CN214121057U - Conductor position detection device capable of being arranged in offset mode and lead processing equipment - Google Patents

Abstract

The utility model provides a conductor position detection device capable of being arranged in a biased manner and a lead processing device, which comprises a bracket, a first driving mechanism and a detection mechanism, wherein the first driving mechanism comprises a first supporting shaft and an installation slide block which are rotatably arranged on the bracket, and the installation slide block can move relative to the bracket along the extending direction of the first supporting shaft when the first supporting shaft rotates; detection mechanism fixed connection is on the installation slider, and can follow the extending direction of first supporting shaft and movably set up relatively the support for judge whether being located the detection area of assigned position by the conductor that is surveyed. The utility model provides a but conductor position detection device and wire processing equipment of biasing setting, through reverse adjustment detection mechanism's position in advance, the offset of compensation pyrocondensation pipe, and then wrap up the exposed conductor surface of the assigned position of wire with the pyrocondensation pipe accurately in the guarantee subsequent handling, increase application scope.

Description

Conductor position detection device capable of being arranged in offset mode and lead processing equipment

Technical Field

The utility model belongs to the technical field of the wire processing, more specifically say, relate to a but conductor position detection device and wire processing equipment of biasing setting.

Background

When two bundles of wires are spliced, the insulating skins of the two bundles of wires need to be cut off for one section, partial conductors are exposed respectively, the exposed partial conductors of the two bundles of wires are welded and connected, and then a section of insulating heat-shrinkable sleeve is coated outside the exposed conductors. In the automatic processing process, two bundles of conducting wires are required to be fixed and the exposed conductor is positioned at a specified position so as to coat the insulating heat-shrinkable sleeve on the surface of the exposed conductor; in the prior art, the position of a probe is manually adjusted in advance and then production is carried out, and a welded bare conductor is conveyed to a detection device for detection so as to judge whether a lead is at an appointed position or not, but the position of a detection mechanism cannot be adjusted in the production process; when the cross sectional areas of the two ends of the exposed conductor of the wire to be spliced are different, the heat-shrinkable tube can deviate, so that the insulating heat-shrinkable sleeve has the risk that the surface of the exposed conductor of the wire cannot be accurately wrapped, and the application range is limited.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a but conductor position detection device and wire processing equipment of biasing setting to solve the detection device that exists among the prior art and can't adjust detection mechanism's position in process of production, when the exposed conductor both ends cross-sectional area of the wire of reply production concatenation is different, the pyrocondensation pipe can produce the skew, leads to the heat shrinkage bush to have the risk that can't wrap up the exposed conductor surface of wire accurately, the limited technical problem of application scope.

In order to achieve the above object, the utility model adopts the following technical scheme: there is provided a biasable conductor position sensing device comprising:

a support;

the first driving mechanism comprises a first supporting shaft which is rotatably arranged on the bracket and a mounting sliding block which is arranged on the first supporting shaft, and the mounting sliding block can move relative to the bracket along the extending direction of the first supporting shaft when the first supporting shaft rotates; and

and the detection mechanism is fixedly connected to the mounting sliding block and can move along the extending direction of the first support shaft relative to the support, and is used for judging whether the detected conductor is located in a detection area of a designated position.

In one embodiment, the first support shaft includes a threaded section and a smooth section fixedly connected to the threaded section, and the mounting slider is threadedly connected to the threaded section.

In one embodiment, the first drive mechanism further comprises a support slide slidably disposed on the smooth section.

In one embodiment, a first knob is fixedly arranged on the first support shaft and used for driving the first support shaft to rotate relative to the bracket.

In one embodiment, the detection mechanism further comprises a swing frame and a first measurement assembly, the first measurement assembly comprises a first fixing frame fixedly connected with the swing frame and an offset measurement indicator arranged on the first fixing frame, and the offset measurement indicator can be matched with a reference mark fixed on the support and used for measuring the offset of the detection mechanism.

