CN110713066A - Gear transmission type winding mechanism for high-frequency composite wire processing - Google Patents

Abstract

The invention provides a gear transmission type winding mechanism for processing a high-frequency composite wire, relates to the technical field of winding mechanisms, and solves the problems that when the existing high-frequency composite wire winding drum is used, the position of the winding drum is unchanged, an external device is needed to push the high-frequency composite wire to slide along the winding drum so as to avoid the situation that the high-frequency composite wire is wound on a single part area of the winding drum, but the high-frequency composite wire wound on a drum body is uneven in a pushing mode through the external device. A gear transmission type winding mechanism for machining a high-frequency composite wire comprises a rack, wherein the left end of the rack is connected with a group of sliding type installation mechanisms in a sliding mode. According to the invention, through the meshing transmission fit of the transmission type mounting mechanism, the driving mechanism, the driven driving mechanism and the auxiliary driving mechanism, the winding reel is driven to slide left and right, and the high-frequency composite wire after being finished is ensured to be uniformly wound on the winding reel.

Description

Gear transmission type winding mechanism for high-frequency composite wire processing

Technical Field

The invention belongs to the technical field of winding mechanisms, and particularly relates to a gear transmission type winding mechanism for high-frequency composite wire processing.

Background

In a high-frequency composite wire processing and manufacturing plant, a large amount of high-frequency composite wires are produced every day, the high-frequency composite wires are packaged by using a winding drum, but the position of the winding drum is not changed when the existing high-frequency composite wire winding drum is used, an external device is needed to push the high-frequency composite wires to slide along the winding drum so as to prevent the high-frequency composite wires from being wound on a single part area of the winding drum, and the high-frequency composite wires wound on a drum body are not smooth in a pushing mode through the external device.

For example, application No.: 201710792670.5 the invention discloses a colored spun yarn bobbin, which comprises a bobbin body, baffles, a connecting groove and a fixing hole, wherein the bobbin body is provided with convex blocks, lead grooves are formed between the convex blocks, the baffles are fixed on the left side and the right side of the driving of the bobbin body, the baffles are provided with threading holes, the threading holes are provided with connecting pieces, the connecting pieces are connected with winding rods, the winding rods are provided with winding grooves, the tail ends of the winding rods are connected with connecting rods, the tail ends of the connecting rods are connected with snap rings which are fixed on the baffles, the connecting groove is arranged on the bobbin body, anti-skid pads are arranged inside the connecting groove, the fixing hole is arranged on the baffles, sleeves are embedded inside the body walls of the fixing holes, and springs are connected inside the sleeves. This colored spun yarn bobbin is mainly used for twining colored spun yarn and designs, has set up the baffle on this device, can be better with the better winding of colored spun yarn on the barrel, set up the lug on the barrel, can make the winding more level and smooth at the barrel colored spun yarn. Based on the search of this patent, and in combination with the devices in the prior art, it was found that the above-mentioned devices, when applied, have the same application disadvantages as when wrapping the package for high frequency composite wires.

Disclosure of Invention

In order to solve the technical problems, the invention provides a gear transmission type winding mechanism for processing a high-frequency composite wire, which aims to solve the problems that the position of a winding drum is not changed when the existing high-frequency composite wire winding drum is used, an external device is needed to push the high-frequency composite wire to slide along the winding drum so as to avoid the high-frequency composite wire from being wound on a single part of the winding drum, but the high-frequency composite wire wound on a drum body is not flat in a pushing mode through the external device.

The invention relates to a gear transmission type winding mechanism for high-frequency composite wire processing, which is realized by the following specific technical means:

a gear transmission type winding mechanism for high-frequency composite wire processing comprises a rack, wherein the left end of the rack is connected with a group of sliding type mounting mechanisms in a sliding manner, and a winding reel is fixedly mounted between each sliding type mounting mechanism and the corresponding transmission type mounting mechanism; the rack right-hand member rear side is connected with intermeshing from last to rotating down in proper order initiative actuating mechanism, auxiliary drive mechanism and driven actuating mechanism.

Further, the rack comprises a rectangular base, a rectangular supporting block, a bearing A, a bearing B, a bearing C, a front blocking plate and a rear blocking plate, wherein the rectangular supporting block is welded on the right rear side of the top end face of the rack, the bearing A, the bearing B and the bearing C are sequentially and rotatably connected with the rectangular supporting block from top to bottom, two front blocking plates are welded on the front sides of adjacent middle parts on the right side of the top end face of the rack, and two rear blocking plates are welded on the rear sides of adjacent middle parts on the right side of the top end face of the rack;

furthermore, the sliding type mounting mechanism comprises a rectangular plate, a motor A, a disc A, limiting through holes A, concave sliding blocks and balls, wherein one concave sliding block is welded on the bottom end face of the rectangular plate, two rows of concave end faces of the concave sliding blocks are embedded and rotatably connected, five balls are arranged in each row, the motor A is mounted on the top side of the rear end face of the rectangular plate, the disc A rotatably connected with the motor A is arranged on the front end face of the rectangular plate, and six limiting through holes A are formed in the disc A in an annular array shape;

