CN212182723U - Connecting wire and medical assembly - Google Patents

Abstract

The utility model provides a connecting wire and medical treatment subassembly, the connecting wire includes: the cable comprises a conducting wire, a first cable section, a second cable section and an insulating sleeve, wherein a first end of the first cable section is provided with a first connector, and a second end of the first cable section is connected with the conducting wire; the first connecting end of the second cable section is provided with a second connector, and the second connecting end of the second cable section is connected with the conducting wire; the insulating cover overcoat is in the wire, and the one end of insulating cover cup joints with the second end of first cable section, and the other end of insulating cover cup joints with the second connection end of second cable section, and the insulating cover is all movable for wire, first cable section and second cable section. According to the utility model discloses a connecting wire, in the use of the equipment of being connected with it, equipment can drive the wire through first cable section or second cable section and for the rotatory winding of insulating cover, makes the connecting wire have rotatory winding function, has effectively avoided in the equipment use, does not have the problem that the normal use of equipment is influenced to rotatory winding function because of the connecting wire.

Description

Connecting wire and medical assembly

Technical Field

The utility model relates to the technical field of medical equipment, especially, relate to a connecting wire and medical treatment subassembly.

Background

The cable type extension wire of the existing electronic equipment does not have the function of anti-rotation winding because the requirements of integrity, continuity, safety and the like are required to be met, and the cable type extension wire has the following defects: when the function of the equipment requires continuous wire cutting and multi-turn rotation, the extension wire can be wound to influence the normal use of the equipment. When the extension lead is seriously wound, the operation must be stopped, the extension lead plug is pulled down, and the extension lead is reconnected after the extension lead is loosened to restore the work. If the extension lead is too hard and thick, the normal use and the function of the equipment are also influenced.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to solve in the equipment use, the connecting wire does not possess anti rotatory winding function and influences the problem that equipment used, the utility model provides a connecting wire and medical treatment subassembly.

According to the utility model discloses connecting wire, include:

a wire;

a first cable section having a first connector at a first end thereof and connected to the conductor at a second end thereof;

the first connecting end of the second cable section is provided with a second connector, and the second connecting end of the second cable section is connected with the lead;

the insulating sleeve, the insulating sleeve overcoat in the wire, the one end of insulating sleeve with the second end of first cable section cup joints, the other end of insulating sleeve with the second cable section the second link cup joints, the insulating sleeve is relative the wire, first cable section and the second cable section is all movable.

According to the utility model discloses the connecting wire, in the use of the equipment of being connected with it, equipment can drive the wire through first cable section or second cable section and carry out the rotation winding for insulating cover, makes the connecting wire have the rotation winding function, has effectively avoided in the equipment use, because of the connecting wire does not have the problem that the normal use of rotation winding function influences equipment.

According to some embodiments of the utility model, the wire is many, first cable section with second cable section all have with wire quantity is the same, and with many the wire corresponds many inner cores of connecting.

In some embodiments of the present invention, each of the wires has an insulating shield.

According to some embodiments of the present invention, the insulating sleeve is a transparent material.

In some embodiments of the present invention, one end of the insulating sleeve is movably sleeved on the outer sleeve or the inner sleeve of the first cable segment at the second end, and the other end of the insulating sleeve is movably sleeved on the outer sleeve or the inner sleeve of the second cable segment at the second connecting end.

According to some embodiments of the utility model, be close to on the first cable section second end department is equipped with the restriction insulating bush axial displacement's first backstop portion, be close to on the second cable section second connecting end department is equipped with second backstop portion.

According to some embodiments of the utility model, first backstop portion with second backstop portion is the ring form, first backstop portion with all be equipped with the spacing annular of circumference extension on the periphery wall of second backstop portion, the both ends of insulating cover be equipped with respectively with the spacing card reason of spacing annular looks adaptation.

The utility model discloses an in some embodiments, be close to on the first cable section first connector department is equipped with first handle portion, being close to of second cable section second connector department is equipped with second handle portion.

According to the utility model discloses medical treatment subassembly, include:

an operating device having a mating connector;

the connecting line is the connecting line, and the first connector is connected with the matched connector;

in the use process of the operating device, the operating device drives the first cable section and the conducting wire to rotate relative to the insulating sleeve.

According to the utility model discloses medical treatment subassembly, in operating equipment's use, operating equipment can drive the wire through first cable section and carry out the rotation winding for insulating cover, makes the connecting wire have the rotation winding function, has effectively avoided in the equipment use, because of the connecting wire does not have the problem that the normal use of rotation winding function influences equipment.