In one embodiment, the detection mechanism comprises a swing frame and a second driving mechanism, the swing frame is fixedly connected to the mounting sliding block, the second driving mechanism comprises a hollow driving rod, a second supporting shaft and a transmission assembly, the hollow driving rod is sleeved on one end of the first supporting shaft and can be rotatably arranged on the support, the second supporting shaft is rotatably arranged on the swing frame, and the transmission assembly is connected between the driving rod and the second supporting shaft.

In one embodiment, the first drive mechanism and the second drive mechanism are independent of each other.

In one embodiment, the first support shaft includes a threaded section and a smooth section fixedly connected to the threaded section, and an end of the smooth section, which is far away from the threaded section, is embedded in the driving rod.

In one embodiment, a second knob is fixedly arranged on the driving rod and used for driving the driving rod to rotate relative to the bracket.

In one embodiment, the detection mechanism further comprises a support arm arranged on the second support shaft and conductive probes rotatably arranged on the support arm, and a detection area for judging whether the conductor to be detected is located at the designated position is formed between the conductive probes.

In one embodiment, a first fixing frame is fixedly arranged on the swing frame, and a centering reference line is arranged on the first fixing frame and used for centering the conductive probe.

In one embodiment, the second support shaft includes a first threaded portion and a second threaded portion, the thread direction of the first threaded portion is opposite to the thread direction of the second threaded portion, the number of the support arms is plural, and the plurality of the support arms are in threaded connection with the second support shaft; when the second support shaft is rotated, the support arm at the first threaded portion and the support arm at the second threaded portion can be moved closer to or farther from each other.

In one embodiment, a compression spring is sleeved on the second support shaft, one end of the compression spring abuts against the swing frame, and the other end of the compression spring abuts against the support arm.

In one embodiment, the detection device further comprises a detection circuit electrically connected to the conductive probe.

In one embodiment, the detection mechanism further comprises a second measurement assembly, and the second measurement assembly comprises a second fixed frame fixedly connected with the swing frame and a graduated scale arranged on the second fixed frame and used for measuring the distance between two adjacent conductive probes.

In one embodiment, the transmission assembly includes a first gear fixedly connected to the circumferential outer wall of the driving rod and a second gear engaged with the first gear and fixedly connected to the second support shaft.

In one embodiment, the detection device further comprises a driving assembly for driving the swing frame to rotate relative to the support, the driving assembly comprises a connecting shaft, a driving cylinder arranged on the support and a transmission block rotatably arranged on the first support shaft, the connecting shaft is arranged between the transmission block and the installation sliding block in a penetrating manner, and the transmission block and the installation sliding block are arranged in a circumferential linkage manner.

The utility model also provides a wire processing equipment, but the conductor position detection device of foretell biasing setting including wire processingequipment, detection device is used for the position of wire processing front detection conductor.

In one embodiment, the wire processing device is a wire thermal compressor.

In one embodiment, the lead processing equipment further comprises a housing fixedly connected to the support, and the housing is provided with a reference mark for measuring the offset of the detection mechanism.

The utility model provides a but conductor position detection device of biasing setting's beneficial effect lies in: compared with the prior art, the utility model discloses a but conductor position detection device of biasing setting is through being provided with first actuating mechanism on the support, first actuating mechanism includes rotatable first supporting shaft that sets up on the support and sets up the installation slider on first supporting shaft, the installation slider can be when first supporting shaft rotates, move along the extending direction of first supporting shaft relative support, detection mechanism fixed connection is on the installation slider, and can be along the extending direction of first supporting shaft relative support movable setting, be used for judging whether surveyed conductor is located the detection area of assigned position, drive the installation slider along the extending direction of first supporting shaft relative support movement through driving first supporting shaft rotation, and then drive detection mechanism and adjust to the assigned detection area; when the conductor to be detected is located at the designated position, the plurality of conductive probes are contacted with the conductor to be detected, the plurality of conductive probes can be electrically connected through the conductor to be detected, and the detection circuit is connected; if the conductor to be detected is not at the designated position, the conductive probe can not be fully contacted with the conductor to be detected, and the detection circuit is disconnected. Therefore, whether the conductor to be detected is at the designated position can be judged according to whether the detection circuit is connected or not; when the cross sectional areas of the two ends of the exposed conductor of the wire to be spliced in production are different, the position of the detection mechanism is reversely adjusted in advance, the offset of the heat shrinkable tube is compensated, the heat shrinkable tube is accurately wrapped on the surface of the exposed conductor at the specified position of the wire in the subsequent process, and the application range is enlarged.

