adapted to be worn at the limbs of a human body;

the monitoring equipment is ward-level monitoring equipment and/or hospital-level monitoring equipment;

the monitoring equipment at least comprises a first wireless communication module;

the first monitoring body is in wireless communication connection with the second monitoring body, and at least one of the first monitoring body and the second monitoring body comprises a second wireless communication module which is in communication with the first wireless communication module, so that the physiological parameters collected from the first monitoring body and the second monitoring body are transmitted to the monitoring equipment through the second wireless communication module.

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