CN112139396B - Automatic winding detection device - Google Patents

Abstract

The invention discloses an automatic winding detection device, which belongs to the technical field of part production and comprises a winding assembly, support assemblies, two rotating assemblies, a moving assembly and a platform, wherein a limit groove is formed in the platform, the moving assembly is arranged in the limit groove, two moving tables convenient for fixing the winding assembly and the winding assembly are symmetrically sleeved on the moving assembly, four groups of support assemblies are arranged on the support assemblies, the four groups of support assemblies are respectively and symmetrically inserted at two ends of the winding assembly, the four groups of support assemblies and the two rotating assemblies are respectively fixed with one moving table, the two rotating assemblies are respectively positioned between every two support assemblies, and the output ends of the two rotating assemblies are mutually matched with the four groups of support assemblies: can carry out the wire winding to the spring cable and detect time measuring, accomplish fixed, straight, the step of wire winding and detection in proper order, its practicality is stronger, and the function is diversified, the wire winding and the detection of the spring cable of being convenient for.

Description

Automatic winding detection device

Technical Field

The invention relates to the technical field of part production, in particular to an automatic winding detection device.

Background

Spring cables, also called spiral cables, are necessary in almost all industries, whether in medical technology, in the production of electric machines, in mechanical engineering or in the lighting industry, and have applications everywhere.

However, the spring cable in the prior art has the following problems:

first, current spring cable is when the wire winding, because of artifical or machinery do not have spring cable straight when the wire winding to there is the not good problem of use in the spring cable that leads to current wire winding to end when using, the second, current spring cable does not have the elastic device of fine detection spring cable, it detects to need the manual work to carry out manual drawing usually, lead to hard too violently to draw spring cable bad and the elasticity that can not accurate calculation spring cable like this easily.

Disclosure of Invention

The invention aims to provide an automatic winding detection device, which aims to solve the technical problems that the spring cable is not straight and the elasticity of the spring cable cannot be well detected when the spring cable is wound in the prior art.

The invention provides an automatic winding detection device which comprises a winding assembly, support assemblies, two rotating assemblies, a moving assembly and a platform, wherein a limiting groove is formed in the platform, the moving assembly is arranged in the limiting groove, two moving tables convenient for fixing the winding assembly and the winding assembly are symmetrically sleeved on the moving assembly, four groups of support assemblies are arranged on the support assemblies, the four groups of support assemblies are symmetrically inserted at two ends of the winding assembly respectively, the four groups of support assemblies and the two rotating assemblies are fixed with one moving table respectively, the two rotating assemblies are located between every two support assemblies respectively, and output ends of the two rotating assemblies are matched with the four groups of support assemblies.

Further, the winding subassembly is including holding roller, two backup pads, two fixed blocks and connecting roller, two the backup pad symmetry sets up on another mobile station, the both ends of connecting roller run through the inner wall of two backup pads respectively and between swing joint, two the fixed block is L type structure, and the one end of two fixed blocks is articulated with the connecting roller both ends respectively, two be equipped with the fixed slot that supplies two fixed block other ends to peg graft fixedly in the backup pad, the roller cover is established on connecting roller to the dress, be equipped with the fixed lug that one end of fixed spring cable was held on the outer wall of dress roller, the last inserting groove of being convenient for one end male of spring cable of having seted up of fixed lug.

Furthermore, the winding assembly comprises a winding screw, a winding motor, two support frames and a winding ring, the two support frames are symmetrically arranged above a mobile station, the two ends of the two support frames are respectively fixed by four groups of support assemblies, the two ends of the winding screw respectively penetrate through the tops of the two support frames, one end of the winding screw is provided with a support block for fixing the winding motor, the output end of the winding motor is connected with one end of the winding screw, the winding ring is sleeved on the winding screw, and one side of the winding ring is provided with a clamping block.

Furthermore, every supporting component all includes L type pole and supporting screw, the one end of L type pole is fixed on a mobile station, the one end of supporting screw and the other end swing joint of L type pole, the top of supporting frame one side is run through to the other end of supporting screw.

Further, two the runner assembly all includes biax motor, two running gear and two rotatory gears, the biax motor is fixed on a mobile station and is located between per two supporting screw, two running gear overlaps respectively to be established on two output of biax motor, is equipped with the connecting rod that every rotatory gear cover was established, two on the other end of per two supporting screw the meshing between running gear and two rotatory gears.