The utility model provides a wire processing equipment's beneficial effect lies in: compared with the prior art, the wire processing device of the utility model is provided with the wire processing device and the conductor position detection device which can be arranged in a biased way, the detection device is used for detecting the position of the conductor before the wire processing, the conductor position detection device which can be arranged in a biased way is provided with the first driving mechanism on the bracket, the first driving mechanism comprises the first supporting shaft which is rotatably arranged on the bracket and the installation slide block which is arranged on the first supporting shaft, the installation slide block can move relative to the bracket along the extending direction of the first supporting shaft when the first supporting shaft rotates, the detection mechanism is fixedly connected on the installation slide block and can be movably arranged relative to the bracket along the extending direction of the first supporting shaft for judging whether the detected conductor is positioned in the detection area of the designated position or not, and the installation slide block is driven to move relative to the bracket along the extending direction of the first supporting shaft by driving the first supporting shaft to rotate, further driving the detection mechanism to adjust to a specified detection area; when the conductor to be detected is located at the designated position, the plurality of conductive probes are contacted with the conductor to be detected, the plurality of conductive probes can be electrically connected through the conductor to be detected, and the detection circuit is connected; if the conductor to be detected is not at the designated position, the conductive probe can not be fully contacted with the conductor to be detected, and the detection circuit is disconnected. Therefore, whether the conductor to be detected is at the designated position can be judged according to whether the detection circuit is connected or not; when the cross sectional areas of the two ends of the exposed conductor of the wire to be spliced in production are different, the position of the detection mechanism is reversely adjusted in advance, the offset of the heat shrinkable tube is compensated, the heat shrinkable tube is accurately wrapped on the surface of the exposed conductor at the specified position of the wire in the subsequent process, and the application range is enlarged.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required for the embodiments or the prior art descriptions will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without inventive labor.

Fig. 1 is a schematic perspective view of a conductor position detecting device that can be disposed in an offset manner according to an embodiment of the present invention;

fig. 2 is a schematic perspective view of a bracket and a first driving mechanism of a conductor position detecting device that can be arranged in an offset manner according to an embodiment of the present invention;

fig. 3 is a schematic bottom view of a conductor position detecting device that can be disposed in an offset manner according to an embodiment of the present invention;

fig. 4 is a schematic top view of a conductor position detecting device capable of being disposed in an offset manner according to an embodiment of the present invention;

fig. 5 is a schematic cross-sectional structural diagram of a conductor position detecting device that can be disposed in an offset manner according to an embodiment of the present invention.

Wherein, in the figures, the respective reference numerals:

1-a scaffold; 2-a first drive mechanism; 21-a first support shaft; 211-a threaded segment; 212-smooth section; 22-mounting a slide block; 23-supporting the slide block; 24-a first knob; 25-a first measurement assembly; 251-a first mount; 252-offset measurement designation; 3-a detection mechanism; 31-a swing frame; 32-a second drive mechanism; 321-a drive rod; 322-a second support shaft; 323-a transmission assembly; 3231-first gear; 3232-second gear; 324-a second knob; 33-a support arm; 34-a conductive probe; 35-a second measuring assembly; 351-a second fixing frame; 352-scale; 4-a drive assembly; 41-a connecting shaft; 42-a driving cylinder; 43-a transmission block.

Detailed Description

In order to make the technical problem, technical solution and advantageous effects to be solved by the present invention more clearly understood, the following description is given in conjunction with the accompanying drawings and embodiments to illustrate the present invention in further detail. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or be indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or be indirectly connected to the other element.

It will be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in an orientation or positional relationship indicated in the drawings for convenience in describing the invention and to simplify the description, and are not intended to indicate or imply that the device or element so referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.