According to some embodiments of the present invention, the length of the first cable section is less than or equal to the length of the second cable section.

In some embodiments of the present invention, in the using process of the operating device, the operating device needs to drive the first cable segment and the conductor relative to the more frequent the insulating sleeve rotates, the larger the preset length of the conductor is.

Drawings

Fig. 1 is a schematic structural diagram of a connection line according to an embodiment of the present invention, wherein the connection line is in an unrotated winding state;

fig. 2 is a schematic structural diagram of a connection line according to an embodiment of the present invention, wherein the connection line is in a rotating winding state;

FIG. 3 is a schematic diagram of a partial structure of a connection line according to another embodiment of the present invention;

FIG. 4 is a schematic diagram of a portion of the connecting line shown in FIG. 3 from another view;

FIG. 5 is a partial cross-sectional view of the connecting wires shown in FIG. 3;

FIG. 6 is a schematic view of a portion of the connecting wires shown in FIG. 3;

fig. 7 is a schematic structural diagram of a first stopping portion of the connecting wire shown in fig. 3;

fig. 8 is a schematic structural view of a second stopper portion of the connecting line shown in fig. 3;

FIG. 9 is a schematic structural view of an insulating sheath of the connecting wire shown in FIG. 3;

fig. 10 is a cross-sectional view of the insulating sleeve shown in fig. 9.

A connecting line 100;

a wire 10;

the first cable segment 20, the first connecting head 210, the first handle part 220, the first stopping part 230 and the limiting ring groove 231;

a second cable segment 30, a second connector 310, a second handle 320, a second stopper 330;

insulating sleeve 40, spacing card edge 410.

Detailed Description

To further illustrate the technical means and effects of the present invention adopted to achieve the predetermined objects, the present invention will be described in detail below with reference to the accompanying drawings and preferred embodiments.

As shown in fig. 1, the connecting line 100 according to the embodiment of the present invention includes: a conductor 10, a first cable segment 20, a second cable segment 30, and an insulating jacket 40.

Wherein a first end of the first cable segment 20 has a first connector 210, and a second end of the first cable segment 20 is connected to the conductor 10. As shown in fig. 1, the first end of the first cable segment 20 may be the left end of the first cable segment 20 shown in fig. 1, and the left end of the first cable segment 20 has a first connector 210, so that the connection line 100 may be connected to other devices through the first connector 210. The second end of the first cable segment 20 may be the right end of the first cable segment 20 shown in fig. 1, the right end of the first cable segment 20 being connected with the left end of the conductor 10.

The first connection end of the second cable section 30 has a second connector 310, and the second connection end of the second cable section 30 is connected to the conductor 10. As shown in fig. 1, the first connection end of the second cable segment 30 may be the right end of the second cable segment 30 shown in fig. 1, and the right end of the second cable segment 30 has a second connector 310, so that the connection line 100 can be connected with other devices through the second connector 310. The second connection end of the second cable segment 30 may be the left end of the second cable segment 30 shown in fig. 1, and the left end of the second cable segment 30 is connected with the right end of the conductor 10.

The insulation cover 40 is sleeved on the conductive wire 10, one end of the insulation cover 40 is sleeved on the second end of the first cable section 20, the other end of the insulation cover 40 is sleeved on the second connecting end of the second cable section 30, and the insulation cover 40 is movable relative to the conductive wire 10, the first cable section 20 and the second cable section 30.

It should be noted that the connection line 100 can be connected to the operation device through the first connector 210, and connected to other related devices through the second connector 310. As shown in fig. 2, during the operation of the operating device, the first cable segment 20 can rotate the conducting wire 10 relative to the insulating sheath 40, so that the connecting wire 100 can have a function of rotating and winding to avoid affecting the normal use of the operating device.

According to the utility model discloses connecting wire 100, in the use of the equipment of being connected with it, equipment can drive wire 10 through first cable section 20 or second cable section 30 and carry out the rotation winding for insulating cover 40, makes connecting wire 100 have the rotation winding function, has effectively avoided in the equipment use, because of connecting wire 100 does not have the rotation winding function and influences the problem of the normal use of equipment.

