CN112676498B - Processing device for multi-node thermocouple transient heat flow sensor - Google Patents

Abstract

The invention discloses a processing device of a multi-node thermocouple transient heat flow sensor, which comprises a multi-wire processing device for wrapping wires, wherein a plurality of nickel-chromium wire coils for winding bare wires and a plurality of constantan wire coils for winding enameled wires are arranged on the multi-wire processing device, an outer layer wrapping device which is connected with a plurality of bare wires and enameled wires and wraps the whole outer side of the bare wires and the enameled wires is arranged on the multi-wire processing device, and a wire drawing device for drawing the outer layer wrapping device to discharge a wrapped sensor structure is arranged on the side of the multi-wire processing device. According to the invention, the multiple wire restraining mechanisms are used for limiting, guiding and adjusting the bare wires on the plurality of nickel-chromium wire coils and the enameled wires on the plurality of constantan wire coils, so that the plurality of wires guided by the multiple wire restraining mechanisms are guided and restrained into the distribution shape of the sensor inner core to be processed, and the sensor is suitable for subsequent processing of the sensor.

Description

Processing device for multi-node thermocouple transient heat flow sensor

Technical Field

The invention relates to the technical field of thermocouple transient heat flow sensors, in particular to a processing device for a multi-node thermocouple transient heat flow sensor.

Background

The coaxial thermocouple transient heat flow sensor is an experimental component which utilizes Seebeck effects of different electrode materials to form electromotive force under different temperature gradient effects and measure the electromotive force so as to invert temperature and heat flow, is mainly used for aerospace hypersonic aircraft pneumatic experiments, hypersonic flow related experiments and the like, and has the characteristics of fast response, large measuring range, high precision, strong robustness and the like.

The thermocouple transient heat flow sensor can be divided into various types of inner cores according to different use requirements, the inner core structure of the thermocouple transient heat flow sensor comprises but is not limited to five-core single-measuring point, four-core single-measuring point, nine-core five-measuring point and single main core multi-measuring point, a general sensor processing device mainly processes specific inner core types, when the types of the processed sensor inner cores are changed, various devices on the processing device need to be adjusted, the operation is complex, and the distribution condition of wires of the inner cores is difficult to change rapidly according to the requirements.

In addition, when the existing sensor processing device is used for processing a sensor inner core and consists of more wires, certain gaps can exist among the wires in the conveying process, so that dislocation can occur due to uneven stress on the wires in the drawing process, the subsequent wrapping processing of the outer sides of the wires is not facilitated, and the qualified rate of processed sensor finished products is reduced.

Disclosure of Invention

The invention aims to provide a processing device for a multi-node thermocouple transient heat flow sensor, which is used for solving the problems that the distribution condition of each wire is difficult to rapidly change according to the type requirement of a sensor inner core and the distribution states of the wires are possibly misplaced in the drawing process of a plurality of wires in the prior art.

In order to solve the technical problems, the invention specifically provides the following technical scheme:

a multi-node thermocouple transient heat flow sensor processing device comprises a multi-wire processing device for wrapping wires, wherein a plurality of nickel-chromium wire coils for coiling bare wires and a plurality of constantan wire coils for coiling enameled wires are arranged on the multi-wire processing device;

the multi-wire material processing device is provided with a multi-wire material constraint mechanism for movably overlapping a plurality of bare wires on the nickel-chromium wire material roll and enameled wires on the constantan wire material roll, the inside of the multi-wire material constraint mechanism is respectively in limited overlapping connection with a plurality of wires through layering, the multi-wire material processing device is provided with a plurality of wires for drawing in the bare wires and the enameled wires on the nickel-chromium wire material roll, the multi-wire material extrusion forming mechanism for drawing in the bare wires and the enameled wires on the constantan wire material roll, the inner side of the multi-wire material extrusion forming mechanism is provided with a plurality of wires through a plurality of relative rolling clamping sleeves, and the multi-wire material extrusion forming mechanism is matched with the multi-wire material constraint mechanism for drawing in the plurality of wires limited by the multi-wire material constraint mechanism and shaping the distribution structure of the plurality of wires.