Referring to fig. 1 to fig. 3, the conductor position detecting device capable of being biased according to the present embodiment includes a bracket 1, a first driving mechanism 2, and a detecting mechanism 3, where specific structures and connection manners of the bracket 1, the first driving mechanism 2, and the detecting mechanism 3 are not limited. The first driving mechanism 2 comprises a first supporting shaft 21 rotatably arranged on the bracket 1 and a mounting slide block 22 arranged on the first supporting shaft 21 and used for fixedly connecting the detection mechanism 3, when the first supporting shaft 21 rotates, the mounting slide block 22 can drive the first supporting shaft 21 to rotate, moves relative to the bracket 1 along the extending direction of the first supporting shaft 21, the detection mechanism 3 is fixedly connected with the mounting slide block 22 and can be movably arranged relative to the bracket 1 along the extending direction of the first supporting shaft 21, a detection area for judging whether the detected conductor is positioned at the designated position, optionally, a first knob 24 is fixedly arranged on the first supporting shaft 21, the detection device is used for driving the first support shaft 21 to rotate relative to the support 1, an operator drives the first support shaft 21 to rotate by rotating the first knob 24, and drives the installation slide block 22 to move relative to the support 1 along the extending direction of the first support shaft 21, so as to drive the detection mechanism 3 to be adjusted to a specified detection area; optionally, the detection apparatus further includes a detection circuit, the detection circuit is electrically connected to the conductive probes 34, when the conductor to be detected of the lead is located at the designated position, the conductive probes 34 are in contact with the conductor to be detected, the conductive probes 34 can be electrically connected through the conductor to be detected, and then the detection circuit is turned on; if the conductor under test is not in the designated position, the conductive probe 34 cannot be fully contacted with the conductor under test, and the detection circuit is open. Therefore, whether the detected conductor is located at the designated position or not can be judged according to whether the detection circuit is connected or not, when the cross sectional areas of the two ends of the exposed conductor of the lead wire which is spliced in production are different, the position of the detection mechanism 3 is reversely adjusted in advance, the offset of the heat shrinkable tube is compensated, the heat shrinkable tube is accurately wrapped on the surface of the exposed conductor at the designated position of the lead wire in the subsequent process, and the application range is enlarged.

Referring to fig. 4, in the present embodiment, the detecting mechanism 3 further includes a swing frame 31 and a first measuring assembly 25, the first measuring assembly 25 includes a first fixing frame 251 fixedly connected to the swing frame 31 and an offset measuring mark 252 disposed on the first fixing frame 251, the offset measuring mark 252 can be matched with a reference mark fixed on the support 1 for measuring an offset of the detecting mechanism 3, the offset measuring mark 252 is stably mounted at a preset position on the swing frame 31 through the first fixing frame 251, when the detecting mechanism 3 is offset, the offset measuring mark 252 on the swing frame 31 generates an equivalent offset with respect to the reference mark on the support 1, so as to accurately measure the offset of the detecting mechanism 3, and further ensure that the heat shrinkable tube can be wrapped on the exposed conductor surface of the lead wire accurately.