Further, the removal subassembly includes two movable plates, two removal screw rods, two mobile gears, main commentaries on classics gear and moving motor, the vertical setting of moving motor is at the spacing inslot, two the one end difference swing joint of removal screw rod is on the inner wall at the both ends of spacing groove, two the other end of removal screw rod is located the output end of moving motor, main commentaries on classics gear cover is established on the output of moving motor, two the mobile gears overlaps respectively and is established on the other end of two removal screw rods, two meshing between mobile gears and the main commentaries on classics gear, two the movable plate symmetry cover is established on two mobile screws, two the bottom of mobile platform is fixed with the top of two movable plates respectively.

Furthermore, the top of the platform is provided with two slide rails which are symmetrically arranged, two ends of the bottom of the two mobile stations are respectively provided with a sliding block, and each sliding block is slidably inserted into the two slide rails.

Furthermore, the inner side walls of the two mobile stations are provided with cushion blocks.

Furthermore, a stop block is arranged on the outer side of one of the mobile stations, and a counter matched with the stop block is arranged on the platform.

Furthermore, four universal wheels are arranged at the bottom of the platform.

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

one of the two supporting rods are driven by two rotating assemblies to rotate, one end of the spring cable is inserted into the insertion groove manually, then the spring cable is wound on the accommodating roller by rotating the accommodating roller, when the spring cable is wound for one section, two fixing blocks are inserted into two fixing grooves to enable the connecting roller to be fixed, the winding assembly and the accommodating roller are prevented from being separated from each other by two moving platforms, the spring cable can drive the accommodating roller to rotate due to the influence of tension, the spring cable is loosened and drops, then the other end of the spring cable is pulled to the winding ring position manually and the other end of the spring cable is inserted into the clamping block, the winding motor is started to drive the winding screw to rotate, the winding screw is driven to move by the winding screw, the spring cable is driven to automatically wind by the winding ring, then every two supporting rods are driven to rotate by the two rotating assemblies respectively, every two supporting rods drive one supporting frame to lift and adjust, and when the height is adjusted, the distance between the winding screw and the accommodating roller is gradually enlarged, and therefore the spring cable is straightened and continues to stretch, and the elasticity test of the spring cable is realized.

Secondly, in order to improve the elasticity of the test spring cable, the movable motor is started to drive the main rotating gear to rotate, the main rotating gear drives the two movable gears to rotate along two opposite directions, then the two movable gears drive the two movable screws to rotate, the rotating directions of the two movable screws are opposite, and therefore reverse thread operation is achieved, the two movable plates are enabled to be synchronously folded inwards or outwards unfolded to move along the directions of the two movable screws respectively, the two movable plates drive the two movable tables to move when moving, the elasticity of the test spring cable is further achieved, and the practicability is improved.

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 embodiments or the prior art descriptions will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a perspective view of the winding assembly of the present invention;

FIG. 3 is a perspective view of the wire winding assembly of the present invention;

FIG. 4 is a partial perspective view of the present invention;

FIG. 5 is a perspective view of the moving assembly of the present invention;

FIG. 6 is an enlarged view of the point A in FIG. 5;

reference numerals:

the winding device comprises a winding assembly 1, a winding assembly 2, a supporting assembly 3, a rotating assembly 4, a moving assembly 5, a platform 6, a limiting groove 61, a moving table 62, a containing roller 11, a supporting plate 12, a fixing block 13, a connecting roller 14, a fixing lug 15, a winding screw 21, a winding motor 22, a supporting frame 23, a winding ring 24, a supporting block 25, a clamping block 26, an L-shaped rod 31, a supporting screw 32, a double-shaft motor 41, a rotating gear 42, a rotating gear 43, a moving plate 51, a moving screw 52, a moving gear 53, a main rotating gear 54, a moving motor 55, a sliding rail 63, a sliding block 64, a cushion block 65, a resisting block 66, a counter 67 and a universal wheel 68.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention.

The components of embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the present invention, as presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention.

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.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in a specific case to those of ordinary skill in the art.