According to some embodiments of the present invention, as shown in fig. 1 and 2, the wires 10 may be multiple, and the first cable segment 20 and the second cable segment 30 both have multiple inner cores, which are the same in number as the wires 10 and correspondingly connected to the multiple wires 10. It should be noted that the number of the wires 10 and the cores in the first cable segment 20 and the second cable segment 30 can be designed according to the functional requirements of the device connected to the connection cable 100. It will be appreciated that in some particular arrangements, the conductor 10 may be provided as a single conductor. Accordingly, each of the first and second cable segments 20 and 30 has an inner core connected to the conductor 10.

In some embodiments of the present invention, each wire 10 has an insulating sheath. It should be noted that, when the conductor 10 is a single conductor, the insulation sheath 40 is disposed outside the single conductor, and thus, the insulation sheath may not be disposed on the conductor 10 alone. When there are a plurality of wires 10, each wire 10 needs to be provided with an insulating shielding sleeve. Therefore, the wires 10 can be insulated from each other, and the problem that the wires 10 contact each other to cause a conductive short circuit when the wires 10 are wound in a rotating manner can be avoided.

According to some embodiments of the present invention, the insulating sheath 40 is a transparent material. It should be noted that, the insulating sleeve 40 is made of a transparent material, so that the winding condition of the wire 10 in the insulating sleeve 40 can be observed conveniently. When the wire 10 is found to be wound too tightly, the connection between the connection wire 100 and other devices can be timely disconnected, and the wire 10 which is wound in a rotating way is reversely rotated and restored to the initial state shown in fig. 1. Therefore, the problem that the wire 10 is wound too tightly to cause overlarge stress and break damage is effectively avoided.

In some embodiments of the present invention, one end of the insulating sleeve 40 is movably sleeved outside or inside the second end of the first cable segment 20, and the other end of the insulating sleeve 40 is movably sleeved outside or inside the second connecting end of the second cable segment 30. As shown in fig. 1 and 2, the left end of the insulating sleeve 40 may be sleeved on the right end of the first cable segment 20, the right end of the insulating sleeve 40 may be sleeved on the left end of the second cable segment 30, and the insulating sleeve 40 may rotate circumferentially relative to both the first cable segment 20 and the second cable segment 30, and the insulating sleeve 40 may also move axially along the extension direction of the conductor 10 relative to the first cable segment 20 and the second cable segment 30. Of course, the left end of the insulating sleeve 40 may be internally sleeved on the right end of the first cable section 20, and the right end of the insulating sleeve 40 may be internally sleeved on the left end of the second cable section 30.

According to some embodiments of the present invention, a first stopping portion 230 is disposed on the first cable segment 20 near the second end for limiting the axial movement of the insulating sleeve 40, and a second stopping portion 330 is disposed on the second cable segment 30 near the second connecting end. It should be noted that the "axial" direction described herein is understood to be an extending direction of the central axis of the insulating sheath 40. As previously described, the insulating jacket 40 may be displaced relative to the first and second cable segments 20, 30 in a delayed axial direction. Therefore, the axial moving range of the insulating sleeve 40 can be effectively limited by the arrangement of the first stopping portion 230 and the second stopping portion 330, and the insulating sleeve 40 is prevented from being separated from the shielding protection of the wire 10 due to an excessively large moving distance.

According to other embodiments of the present invention, as shown in fig. 3-8, first blocking portion 230 and second blocking portion 330 are both circular rings, first blocking portion 230 is sleeved on the right end of first cable segment 20, and second blocking portion 330 is sleeved on the left end of second cable segment 30.

As shown in fig. 5, 7 and 8, the outer peripheral walls of the first blocking portion 230 and the second blocking portion 330 are each provided with a circumferentially extending limiting ring groove 231. Accordingly, as shown in fig. 5, 9 and 10, the two ends of the insulation sleeve 40 are respectively provided with a position-limiting snap edge 410 which is matched with the position-limiting ring groove 231. As shown in fig. 5 and 7-10, the limiting snap edge 410 at the left end of the insulating sleeve 40 can be circumferentially and rotatably fitted in the limiting ring groove 231 of the first stopping portion 230, and the limiting snap edge 410 at the right end of the insulating sleeve 40 can be circumferentially and rotatably fitted in the limiting ring groove 231 of the second stopping portion 330.

It should be noted that first blocking portion 230 may be fixed to the right end of first cable segment 20, that is, first blocking portion 230 is immovable with respect to first cable segment 20; the second stopping portion 330 may be fixed to the left end of the second cable segment 30, that is, the second stopping portion 330 is immovable relative to the second cable segment 30. Thereby, the axial movement of the insulating sleeve 40 can be restricted by the first stopper 230 and the second stopper 330.