Referring to fig. 2 to 4, in the present embodiment, the detecting mechanism 3 includes a swing frame 31 and a second driving mechanism 32, the swing frame 31 is fixedly connected to the mounting slider 22, the detecting device includes a driving assembly 4 for driving the swing frame 31 to rotate relative to the support 1, the driving assembly 4 drives the detecting mechanism 3 to rotate relative to the support 1, so as to swing the conductive probe 34 to the detecting area, and move away from the detecting area after the detection is completed, so as to prevent the conductive probe 34 from affecting the next processing operation. The driving assembly 4 comprises a connecting shaft 41, a driving cylinder 42 arranged on the support 1 and a transmission block 43 rotatably arranged on the first supporting shaft 21, the connecting shaft 41 is arranged between the transmission block 43 and the installation sliding block 22 in a penetrating mode, the transmission block 43 and the installation sliding block 22 are arranged in a circumferential linkage mode, the driving cylinder 42 drives the transmission block 43 on the first supporting shaft 21 to rotate relative to the first supporting shaft 21, the connecting shaft 41 is arranged between the transmission block 43 and the installation sliding block 22 in a penetrating mode, and therefore the transmission block 43 and the installation sliding block 22 are in circumferential linkage. The driving cylinder 42 has a telescopic piston rod, the piston rod is arranged in a telescopic manner, the piston rod is rotatably connected with the transmission block 43, and when the piston rod is telescopic, the transmission block 43 is pulled to rotate around the first supporting shaft 21. When the transmission block 43 rotates, the mounting slider 22 is driven to rotate around the first supporting shaft 21 through the connecting shaft 41, and the detection mechanism 3 is driven to swing to the detection area. Optionally, a plurality of installation sliders 22 for installing the detection mechanism 3 are arranged on the first support shaft 21, and the installation sliders 22 are respectively arranged on two sides of the transmission block 43, so that the detection mechanism 3 is more stably connected, and meanwhile, the swing frame 31 is more uniformly stressed in the swing process, and the reliability of the detection device is improved.

In one embodiment, whether the detection circuit is on or off may be indicated by a light or sound device, such as a light or an audible alarm disposed in the detection circuit. If the detection circuit is connected, the lamp emits light or the sound alarm emits sound to prompt an operator that the detection circuit is connected. In addition, the electric signal after the detection circuit is connected can be used as the condition of the next processing, the detection circuit is connected and outputs the electric signal, and the upper computer controls the processing equipment of the next processing to continue working according to the electric signal; if the detection circuit is not connected, no electric signal is output, and the upper computer controls the next processing equipment to stop working.

Referring to fig. 3 to fig. 5, as a specific embodiment of the conductor position detecting device capable of being disposed in an offset manner according to the present embodiment, the detecting mechanism 3 includes a swing frame 31 and a second driving mechanism 32, and the first driving mechanism 2 and the second driving mechanism 32 are independent from each other; the second driving mechanism 32 comprises a hollow driving rod 321 which is sleeved at one end of the first supporting shaft 21 and is rotatably arranged on the bracket 1, a second supporting shaft 322 which is rotatably arranged on the swing frame 31, and a transmission assembly 323 which is connected between the driving rod 321 and the second supporting shaft 322; the operator drives the driving rod 321 to rotate, so as to drive the transmission assembly 323 to rotate, and further drive the second supporting shaft 322 to rotate. Optionally, a second knob 324 is fixedly disposed on the driving rod 321, and is used for driving the driving rod 321 to rotate relative to the bracket 1, one end of the driving rod 321 is connected to the first supporting shaft 21, and the other end is fixedly connected to the second knob 324; optionally, first support shaft 21 includes screw thread section 211 and the smooth section 212 with screw thread section 211 fixed connection, actuating lever 321 is put into to the one end of keeping away from screw thread section 211 of smooth section 212, install the installation slider 22 that is used for fixed connection detection mechanism 3 on the screw thread section 211, installation slider 22 passes through threaded connection with screw thread section 211, make first support shaft 21 can drive installation slider 22 and remove along 1 relative support of extending direction of first support shaft 21 during rotating, and then drive detection mechanism 3 and remove to appointed detection area, put into hollow actuating lever 321 with smooth section 212, drive actuating lever 321 and rotate when preventing first support shaft 21 from rotating, the influence detects the precision, and can reduce the external resistance that first support shaft 21 received when rotating, the operating personnel of being convenient for operate. Optionally, the first driving mechanism 2 further includes a supporting slider 23 for fixedly connecting the swing frame 31, and the supporting slider 23 is slidably disposed on the smooth section 212, so that the connection of the detecting mechanism 3 is more stable, and meanwhile, the stress of the swing frame 31 is more uniform in the swing process, which is beneficial to improving the reliability of the detecting device. Optionally, the transmission assembly 323 includes a first gear 3231 fixedly connected to the circumferential outer wall of the driving rod 321 and a second gear 3232 engaged with the first gear 3231 and fixedly connected to the second support shaft 322, the second knob 324 is driven by an operator to rotate, the driving rod 321 is driven to rotate and drive the first gear 3231, the first gear 3231 rotates and drives the second gear 3232 engaged therewith to rotate, and then the second support shaft 322 fixedly connected to the second gear 3232 is driven to rotate, so that the gap between the conductive probes 34 is adjusted, and further the length of the detection area is adjusted.