As a preferred scheme of the present invention, the multi-wire constraining mechanism includes a multi-plate seat frame fixedly mounted on the multi-wire processing device, a plurality of wire layer clamping mechanisms horizontally distributed and vertically adjusted along the multi-plate seat frame are mounted on an inner side of the multi-plate seat frame, and a plurality of wire guiding mechanisms moving left and right along the wire layer clamping mechanisms are mounted on the wire layer clamping mechanisms, and are used for movably sleeving corresponding wires, and the plurality of wire guiding mechanisms drive the corresponding wires to be arranged and distributed by adjusting their own arrangement.

As a preferable scheme of the present invention, the multi-layer plate holder frame is integrally a u-shaped structure perpendicular to the outer layer wrapping device, an inner side of the multi-layer plate holder frame is provided with an inner sliding groove along a central axis portion of the inner side of the multi-layer plate holder frame, and in-groove latches for cooperating with and movably engaging with the wire layer clamping mechanism are equidistantly distributed inside the inner sliding groove.

As a preferred scheme of the present invention, the wire layer snap-gauge mechanism includes an inner frame crosspiece transversely abutted against both sides of the inner frame chute, and the inner frame crosspiece is matched with the inner frame chute through both sides to slide up and down horizontally along the inner frame chute, both ends of the inner frame crosspiece are respectively provided with a torsion spring coupling plate connected with the crosspiece side fixing buckle, the crosspiece side fixing buckle tends to clamp the in-groove latch through the torsion spring coupling plate and is separated from the in-groove latch by pressing itself, and crosspiece engaging teeth for matching with the wire guiding mechanism to clamp and fix are equidistantly distributed on the inner frame crosspiece.

As a preferable scheme of the present invention, the wire guiding mechanism includes a crosspiece slide installed outside the crosspiece in the frame and moving laterally along the crosspiece in the frame, and a mechanically openable and closable abutting-type ferrule is installed on the crosspiece slide, and two interlocking engagement pieces are installed in the crosspiece slide and cooperate with the abutting-type ferrule in a closed state to automatically engage with the crosspiece engaging teeth at corresponding positions, and the abutting-type ferrule in an opened and closed state is driven by the interlocking engagement pieces and controls the interlocking engagement pieces to automatically disengage from the crosspiece engaging teeth.

As a preferable scheme of the present invention, the linkage engaging member includes two hinge members having end portions rotatably connected to the abutting type engaging sleeve, and middle end portions of the two hinge members are staggered and rotatably connected to the crosspiece slider, the two abutting type engaging sleeves are closed to drive tail ends of the two hinge members to engage with the crosspiece engaging teeth, and the outer sides of the two hinge members are both sleeved with spring springs for pressing the two abutting type engaging sleeves toward a closed state.

As a preferable scheme of the present invention, the multi-wire extrusion molding mechanism includes a clip-shaped mounting bracket having a fixed pattern between the multi-wire processing device and the multi-wire restraining mechanism and the outer layer wrapping device, a longitudinal pressing mechanism for pressing the plurality of wires vertically and a transverse pressing mechanism for pressing the plurality of wires horizontally are installed on an inner side of the clip-shaped mounting bracket, and an annular gathering ferrule for gathering the plurality of pressed wires is installed at a tail end of the clip-shaped mounting bracket.

As a preferable scheme of the invention, the longitudinal pressing mechanism comprises two in-frame sliding blocks respectively distributed at the upper end and the lower end of the clip-shaped mounting frame, a sliding block driving screw rod which extends to the outer side of the clip-shaped mounting frame and drives the in-frame sliding block to move up and down along the clip-shaped mounting frame is mounted on the in-frame sliding block, and a horizontally distributed extrusion roller for abutting against a wire rod is movably sleeved on the inner side of the clip-shaped mounting frame on the in-frame sliding block.

As a preferable scheme of the present invention, the structure of the transverse pressing mechanism is the same as that of the longitudinal pressing mechanism, and the two horizontally distributed squeezing rollers on the longitudinal pressing mechanism cooperate with the transverse pressing mechanism to form a structure shaped like a Chinese character 'jing' for squeezing the periphery of the multi-strand.