Referring to fig. 1 to 6, an embodiment of the present invention provides an automatic winding detection apparatus, including a winding assembly 1, a winding assembly 2, support assemblies 3, two rotating assemblies 4, a moving assembly 5 and a platform 6, where the platform 6 is provided with a limiting groove 61, the moving assembly 5 is disposed in the limiting groove 61, the moving assembly 5 is symmetrically sleeved with two moving tables 62 convenient for fixing the winding assembly 1 and the winding assembly 2, the support assemblies 3 are provided with four groups, the four groups of support assemblies 3 are respectively and symmetrically inserted at two ends of the winding assembly 2, and the four groups of support assemblies 3 and the two rotating assemblies 4 are both fixed to one moving table 62, the two rotating assemblies 4 are respectively located between every two support assemblies 3, and output ends of the two rotating assemblies 4 are mutually matched with the four groups of support assemblies 3.

The winding assembly 1 comprises a containing roller 11, two supporting plates 12, two fixing blocks 13 and a connecting roller 14, wherein the two supporting plates 12 are symmetrically arranged on another moving table 62, two ends of the connecting roller 14 penetrate through the inner walls of the two supporting plates 12 and are movably connected with each other, the two fixing blocks 13 are of an L-shaped structure, one ends of the two fixing blocks 13 are hinged to two ends of the connecting roller 14, fixing grooves for inserting and fixing the other ends of the two fixing blocks 13 are formed in the two supporting plates 12, the containing roller 11 is sleeved on the connecting roller 14, fixing convex blocks 15 for fixing one end of a spring cable are arranged on the outer wall of the containing roller 11, inserting grooves for facilitating insertion of one end of the spring cable are formed in the fixing convex blocks 15, one end of the spring cable is inserted into the inserting grooves manually, the containing roller 11 is rotated to enable the spring cable to be wound on the containing roller 11, after the spring cable is wound by one section, the two fixing blocks 13 are inserted into the two fixing grooves to enable the connecting roller 14 to be fixed, and the spring cable is prevented from falling off due to the influence of tensile force when the spring cable is separated from the two moving tables 62, and the spring cable is driven to rotate and the winding roller 11, so as to cause looseness.

The winding assembly 2 comprises a winding screw 21, a winding motor 22, two support frames 23 and a winding coil 24, the two support frames 23 are symmetrically arranged above a moving platform 62, the four support assemblies 3 are used for fixing two ends of the two support frames 23 respectively, two ends of the winding screw 21 penetrate through the tops of the two support frames 23 respectively, one end of the winding screw 21 is provided with a support block 25 for fixing the winding motor 22, the output end of the winding motor 22 is connected with one end of the winding screw 21, the winding coil 24 is sleeved on the winding screw 21, one side of the winding coil 24 is provided with a clamping block 26, the other end of the spring cable is pulled to the winding coil 24 and is inserted into the clamping block 26, the winding screw 21 is driven to rotate by opening the winding motor 22, the winding coil 24 is driven to move by the winding screw 21, and the automatic winding process is carried out on the spring cable through the winding coil 24, so that the automatic winding of the spring cable is realized.

Each supporting component 3 comprises an L-shaped rod 31 and a supporting screw rod 32, one end of each L-shaped rod 31 is fixed on one mobile station 62, one end of each supporting screw rod 32 is movably connected with the other end of each L-shaped rod 31, the other end of each supporting screw rod 32 penetrates through the top of one side of each supporting frame 23, each two supporting screw rods 32 are respectively driven to rotate through the two rotating components 4, each two supporting screw rods 32 drive one supporting frame 23 to be adjusted in a lifting mode, and when the height is adjusted, the distance between each winding screw rod 21 and each accommodating roller 11 is gradually enlarged, so that the spring cable is stretched straightly and continuously, and the elasticity test of the spring cable is realized.

The two rotating assemblies 4 respectively comprise a double-shaft motor 41, two rotating gears 42 and two rotating gears 43, the double-shaft motor 41 is fixed on one moving platform 62 and located between every two supporting screw rods 32, the two rotating gears 42 are respectively sleeved on two output ends of the double-shaft motor 41, a connecting rod sleeved with each rotating gear 43 is arranged at the other end of each supporting screw rod 32, the two rotating gears 42 are meshed with the two rotating gears 43, the double-shaft motor 41 is started to drive the two rotating gears 42 to rotate, the two rotating gears 42 drive the two rotating gears 43 to rotate, the rotating gears 43 drive the connecting rods to rotate, the supporting screw rods 32 are driven by the connecting rods to rotate, automatic adjustment can be achieved, and the full automation step is further improved.