Referring to fig. 1, fig. 3 and fig. 4, in the present embodiment, the detecting mechanism 3 further includes a supporting arm 33 disposed on the second supporting shaft 322 and a conductive probe 34 rotatably disposed on the supporting arm 33, such that the conductive probe 34 is firmly connected to the second supporting shaft 322, and a detecting area for determining whether the detected conductor is located at a designated position is formed between the conductive probes 34; the supporting arm 33 is a rod-shaped structure, one end of the supporting arm 33 is in threaded connection with the second supporting shaft 322, and the other end is rotatably provided with the conductive probe 34; optionally, a U-shaped frame is arranged at the end of the supporting arm 33 connected to the conductive probe 34, and a pin shaft for connecting the conductive probe 34 is arranged on the U-shaped frame, so that the conductive probe 34 can rotate around the pin shaft; optionally, the detecting mechanism 3 further includes an elastic resetting member, one end of the elastic resetting member is connected to the supporting arm 33, and the other end of the elastic resetting member is connected to the conductive probe 34, the elastic resetting member is used for keeping the conductive probe 34 in the initial position state, and when the conductive probe 34 is rotated relative to the supporting arm 33 and then leaves the initial position state, the elastic resetting member is used for resetting the conductive probe 34; optionally, the elastic return member is an extension spring; when the conductive probe 34 rotates relative to the supporting arm 33, the elastic restoring member is elongated to generate an elastic force, and the elastic force can help the conductive probe 34 restore. In the detection process, if the pressure of the conductive probe 34 on the conductor is too large, the conductive probe 34 can move relative to the supporting arm 33, so that the conductive probe 34 can be in close contact with the conductor, the conductor or the conductive probe 34 can be prevented from being damaged due to the excessive force applied by the conductive probe 34 on the conductor, the conductive probe 34 is reset through the elastic resetting piece, and the situation that the detection cannot be continued due to the fact that the conductive probe 34 moves relative to the supporting arm 33 is avoided. Optionally, a first fixing frame 251 is fixedly arranged on the swing frame 31, and a centering reference line is arranged on the first fixing frame 251 and used for centering the conductive probe 34, so that the position of the conductive probe 34 is centered and adjusted, the accuracy of the position of the conductive probe 34 is improved, and it is favorable for ensuring that the heat shrink tube can be accurately wrapped on the exposed conductor surface of the lead.

In one embodiment, the second support shaft 322 includes a first threaded portion and a second threaded portion, the thread direction of the first threaded portion is opposite to the thread direction of the second threaded portion, the number of the support arms 33 is plural, and the plurality of support arms 33 are in threaded connection with the second support shaft 322; when the second support shaft 322 rotates, the support arm 33 located at the first threaded portion and the support arm 33 located at the second threaded portion can be moved closer to or away from each other, so that the distance between two adjacent conductive probes 34 can be adjusted, and the application range is increased. Optionally, the detection mechanism 3 further includes a second measurement component 35, so that the operator can more intuitively obtain the distance between two adjacent conductive probes 34, the second measurement component 35 includes a second fixing frame 351 fixedly connected to the swing frame 31 and a scale 352 disposed on the second fixing frame 351 and used for measuring the distance between two adjacent conductive probes 34, the scale 352 is stably mounted at a preset position through the second fixing frame 351, the distance between two adjacent conductive probes 34 can be accurately measured, and the heat shrink tube can be further accurately wrapped on the exposed conductor surface of the lead. Optionally, the second support shaft 322 is sleeved with a compression spring, one end of the compression spring abuts against the swing frame 31, and the other end of the compression spring abuts against the support arm 33, so that a thread gap can be eliminated, the position of the support arm 33 is kept stable, and the influence on the detection effect caused by shaking in the detection process is avoided.