As a preferred scheme of the invention, the annular furling cutting sleeve is integrally and vertically fixed at the tail end wire outlet of the clip-shaped mounting rack, the inner diameter of the annular furling cutting sleeve is the same as the outer diameter of the inner core of the finished product sensor structure, and the circle center of the annular furling cutting sleeve always faces the input port of the outer layer wrapping device.

Compared with the prior art, the invention has the following beneficial effects:

(1) according to the invention, the multiple wire restraining mechanisms are used for limiting, guiding and adjusting the bare wires on the plurality of nickel-chromium wire coils and the enameled wires on the plurality of constantan wire coils, so that the plurality of wires guided by the multiple wire restraining mechanisms are guided and restrained into the distribution shape of the sensor inner core to be processed, and the sensor is suitable for subsequent processing of the sensor;

(2) according to the invention, when the multi-wire extrusion forming mechanism is arranged in the multi-wire extrusion forming mechanism, the plurality of bare wires and the enameled wires which are guided by constraint are constrained in a vertical pressing and a horizontal pressing manner, and finally the plurality of constrained bare wires and enameled wires are folded by the annular folding clamping sleeve, so that the wires distributed as required are prevented from being dislocated, and the subsequent device is convenient to wrap.

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 should be apparent that the drawings in the following description are merely exemplary, and that other embodiments can be derived from the drawings provided by those of ordinary skill in the art without inventive effort.

Fig. 1 provides an overall schematic connection diagram for an embodiment of the present invention.

Fig. 2 is a schematic structural view of a multi-wire restraining mechanism according to an embodiment of the present invention.

Fig. 3 is a cross-sectional view of a wire guide mechanism provided in an embodiment of the present invention.

Fig. 4 is a schematic diagram of a multi-wire extrusion molding mechanism according to an embodiment of the present invention.

Fig. 5 is a schematic connection diagram of a longitudinal pressing mechanism according to an embodiment of the present invention.

The reference numerals in the drawings denote the following, respectively:

1-a multi-wire processing device; 2-a nickel chromium wire coil; 3-constantan wire coil; 4-outer layer wrapping means; 5-a wire drawing device; 6-a multi-wire restraint mechanism; 7-a multi-wire extrusion forming mechanism;

61-multilayer plate seat frame; 62-wire layer snap gauge mechanism; 63-a wire guide mechanism;

611-in-frame sliding groove; 612-in-groove latch; 621-an inner frame rail; 622-fixing buckles on the lateral sides of the crosspieces; 623-crosspiece engaging teeth; 631-a rail slide; 632-butt-joint type ferrule; 633-linkage engaging member;

6331-elastic hinge; 6332-spring;

71-a clip mount; 72-longitudinal pressing mechanism; 73-transverse pressing mechanism; 74-annular furling cutting sleeve;

721-internal slide block; 722-a slider drive screw; 723-extrusion roller.

Detailed Description

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

As shown in fig. 1 to 5, the invention provides a multi-node thermocouple transient heat flow sensor processing device, which comprises a multi-wire processing device 1 for wrapping wires, wherein a plurality of nickel-chromium wire coils 2 for winding bare wires and a plurality of constantan wire coils 3 for winding enameled wires are arranged on the multi-wire processing device 1, an outer layer wrapping device 4 which is connected with a plurality of bare wires and enameled wires and wraps the whole outer side of the bare wires and the enameled wires is arranged on the multi-wire processing device 1, and a wire drawing device 5 for drawing the outer layer wrapping device 4 to discharge a wrapped sensor structure is arranged on the side of the multi-wire processing device 1;

install on many wire rod processingequipment 1 and be used for a plurality of nichrome wires of activity overlap joint to roll up bare wire and the many wire rod restraint mechanism 6 of the enameled wire of 3 is rolled up to constantan wire material on 2, and the inside of many wire rod restraint mechanism 6 is through the spacing a plurality of wire rods of overlap joint respectively of layering, install on the many wire rod processingequipment 1 and be used for drawing in a plurality of nichrome wires and roll up bare wire and a plurality of constantan wire and roll up the many wire rod extrusion mechanism 7 of the enameled wire of 3, and a plurality of wire rods of multiple relative roll extrusion cutting ferrule are passed through to the inboard of many wire rod extrusion mechanism 7, many wire rod extrusion mechanism 7 cooperates many wire rod restraint mechanism 6 to draw in a plurality of wire rods of 6 spacing of many wire rod restraint mechanism and stereotype the distribution structure of a plurality of wire rods.