Of course, the first blocking portion 230 can also be movably sleeved on the right end of the first cable segment 20, and the second blocking portion 330 can also be movably sleeved on the left end of the second cable segment 30. Thereby, the insulating sleeve 40 can be moved in the axial direction.

In some embodiments of the present invention, a first handle portion 220 is disposed on the first cable segment 20 near the first connector 210, and a second handle portion 320 is disposed on the second cable segment 30 near the second connector 310. As shown in fig. 1 and 2, a first handle portion 220 is provided at the left end of the first cable segment 20. Thus, the first connection head 210 can be easily inserted and removed through the first handle part 220. A second handle portion 320 is provided on the second cable section 30. Therefore, the second connector 310 can be conveniently inserted into and pulled out of the second handle 320.

According to the utility model discloses medical treatment subassembly, include: operating equipment and connecting wires 100.

The operating device has a mating connector, the connecting line 100 is the connecting line 100 described above, and the first connecting connector 210 is connected to the mating connector.

During use of the handling device, the handling device brings the first cable section 20 and the conductor 10 into rotation relative to the insulating sheath 40.

According to the utility model discloses medical treatment subassembly, in operating equipment's use, operating equipment can drive wire 10 through first cable section 20 and carry out the rotation winding for insulating cover 40, makes connecting wire 100 have the rotation winding function, has effectively avoided in the equipment use, because of connecting wire 100 does not have the rotation winding function and influences the problem of the normal use of equipment.

According to some embodiments of the present invention, the length of the first cable segment 20 is less than or equal to the length of the second cable segment 30. It should be noted that by setting the length of the first cable segment 20 to be less than or equal to the length of the second cable segment 30, the distance of the conductor 10 from the operating device can be made relatively small. Therefore, when the operating device drives the first cable segment 20 to rotate during the use of the operating device, the rotating twisting force can be timely transmitted to the wire 10, so that the wire 10 is rotated and wound, and the connecting wire 100 has good rotating and winding performance.

In some embodiments of the present invention, the more frequently the operating device needs to drive the first cable section 20 and the conducting wire 10 to rotate relative to the insulating sheath 40 during the use of the operating device, the larger the preset length of the conducting wire 10. It should be noted that the length of the conductor 10 can be determined according to the number of core conductors of the cable and the expected number of rotations of the connected operating device, and the basic principle is as follows: the greater the number of core wires in the cable, the greater the number of rotations the device expects, and the longer the length of the dispersive wire 10.

According to some embodiments of the present invention, the operating device is a catheter movement control handle, the first connecting joint 210 of the connecting wire 100 is connected to a mating joint of the catheter movement control handle, and the length of the first cable segment 20 is not shorter than 5 cm. It should be noted that, during the use process, the catheter moving control handle will rotate circumferentially to control the catheter to rotate circumferentially. During the circumferential rotation of the catheter, the first cable segment 20 drives the wire 10 to rotate relative to the insulating sheath 40. As shown in fig. 2, the wire 10 can be wound in the insulating sheath 40 in a rotating manner, so that the connecting wire 100 has good performance of winding in a rotating manner, thereby avoiding the problem that the normal use of the catheter moving control handle is influenced because the connecting wire 100 cannot rotate.

The connection line 100 according to the present invention is described in detail below in two specific embodiments with reference to fig. 1 and 2. It is to be understood that the following description is only exemplary in nature and should not be taken as a specific limitation on the invention.

In the actual use process of many existing small-sized or portable electronic devices, one or more circles of rotation actions need to be completed intermittently or continuously. Since the cable-like extension wires connected to these devices do not have an anti-twisting function, the following problems often result: 1. since the twisted extension wire affects the operation and the function of the device, the operation has to be stopped, the extension wire plug is pulled out after the shutdown, and the operation is resumed after the twist is released. When such loosening operations are repeated repeatedly, the working efficiency, quality and safety of the equipment are affected. If the diameter of the extension wire is too thick and the material is too hard, the operation action of the equipment is limited or influenced, and the stability and the accuracy of the operation of the equipment are hindered. 3. As a result of frequent rotation of the device, excessive twisting and twisting of the extension wire can be caused, which on the one hand prevents proper operation of the extension wire passage area and on the other hand is prone to damage and failure of the extension wire.