The moving assembly 5 comprises two moving plates 51, two moving screws 52, two moving gears 53, a main rotating gear 54 and a moving motor 55, the moving motor 55 is vertically arranged in a limiting groove 61, one end of each of the two moving screws 52 is movably connected to the inner wall of each of the two ends of the limiting groove 61, the other end of each of the two moving screws 52 is located at the output end of the moving motor 55, the main rotating gear is sleeved on the output end of the moving motor 55, the two moving gears 53 are respectively sleeved on the other ends of the two moving screws 52, the two moving gears 53 are meshed with the main rotating gear, the two moving plates 51 are symmetrically sleeved on the two moving screws 52, the bottoms of the two moving tables 62 are fixed to the tops of the two moving plates 51, in order to improve the elasticity of the test spring cable, the main rotating gear 54 is driven to rotate by starting the moving motor 55, the two moving gears 53 are driven to rotate in two opposite directions by the main rotating gear 54, the two moving screws 52 are driven to rotate by the two moving gears 53, and the two moving screws 52 rotate in opposite rotating directions of the two moving screws 52, so that the two moving plates 51 move outwards synchronously along the two moving directions of the two moving screws 52, and the two moving plates 52 are driven to further improve the elasticity of the test spring cable, and the two moving tables, thereby further realizing the practicality.

The top of the platform 6 is provided with two slide rails 63 which are symmetrically arranged, two ends of the bottom of the two mobile platforms 62 are respectively provided with a slide block 64, each slide block 64 is slidably inserted into the two slide rails 63, and the slide rails 63 can reduce the friction force between the mobile platforms 62 and the platform 6 when the two mobile platforms 62 are moved by the two moving plates 51, so that the service life is prolonged.

The spacers 65 are disposed on the inner sidewalls of the two mobile stations 62, and the spacers 65 prevent the two mobile stations 62 from being in contact with each other and reduce the impact force, thereby prolonging the service life of the mobile stations 62.

The outer side of one of the moving tables 62 is provided with a resisting block 66, the platform 6 is provided with a counter 67 matched with the resisting block 66, when the elasticity of the spring cable is tested, the moving table 62 is driven to move by the moving plate 51, the moving table 62 drives the resisting block 66 to move, and then when the resisting block 66 touches the counter 67, the counter 67 counts the times of pulling the spring cable during testing, so that a person can conveniently know and check the number of the spring cable.

The bottom of the platform 6 is provided with four universal wheels 68, and the platform 6 can be conveniently moved through the universal wheels 68, so that the overall practicability is improved.

The working principle of the invention is as follows: one end of a spring cable is inserted into the insertion groove manually, then a worker rotates the accommodating roller 11 to enable the spring cable to be wound on the accommodating roller 11, when the spring cable is wound for a section, two fixing blocks 13 are inserted into two fixing grooves to enable the connecting roller 14 to be fixed, the situation that the distance between the winding assembly 2 and the accommodating roller 11 is separated through two moving tables 62 is avoided, the spring cable can drive the accommodating roller 11 to rotate due to the influence of tension, the spring cable is loosened and dropped, then the other end of the spring cable is pulled to the winding ring 24 and inserted into the clamping block 26 manually, the winding motor 22 is started to drive the winding screw 21 to rotate, the winding screw 21 drives the winding ring 24 to move, the spring cable is driven to carry out an automatic winding process through the winding ring 24, then every two supporting screws 32 are driven to rotate through the two rotating assemblies 4 respectively, every two supporting screws 32 drive one supporting frame 23 to carry out lifting adjustment, and when the height is adjusted, the distance between the winding screw 21 and the accommodating roller 11 is gradually enlarged, the spring cable is stretched and stretched continuously, and the elasticity of the spring is tested.

In order to improve the elasticity of the test spring cable, the moving motor 55 is started to drive the main rotating gear 54 to rotate, the main rotating gear 54 drives the two moving gears 53 to rotate along two opposite directions, then the two moving gears 53 drive the two moving screws 52 to rotate, and the rotating directions of the two moving screws 52 are opposite, so that the reverse-thread operation is realized, the two moving plates 51 are synchronously folded inwards or unfolded outwards along the directions of the two moving screws 52 respectively, the two moving plates 51 drive the two moving tables 62 to move respectively when moving, and therefore the elasticity of the test spring cable is further realized, and the practicability is improved.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the invention has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.