According to the embodiment of the invention, the multiple wire restraining mechanism 6 is used for limiting, guiding and adjusting the bare wires on the plurality of nickel-chromium wire coils 2 and the enameled wires on the plurality of constantan wire coils 3, so that the plurality of wires guided by the multiple wire restraining mechanism 6 are guided and restrained into the distribution shape of the sensor inner core to be processed, and the sensor inner core processing device is suitable for the subsequent processing of the sensor;

in addition, when the multi-wire extrusion molding mechanism 7 is used, the plurality of bare wires and enameled wires guided by restraint are restrained by pressing up and down and pressing left and right, and finally the plurality of restrained bare wires and enameled wires are furled by the annular furling clamping sleeve 74, so that the deviation of the wire positions distributed as required is prevented, and the subsequent devices can conveniently perform wrapping processing.

Many wires restraint mechanism 6 includes multiply wood seat frame 61 of fixed mounting on many wires processingequipment 1, the line layer cardboard mechanism 62 of a plurality of horizontal distribution and adjustment from top to bottom along multiply wood seat frame 61 is installed to the inboard of multiply wood seat frame 61, and install a plurality of wire guiding mechanism 63 that remove about line layer cardboard mechanism 62 on the line layer cardboard mechanism 62, a plurality of wire guiding mechanism 63 are used for the activity to embolia corresponding wire rod, and a plurality of wire guiding mechanism 63 arrange through adjustment self and drive corresponding wire rod and arrange the distribution.

The multi-layer plate base frame 61 is integrally of a U-shaped structure perpendicular to the outer layer wrapping device 4, an in-frame sliding groove 611 along the axial line part inside the multi-layer plate base frame 61 is arranged on the inner side of the multi-layer plate base frame 61, and in-groove clamping teeth 612 used for being matched with the wire layer clamping plate mechanism 62 and movably clamping the wire layer clamping plate mechanism 62 are distributed in the in-frame sliding groove 611 at equal intervals.

The line layer cardboard mechanism 62 includes the frame inner crosspiece 621 of spout 611 both sides in the horizontal butt frame, and crosspiece 621 slides from top to bottom along the level in the spout 611 in the frame through both sides and the cooperation of spout 611 in the frame, the both ends of crosspiece 621 all install the torsion spring shaft plate 624 of being connected with crosspiece side fixed knot 622 in the frame, and crosspiece side fixed knot 622 through torsion spring shaft plate 624 tend to block inslot latch 612 and break away from inslot latch 612 through pressing itself, equidistant distribution has the crosspiece interlock tooth 623 that is used for cooperating wire rod guiding mechanism 63 block to fix on the frame crosspiece 621.

The wire guiding mechanism 63 includes a rail slide 631 installed outside the rail 621 in the frame and moving laterally along the rail 621 in the frame, and a docking type clamp sleeve 632 mechanically opened and closed is installed on the rail slide 631, and two linkage engaging pieces 633 matching with the docking type clamp sleeve 632 in a closed state and automatically engaging the rail engaging teeth 623 at corresponding positions are installed in the rail slide 631, and the opening and closing state of the docking type clamp sleeve 632 automatically disengages from the rail engaging teeth 623 by being transmitted with the linkage engaging pieces 633 and controlling the linkage engaging pieces 633.

The linkage engaging member 633 comprises two hinge members 6331 with two ends rotatably connected to the docking type engaging sleeve 632, the middle ends of the two hinge members 6331 are staggered and rotatably connected to the rail sliding base 631, the two docking type engaging sleeves 632 are closed to drive the tail ends of the two hinge members 6331 to engage with the rail engaging teeth 623, and the outer sides of the two hinge members 6331 are both sleeved with spring springs 6332 for pressing the two docking type engaging sleeves 632 to a closed state.