The utility model provides a connecting wire 100 is a cable type extension wire with anti rotatory winding function, can guarantee under the prerequisite that does not influence equipment and normally connect, reaches following purpose: 1. the device connected with the connecting line 100 can rotate in one direction or two directions without influencing the use and the function of the device. 2. The anti-twisting ability of the connection cord 100 may be predetermined when the connection cord 100 is manufactured, and the attached device may be rotated arbitrarily within this range. 3. The appearance integrity of the connecting wire 100 is maintained, and the normal operation of the area through which the connecting wire 100 passes is not influenced. 4. Maintaining the overall insulation and shielding requirements of the connection line 100. 5. The discovery, judgment and release of the abnormal winding state caused by the excessive rotation are not influenced.

The first embodiment is as follows:

as shown in fig. 1 and 2, the connection line 100 includes: a conductor 10, a first cable segment 20, a second cable segment 30, and an insulating jacket 40.

Specifically, as shown in fig. 1, the connection line 100 has a plurality of parallel distributed wires 10, and each wire 10 has an insulation shielding sheath according to the design requirement of the device. The wires 10 are connected between the first cable segment 20 and the second cable segment 30, and each of the first cable segment 20 and the second cable segment 30 has a plurality of cores, the number of which is the same as that of the wires 10, and the cores are connected to the plurality of wires 10.

It should be noted that all the dispersion conductors 10 are complete continuations of the core conductors 10 of the cable sections at both ends thereof, i.e. the portion of the core of the first cable section 20 extending into the insulating sheath 40 is the corresponding conductor 10. The length of the segment of the dispersion conductor 10 depends mainly on the number of core conductors 10 of the cable and the number of intended turns of the connected working equipment, the basic principle being: the greater the number of core wires 10 in the cable, the greater the number of rotations the device expects, and the longer the length of the segment of the dispersion wire 10.

The left end of the first cable section 20 has a first connector 210, and the first connector 210 is an effective pin plug having the same number as the number of cores of the first cable section 20, and is used for connecting a mating interface of a working device. The second cable section 30 has a second connector 310 on the right. The first cable section 20 is provided with a first handle portion 220 near the first connector 210 for inserting or extracting the first connector 210 after being held. The second cable segment 30 is provided with a second handle portion 320 near the second connector 310 for gripping operation to insert or extract the second connector 310.

The insulation sleeve 40 is sleeved outside the lead 10, the insulation sleeve 40 is made of transparent insulation material, and a mesh-shaped shielding structure is arranged in the insulation sleeve. The insulating sleeve 40 is movable with respect to the conductor 10, the first cable segment 20, and the second cable segment 30. The diameter of the cable is larger than that of the cable, and the cable can independently rotate and move in a small range along the left and right long axes. The left end of the insulating sleeve 40 is movably sleeved on the right end of the first cable section 20, and the right end of the insulating sleeve 40 is movably sleeved on the left end of the second cable section 30. A first stopping portion 230 for limiting the axial movement of the insulating sleeve 40 is arranged on the first cable segment 20 near the right end, and a second stopping portion 330 is arranged on the second cable segment 30 near the left end.

The insulating sheath 40 has the following functions: limiting the discrete extent of the bundle of parallel dispersive wires 10; enhancing the shielding capabilities of the dispersive conductor 10; enhancing the insulation effect of the dispersion type wire 10; the rotation of the cables on the two sides at the position is realized, and the appearance integrity and the position stability of the cables are kept; the state and extent of the winding of the dispersion conductor 10 inside the jacket can be observed and evaluated.

The utility model provides an above-mentioned anti rotatory winding connecting wire 100's operating method as follows:

s1, checking the distributed conductors 10 in the movable transparent shielding sleeve to confirm that all the distributed conductors 10 are not wound and are distributed in a natural parallel direction (as shown in a state of figure 1).

And S2, connecting heads at two ends of the connecting wire 100 are respectively connected with the operation equipment and the related equipment.

S3, the connecting wires 100 are placed in a roughly linear mode.

And S4, operating equipment to rotate according to operation requirements.

S5, the winding degree of the distributed conductor 10 is observed conventionally through the movable transparent shielding sleeve, and normal operation cannot be influenced by common winding.

S6, when 10 sections of the distributed wires are wound cumulatively for a long time, and the whole process is tightly wound and contracted to be in a binding rope shape and generate surface traction tension, stopping working equipment, pulling off a plug, and restarting the operation after the distributed wires are completely unwound and wound.