The utility model also provides a wire processing equipment, but including wire processingequipment and foretell conductor position detection device that the biasing set up, detection device is used for the position of wire processing front detection conductor. The conductor position detection device capable of being arranged in a biased mode is characterized in that a first driving mechanism 2 is arranged on a support 1, the first driving mechanism 2 comprises a first supporting shaft 21 and a mounting sliding block 22, the first supporting shaft 21 is rotatably arranged on the support 1, the mounting sliding block 22 is arranged on the first supporting shaft 21, the mounting sliding block 22 can move relative to the support 1 along the extending direction of the first supporting shaft 21 when the first supporting shaft 21 rotates, a detection mechanism 3 is fixedly connected to the mounting sliding block 22 and can be movably arranged relative to the support 1 along the extending direction of the first supporting shaft 21 and used for judging whether a detected conductor is located in a detection area at an appointed position, the mounting sliding block 22 is driven to move relative to the support 1 along the extending direction of the first supporting shaft 21 by driving the first supporting shaft 21 to drive the detection mechanism 3 to be adjusted to the appointed detection area; when the conductor to be detected is located at the designated position, the plurality of conductive probes 34 are contacted with the conductor to be detected, the plurality of conductive probes 34 can be electrically connected through the conductor to be detected, and then the detection circuit is connected; if the conductor under test is not in the designated position, the conductive probe 34 cannot be fully contacted with the conductor under test, and the detection circuit is open. Therefore, whether the conductor to be detected is at the designated position can be judged according to whether the detection circuit is connected or not; when the cross sectional areas of the two ends of the exposed conductor of the lead to be spliced are different, the position of the detection mechanism 3 is reversely adjusted in advance, the offset of the heat shrinkable tube is compensated, the heat shrinkable tube is accurately wrapped on the surface of the exposed conductor at the specified position of the lead in the subsequent process, and the application range is enlarged. The specific structure of the wire processing device is not limited, and optionally, the wire processing device is a wire thermal compressor; when the conductor to be detected is located at the designated position, the conductive probe 34 is moved away from the detection area so that the conductor processing device can process the conductor, and the insulating heat-shrinkable sleeve is sleeved on the conductor and covers the surface of the exposed conductor.

In one embodiment, the lead processing equipment further comprises a housing fixedly connected to the support 1, the housing is provided with a reference mark, the first fixing frame 251 of the swing frame 31 is provided with a centering reference line, and the reference mark on the housing can be matched with the centering reference line fixed on the first fixing frame 251 to measure the offset of the detection mechanism 3; when the detection mechanism 3 deviates, the centering reference line on the first fixing frame 251 deviates by an equivalent amount relative to the reference mark on the shell cover, so that the deviation of the detection mechanism 3 is accurately measured, and the heat shrink tube can be accurately wrapped on the surface of the exposed conductor of the lead.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the present invention, and any modifications, equivalents, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (20)

1. An offset settable conductor position sensing device, comprising:

a support;

the first driving mechanism comprises a first supporting shaft which is rotatably arranged on the bracket and a mounting sliding block which is arranged on the first supporting shaft, and the mounting sliding block can move relative to the bracket along the extending direction of the first supporting shaft when the first supporting shaft rotates; and

and the detection mechanism is fixedly connected to the mounting sliding block and can move along the extending direction of the first support shaft relative to the support, and is used for judging whether the detected conductor is located in a detection area of a designated position.

2. The biasable conductor position sensing device of claim 1, wherein: the first support shaft comprises a threaded section and a smooth section fixedly connected with the threaded section, and the mounting sliding block is connected with the threaded section through threads.

3. The biasable conductor position sensing device of claim 2, wherein: the first driving mechanism further comprises a supporting slide block, and the supporting slide block is slidably arranged on the smooth section.

4. The biasable conductor position sensing device of claim 1, wherein: and a first knob is fixedly arranged on the first support shaft and used for driving the first support shaft to rotate relative to the support.