The multi-wire extrusion forming mechanism 7 comprises a shape-reversing mounting frame 71 which is fixed on the multi-wire processing device 1 and is positioned between the multi-wire restraining mechanism 6 and the outer-layer wrapping device 4, a longitudinal pressing mechanism 72 which presses a plurality of wires vertically and oppositely is arranged on the inner side of the shape-reversing mounting frame 71, a transverse pressing mechanism 73 which presses the plurality of wires leftwards and rightwards and a circular drawing clamping sleeve 74 which is used for drawing the plurality of pressed wires.

The longitudinal pressing mechanism 72 includes two in-frame sliding blocks 721 respectively distributed at the upper and lower ends of the clip-shaped mounting frame 71, and a sliding block driving screw 722 extending to the outside of the clip-shaped mounting frame 71 and driving the in-frame sliding blocks 721 to move up and down along the clip-shaped mounting frame 71 is installed on the in-frame sliding blocks 721, and a horizontally distributed squeezing roller 723 for abutting against the wire rod is movably sleeved on the inside of the in-frame sliding blocks 721 at the clip-shaped mounting frame 71.

The structure of the transverse pressing mechanism 73 is the same as that of the longitudinal pressing mechanism 72, and two horizontally distributed extrusion rollers 723 on the longitudinal pressing mechanism 72 are matched with the transverse pressing mechanism 73 to form a structure in a shape like a Chinese character 'jing' for extruding the periphery of a multi-thread material.

The annular furling cutting sleeve 74 is integrally and vertically fixed at the tail end wire outlet of the clip-shaped mounting frame 71, the inner diameter of the annular furling cutting sleeve 74 is the same as the outer diameter of the inner core of the finished product sensor structure, and the circle center of the annular furling cutting sleeve 74 always faces the input port of the wrapping device of the outer wrapping device 4.

When the sensor core processing device is used, bare wires on a plurality of nickel-chromium wire coils 2 and enameled wires on a plurality of constantan wire coils 3 need to pass through the wire guiding mechanisms 63 at corresponding positions in the multi-wire restraining mechanism 6 respectively according to the type of the sensor core to be processed, so that after the wires are guided by the multi-wire restraining mechanism 6, the wires are guided and restrained to be similar to the distribution situation of the sensor core to be processed.

If the distribution of the plurality of wires is different from the distribution of the sensor cores to be processed, the wire guide mechanism 63 for restraining the wires which are correspondingly dislocated needs to be adjusted, and the wire adjustment mode of the wire guide mechanism 63 is mainly divided into wire height adjustment and wire left and right position adjustment.

When the height of the wire is adjusted, the torsion spring connecting shaft plates 624 at two ends of the inner crosspiece 621 of the frame are pressed to drive the lateral side fixing buckles 622 of the crosspiece not to engage with the in-groove latch 612 on the inner side of the in-frame sliding groove 611, and at the moment, the inner crosspiece 621 of the frame can be controlled to horizontally slide up and down along the in-frame sliding groove 611, so that the height of the corresponding wire constrained by the wire guiding mechanism on the inner crosspiece 621 of the frame is adjusted.

And when the inner frame rail 621 moves to a proper height, the torsion spring coupling plates 624 at the two ends of the inner frame rail 621 are released, so that the rail side fixing buckles 622 press and engage with the in-groove latch 612 again under the action of the torsion springs of the torsion spring coupling plates 624, and the current height of the inner frame rail 621 is fixed.

When the left and right positions of the wire rod are adjusted, outward pulling force is applied to two sides of the butting type clamping sleeve 632, the butting type clamping sleeve 632 is opened and closed mechanically, the butting type clamping sleeve 632 is unfolded to drive the hinge piece 6331 to rotate along the crosspiece slide seat 631, the tail end upper platforms of the two hinge pieces 6331 are not meshed with the crosspiece meshing teeth 623 any more, the hinge piece 6331 rotates to extrude the spring 6332 sleeved on the outer side of the hinge piece 6331, the crosspiece slide seat 631 can slide left and right along the crosspiece 621 in the frame, the butting type clamping sleeve 632 is loosened when the hinge piece slides to a proper position, and the two springs 6332 are released to drive the butting type clamping sleeve 632 to rewrite the butting and form an annular structure for restraining the wire rod.