The winding and unwinding method of the distributed conductor 10 section comprises the following steps: and pulling off the plug closest to the section, pressing or holding the limiting ring part at the far end of the section with one hand, and grasping the pulled plug of the lead 10 with the other hand, and rotating the lead 10 in the opposite direction of winding until the winding of the distributed lead 10 is completely loosened through observation of the movable transparent shielding sleeve, so that the state of the distributed lead is close to the natural parallel running state.

And S8, plugging the plug again, and recovering the operation of the equipment.

To sum up, the utility model provides a connecting wire 100 has following advantage:

the device connected with the connecting line 100 can rotate in one direction or two directions, and the use and the function of the device are not influenced. The strength of the anti-twisting ability of the connection line 100 can be preset during manufacturing, and the connected device can rotate freely within the range. The appearance integrity of the connecting wire 100 is maintained, and the normal operation of the area through which the connecting wire 100 passes is not influenced. The overall insulation and shielding of the connection line 100 meets the operational requirements. The discovery, judgment and release of the abnormal winding state caused by the excessive rotation are not influenced.

Example two:

as shown in fig. 3 to 10, unlike the first embodiment, in this embodiment, the first blocking portion 230 and the second blocking portion 330 are both circular ring-shaped, the first blocking portion 230 is sleeved on the right end of the first cable segment 20, and the second blocking portion 330 is sleeved on the left end of the second cable segment 30.

As shown in fig. 5, 7 and 8, the outer peripheral walls of the first blocking portion 230 and the second blocking portion 330 are each provided with a circumferentially extending limiting ring groove 231. Accordingly, as shown in fig. 5, 9 and 10, the two ends of the insulation sleeve 40 are respectively provided with a position-limiting snap edge 410 which is matched with the position-limiting ring groove 231. As shown in fig. 5 and 7-10, the limiting snap edge 410 at the left end of the insulating sleeve 40 can be circumferentially and rotatably fitted in the limiting ring groove 231 of the first stopping portion 230, and the limiting snap edge 410 at the right end of the insulating sleeve 40 can be circumferentially and rotatably fitted in the limiting ring groove 231 of the second stopping portion 330.

Thereby, the axial movement range of the insulating sleeve 40 can be limited by the first stopper portion 230 and the second stopper portion 330.

The technical means and functions of the present invention to achieve the intended purpose will be understood more deeply and concretely through the description of the embodiments, however, the attached drawings are only for reference and illustration, and are not intended to limit the present invention.

Claims (10)

1. A connector cable, comprising:

a wire;

a first cable section having a first connector at a first end thereof and connected to the conductor at a second end thereof;

the first connecting end of the second cable section is provided with a second connector, and the second connecting end of the second cable section is connected with the lead;

the insulating sleeve, the insulating sleeve overcoat in the wire, the one end of insulating sleeve with the second end of first cable section cup joints, the other end of insulating sleeve with the second cable section the second link cup joints, the insulating sleeve is relative the wire, first cable section and the second cable section is all movable.

2. The connecting wire according to claim 1, wherein the number of the wires is plural, and each of the first cable segment and the second cable segment has a plurality of inner cores, which are the same as the number of the wires and are correspondingly connected to the plural wires.

3. The connecting wire of claim 2, wherein each of said conductors has an insulating shield.

4. The connecting wire of claim 1, wherein the insulating sheath is a transparent material.

5. The connecting wire of claim 1, wherein one end of the insulating sleeve is movably sleeved outside or inside the second end of the first cable segment, and the other end of the insulating sleeve is movably sleeved outside or inside the second connecting end of the second cable segment.

6. The connection line of claim 1, wherein the first cable segment has a first stop adjacent the second end for limiting axial movement of the insulating jacket, and the second cable segment has a second stop adjacent the second connection end.

7. The connecting wire according to claim 6, wherein the first and second stopping portions are both circular rings, the outer peripheral walls of the first and second stopping portions are both provided with circumferentially extending limiting ring grooves, and both ends of the insulating sleeve are respectively provided with a limiting clip adapted to the limiting ring grooves.

8. The connecting cable of claim 1, wherein the first cable segment has a first handle portion adjacent to the first connector, and the second cable segment has a second handle portion adjacent to the second connector.

9. A medical assembly, comprising:

an operating device having a mating connector;

a connection line according to any one of claims 1 to 8, the first connector being connected to the mating connector;

in the using process of the operating device, the operating device drives the first cable section and the conducting wire to rotate relative to the insulating sleeve.

10. The medical assembly of claim 9, wherein the preset length of the wire is greater the more frequently the operating device is required to rotate the first cable segment and the wire relative to the insulating sheath during use of the operating device.

Images