5. The biasable conductor position sensing device of claim 1, wherein: the detection mechanism further comprises a swing frame and a first measurement assembly, the first measurement assembly comprises a first fixing frame fixedly connected with the swing frame and an offset measurement indication arranged on the first fixing frame, and the offset measurement indication can be fixed on the reference mark on the support in a matched mode and is used for measuring the offset of the detection mechanism.

6. The biasable conductor position sensing device of claim 1, wherein: detection mechanism includes swing span and second actuating mechanism, swing span fixed connection is in on the installation slider, second actuating mechanism establishes including the cover first supporting shaft one end and rotatable setting are in hollow actuating lever, rotatable setting on the support are in second supporting shaft on the swing span, and connect the actuating lever with transmission assembly between the second supporting shaft.

7. The biasable conductor position sensing device of claim 6, wherein: the first drive mechanism and the second drive mechanism are independent of each other.

8. The biasable conductor position sensing device of claim 6, wherein: the first support shaft comprises a threaded section and a smooth section fixedly connected with the threaded section, and the driving rod is arranged at one end, far away from the threaded section, of the smooth section.

9. The biasable conductor position sensing device of claim 6, wherein: and a second knob is fixedly arranged on the driving rod and used for driving the driving rod to rotate relative to the bracket.

10. The biasable conductor position sensing device of claim 6, wherein: the detection mechanism further comprises a supporting arm arranged on the second supporting shaft and conductive probes rotatably arranged on the supporting arm, and a detection area used for judging whether the detected conductor is located at a specified position is formed between the conductive probes.

11. The biasable conductor position sensing device of claim 10, wherein: the conductive probe is characterized in that a first fixing frame is fixedly arranged on the swinging frame, and a centering reference line is arranged on the first fixing frame and used for centering the conductive probe.

12. The biasable conductor position sensing device of claim 10, wherein: the second support shaft comprises a first threaded portion and a second threaded portion, the thread direction of the first threaded portion is opposite to that of the second threaded portion, the number of the support arms is multiple, and the support arms are in threaded connection with the second support shaft; when the second support shaft is rotated, the support arm at the first threaded portion and the support arm at the second threaded portion can be moved closer to or farther from each other.

13. The biasable conductor position sensing device of claim 10, wherein: and a compression spring is sleeved on the second supporting shaft, one end of the compression spring abuts against the swing frame, and the other end of the compression spring abuts against the supporting arm.

14. The biasable conductor position sensing device of claim 10, wherein: the detection device further comprises a detection circuit, and the detection circuit is electrically connected with the conductive probe.

15. The biasable conductor position sensing device of claim 10, wherein: the detection mechanism further comprises a second measuring assembly, and the second measuring assembly comprises a second fixing frame fixedly connected with the swing frame and a graduated scale which is arranged on the second fixing frame and used for measuring the distance between every two adjacent conductive probes.

16. The biasable conductor position sensing device of claim 6, wherein: the transmission assembly comprises a first gear fixedly connected to the circumferential outer wall of the driving rod and a second gear meshed with the first gear and fixedly connected with the second supporting shaft.

17. The biasable conductor position sensing device of claim 6, wherein: detection device is still including being used for the drive the swing span is relative support pivoted drive assembly, drive assembly includes the connecting axle, sets up drive actuating cylinder and rotatable setting on the support are in the epaxial transmission piece of first support, the connecting axle is worn to establish the transmission piece with between the installation slider, will the transmission piece with installation slider circumference linkage sets up.

18. A wire processing apparatus characterized in that: comprising wire processing means and an offsetable conductor position sensing means as claimed in any one of claims 1 to 17 for sensing the position of the conductor prior to wire processing.

19. The wire processing apparatus of claim 18, wherein: the lead processing device is a lead thermal shrinkage machine.

20. The wire processing apparatus of claim 18, wherein: the wire processing equipment further comprises a shell cover fixedly connected to the support, and a reference mark is arranged on the shell cover and used for measuring the offset of the detection mechanism.

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