After a plurality of wires are guided and restrained by the multi-wire restraining mechanism 6, the plurality of wires are still in a loose state at the moment, gaps between the wires are large, dislocation possibly occurs in the subsequent wrapping process to influence the processing quality, therefore, the plurality of wires pass through the inside of the multi-wire extrusion forming mechanism 7, the plurality of wires are pressed vertically by the longitudinal pressing mechanism 72 inside the multi-wire extrusion forming mechanism 7, if the extrusion pressure is insufficient, the two sliding block driving screws 722 are screwed, the two inner sliding blocks 721 and the extrusion roller 723 are driven by the two sliding block driving screws 722 to move relatively, and therefore the pressure for pressing the wires is adjusted.

And the plurality of wires are pressed right and left by the transverse pressing mechanism 73, thereby reducing the gaps between the plurality of wires and positioning the wires at the corresponding positions.

Finally, the extruded wires are furled by the annular furling clamping sleeve 74 to simulate the pressure on the wires in the subsequent wrapping process, and the furled wires transversely pass through the outer layer wrapping device 4 to be wrapped and processed, so that a worker can confirm whether the corresponding positions of the wires deviate again at the stage.

The above embodiments are only exemplary embodiments of the present application, and are not intended to limit the present application, and the protection scope of the present application is defined by the claims. Various modifications and equivalents may be made by those skilled in the art within the spirit and scope of the present application and such modifications and equivalents should also be considered to be within the scope of the present application.

Claims (7)

1. The processing device of the multi-node thermocouple transient heat flow sensor is characterized by being used for processing a sensor inner core with multiple wires and comprising a multi-wire processing device (1) used for wrapping the wires, wherein the multi-wire processing device (1) is provided with a plurality of nickel-chromium wire coils (2) used for coiling bare wires and a plurality of constantan wire coils (3) used for coiling enameled wires, an outer layer wrapping device (4) which is connected with the bare wires and the enameled wires and wraps the whole outer side of the bare wires and the enameled wires is arranged on the multi-wire processing device (1), and a wire drawing device (5) used for drawing the outer layer wrapping device (4) to discharge a wrapped sensor structure is arranged on the side of the multi-wire processing device (1);

the multi-wire processing device (1) is provided with a multi-wire restraining mechanism (6) which is used for movably lapping bare wires on the plurality of nickel-chromium wire coils (2) and enameled wires on the constantan wire coils (3), and the inside of the multi-wire rod restraining mechanism (6) is respectively limited and lapped with a plurality of wire rods through layering, the multi-wire processing device (1) is provided with a multi-wire extrusion forming mechanism (7) for drawing the bare wires on the plurality of nickel-chromium wire coils (2) and the enameled wires on the plurality of constantan wire coils (3), and the inner side of the multi-wire extrusion forming mechanism (7) is used for clamping a plurality of wires through multiple opposite rolling, the multi-wire extrusion forming mechanism (7) is matched with the multi-wire restraining mechanism (6) to draw in the wires limited by the multi-wire restraining mechanism (6) and shape the distribution structure of the wires;

the multi-wire restraining mechanism (6) comprises a multi-plate seat frame (61) fixedly mounted on the multi-wire processing device (1), a plurality of wire layer clamping mechanisms (62) which are horizontally distributed and vertically adjusted along the multi-plate seat frame (61) are mounted on the inner side of the multi-plate seat frame (61), a plurality of wire guiding mechanisms (63) which move left and right along the wire layer clamping mechanisms (62) are mounted on the wire layer clamping mechanisms (62), the plurality of wire guiding mechanisms (63) are used for movably sleeving corresponding wires, and the plurality of wire guiding mechanisms (63) drive the corresponding wires to be arranged and distributed by adjusting self arrangement;

an in-frame sliding groove (611) is formed in the inner side of the multilayer board seat frame (61), and in-groove clamping teeth (612) which are used for being matched with the line layer clamping mechanism (62) to use and movably clamping the line layer clamping mechanism (62) are distributed in the in-frame sliding groove (611) at equal intervals;