Claims (5)

1. The utility model provides an automatic wire winding detection device which characterized in that: comprises a winding component (1), a winding component (2), a supporting component (3), two rotating components (4), a moving component (5) and a platform (6), wherein a limiting groove (61) is formed in the platform (6), the moving component (5) is arranged in the limiting groove (61), two moving platforms (62) which are convenient for fixing the winding component (1) and the winding component (2) are symmetrically sleeved on the moving component (5), the supporting components (3) are provided with four groups, the four groups of supporting components (3) are respectively and symmetrically inserted at two ends of the winding component (2), the four groups of supporting components (3) and the two rotating components (4) are fixed with one moving platform (62), the two rotating components (4) are respectively positioned between every two supporting components (3), the output ends of the rotating components (4) are mutually matched with the four groups of supporting components (3), the winding component (1) comprises a holding roller (11), two supporting plates (12), two fixing blocks (13) and a connecting roller (14), the two supporting plates (12) are symmetrically arranged on the other moving platform (62), the two inner walls (14) of the connecting rollers (12) are respectively penetrated through the two fixing blocks (13), and the two fixing blocks (13) are of the two movable supporting plates (12), one end of each of the two fixing blocks (13) is hinged with two ends of the connecting roller (14) respectively, fixing grooves for inserting and fixing the other ends of the two fixing blocks (13) are formed in the two supporting plates (12), the accommodating roller (11) is sleeved on the connecting roller (14), a fixing lug (15) for fixing one end of a spring cable is arranged on the outer wall of the accommodating roller (11), an inserting groove for inserting one end of the spring cable conveniently is formed in the fixing lug (15), the winding assembly (2) comprises a winding screw (21), a winding motor (22), two supporting frames (23) and a winding ring (24), the two supporting frames (23) are symmetrically arranged above one moving platform (62), two ends of the two supporting frames (23) are fixed by four groups of supporting assemblies (3) respectively, two ends of the winding screw (21) penetrate through the tops of the two supporting frames (23) respectively, one end of the winding screw (21) is provided with a supporting block (25) for fixing the winding motor (22), the output end of the winding motor (22) is connected with one end of the winding screw (21), the winding ring (24) is sleeved on one side, and each supporting block (31) comprises a clamping rod (31), one end of the L-shaped rod (31) is fixed on a moving platform (62), one end of each supporting screw rod (32) is movably connected with the other end of the L-shaped rod (31), the other end of each supporting screw rod (32) penetrates through the top of one side of the supporting frame (23), the rotating assemblies (4) comprise a double-shaft motor (41), two rotating gears (42) and two rotating gears (43), the double-shaft motor (41) is fixed on the moving platform (62) and located between every two supporting screw rods (32), the rotating gears (42) are respectively sleeved on two output ends of the double-shaft motor (41), connecting rods sleeved with each rotating gear (43) are arranged on the other ends of every two supporting screw rods (32), the rotating gears (42) are meshed with the two rotating gears (43), each moving assembly (5) comprises two moving plates (51), two moving screw rods (52), two moving gears (53), a main rotating gear (54) and a moving motor (55), the moving motors (55) are vertically arranged in a limiting groove (61), and the two moving screw rods (52) are respectively located at two ends of the moving screw rods (55), the main rotating gear is sleeved on the output end of the moving motor (55), the two moving gears (53) are respectively sleeved on the other ends of the two moving screws (52), the two moving gears (53) are meshed with the main rotating gear, the two moving plates (51) are symmetrically sleeved on the two moving screws (52), and the bottoms of the two moving tables (62) are respectively fixed with the tops of the two moving plates (51).

2. The automatic winding detection device as claimed in claim 1, wherein: the top of the platform (6) is provided with two slide rails (63) which are symmetrically arranged, two ends of the bottom of the mobile station (62) are respectively provided with a sliding block (64), and each sliding block (64) is slidably inserted into the two slide rails (63).

3. The automatic winding detection device as claimed in claim 2, wherein: and cushion blocks (65) are arranged on the inner side walls of the two mobile stations (62).

4. The automatic winding detection device as claimed in claim 2, wherein: a resisting block (66) is arranged on the outer side of one of the mobile stations (62), and a counter (67) matched with the resisting block (66) is arranged on the platform (6).

5. The automatic winding detection device according to claim 1, characterized in that: four universal wheels (68) are arranged at the bottom of the platform (6).

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