crosspiece (621) in the frame of spout (611) both sides in the frame is including horizontal butt crosspiece (62), and crosspiece (621) in the frame through both sides with in the frame spout (611) cooperation is followed slide from top to bottom in the frame spout (611) level, the both ends of crosspiece (621) in the frame all install with the crosspiece side fixed knot (622) torsion spring even shaft board (624) be connected, and crosspiece side fixed knot (622) block is in on inslot latch (612) and through pressing torsion spring even shaft board (624) so that crosspiece side fixed knot (622) break away from inslot latch (612), equidistant distribution has been used for the cooperation on crosspiece (621) in the frame crosspiece (623) the fixed crosspiece interlock tooth (623) of wire rod guiding mechanism (63) block.

2. The processing apparatus of claim 1, wherein the processing apparatus comprises: wire rod guiding mechanism (63) is including installing crosspiece (621) outside in the frame and edge crosspiece (621) lateral shifting's crosspiece slide (631), and install the butt joint formula cutting ferrule (632) that mechanical type opened and shut on crosspiece slide (631), and install two cooperations in crosspiece slide (631) the linkage interlock piece (633) of butt joint formula cutting ferrule (632) closed state automatic interlock relevant position crosspiece interlock tooth (623), and butt joint formula cutting ferrule (632) under the open mode through with linkage interlock piece (633) transmission and control linkage interlock piece (633) are automatic to be disengaged crosspiece interlock tooth (623).

3. The processing apparatus of claim 2, wherein the processing apparatus comprises: linkage interlock piece (633) include two tip with butt joint formula cutting ferrule (632) rotate the articulated elements (6331) of being connected, and two the middle-end position of articulated elements (6331) with crosspiece slide (631) rotate and are connected, two butt joint formula cutting ferrule (632) are closed and are driven two articulated elements (6331) tail end interlock crosspiece interlock tooth (623), and two the outside of articulated elements (6331) all overlaps and is equipped with the extrusion two spring (6332) that butt joint formula cutting ferrule (632) trend closed state.

4. The processing apparatus of claim 1, wherein the processing apparatus comprises: many wire rod extrusion forming mechanism (7) are including fixing on many wire rod processingequipment (1) and be in many wire rod restraint mechanism (6) with shape mounting bracket (71) return between outer parcel device (4), the inboard of returning shape mounting bracket (71) is installed and is vertically to pressing mechanism (72) of a plurality of wire rods from top to bottom to and install horizontal to pressing mechanism (73) that can control a plurality of wire rods, and the tail end of returning shape mounting bracket (71) is installed and is used for binding up a plurality of annular of wire rods after pressing and draw in cutting ferrule (74).

5. The multi-node thermocouple transient heat flow sensor processing apparatus of claim 4, wherein: the longitudinal pressing mechanism (72) comprises two in-frame sliding blocks (721) which are respectively distributed at the upper end and the lower end of the square-shaped mounting frame (71), sliding block driving screws (722) which extend to the outer side of the square-shaped mounting frame (71) and drive the in-frame sliding blocks (721) to move up and down along the square-shaped mounting frame (71) are mounted on the in-frame sliding blocks (721), and horizontally distributed extrusion rollers (723) which are used for abutting against wires are movably sleeved on the inner side of the square-shaped mounting frame (71) on the in-frame sliding blocks (721).

6. The multi-node thermocouple transient heat flow sensor processing apparatus of claim 5, wherein: the structure of the transverse pressing mechanism (73) is the same as that of the longitudinal pressing mechanism (72), and the two horizontally distributed extrusion rollers (723) on the longitudinal pressing mechanism (72) are matched with the transverse pressing mechanism (73) to form a structure in a shape like a Chinese character 'jing' for extruding the periphery of a multi-wire material.

7. The multi-node thermocouple transient heat flow sensor processing apparatus of claim 4, wherein: the annular furling clamping sleeve (74) is integrally and vertically fixed at a tail end wire outlet of the clip-shaped mounting frame (71), the inner diameter of the annular furling clamping sleeve (74) is the same as the outer diameter of an inner core of a finished product sensor structure, and the circle center of the annular furling clamping sleeve (74) is always over against the input port of the outer-layer wrapping device (4).

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