further, when the rack and the sliding type mounting mechanism are mounted, the concave sliding block is connected to the top end face of the left side of the rectangular base in a sliding manner, the concave end face of the concave sliding block is not in contact with the rectangular base, and the ball is in sliding contact with the rectangular base;

furthermore, the bobbin also comprises six studs, the left end and the right end of the bobbin are welded with the six studs in an annular array shape, the left end face of the bobbin is contacted with the right end face of the disc A in the installation state of the bobbin and the sliding type installation mechanism, and the six studs penetrate through the six limiting through holes A and are fixedly connected through nuts;

furthermore, the transmission type mounting mechanism comprises a rack, a round block, a bearing D, an annular block and a limiting through hole B, wherein the rack with teeth on the top end surface and the bottom end surface is welded on the right end surface of the round block, the round block and the inner end surface of the annular block are rotatably connected through the bearing D, and the annular block is provided with six limiting through holes B in an annular array shape;

further, in the state that the transmission type mounting mechanism and the winding drum are mounted, the left end face of the annular block is in contact with the left end face of the winding drum, and six studs penetrate through six limiting through holes B and are fixedly connected through nuts;

further, the driving mechanism comprises a motor B, a rotating shaft A, a gear A and an incomplete gear A, wherein the motor B is rotatably connected with one rotating shaft A, and the gear A and the incomplete gear A are in keyed connection on the rotating shaft A;

further, the driven driving mechanism comprises a rotating shaft B, a gear B and an incomplete gear B, and the gear B and the incomplete gear B are connected to the rotating shaft B in a key manner;

furthermore, the auxiliary driving mechanism comprises a rotating shaft C and a gear C, and the gear C is connected to the rotating shaft C in a key manner;

furthermore, when the driving mechanism, the driven driving mechanism, the auxiliary driving mechanism and the frame are installed, the motor B is arranged on the rear end face of the rectangular supporting block, the rotating shaft A is rotatably connected with the bearing A, the gear A is positioned at the rear side of the rear blocking plate, the front end face and the rear end face of the incomplete gear A are respectively contacted with the front blocking plate and the rear blocking plate and are meshed with the racks, the rotating shaft C is rotationally connected with the bearing B, the gear C is positioned at the rear side of the rear blocking plate and is meshed with the gear A, the rotating shaft B is rotationally connected with the bearing C, the gear B is positioned at the rear side of the rear blocking plate and is meshed with the gear C, the front end face and the rear end face of the incomplete gear B are respectively contacted with the front blocking plate and the rear blocking plate and are meshed with the racks;

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

according to the invention, the transmission type mounting mechanism, the driving mechanism, the driven driving mechanism and the auxiliary driving mechanism are engaged and matched in a transmission manner, so that the bobbin is driven to slide left and right, the high-frequency composite wire after being finished is ensured to be uniformly wound on the bobbin, and the annular block and the round block are rotatably connected through the bearing D, so that the normal rotating operation of the bobbin is not hindered through the arrangement of the bearing D when the bobbin is driven to slide left and right.

Drawings

Fig. 1 is a schematic front view of the present invention.

Fig. 2 is a rear view structural diagram of the present invention.

Fig. 3 is a right-view structural diagram of the present invention.

Fig. 4 is a schematic view of the frame structure of the present invention.

FIG. 5 is a schematic view of the sliding type installation mechanism of the present invention.

FIG. 6 is a schematic bottom end axial view of the sliding type mounting mechanism of the present invention.

FIG. 7 is a schematic cross-sectional view of a concave slider in the sliding type mounting mechanism of the present invention.

Fig. 8 is a schematic view of the bobbin structure of the present invention.

FIG. 9 is a schematic structural view of the driven mounting mechanism of the present invention.

Fig. 10 is a schematic view of the structure of the active driving mechanism of the present invention.

Fig. 11 is a schematic view of the structure of the driven driving mechanism of the present invention.

Fig. 12 is a schematic view of the structure of the auxiliary driving mechanism of the present invention.

Fig. 13 is a schematic structural view of fig. 1 with the front barrier plate and the rear barrier plate removed.

FIG. 14 is a schematic view of the present invention in the configuration of FIG. 13 with the drive-mounted mounting mechanism, partial gear A and partial gear B removed.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. a frame; 101. a rectangular base; 102. a rectangular support block; 103. a bearing A; 104. a bearing B; 105. a bearing C; 106. a front barrier panel; 107. a rear barrier panel; 2. a sliding type mounting mechanism; 201. a rectangular plate; 202. a motor A; 203. a disc A; 204. a limiting through hole A; 205. a concave slider; 206. a ball bearing; 3. a bobbin; 301. a stud; 4. a transmission type mounting mechanism; 401. a rack; 402. a round block; 403. a bearing D; 404. a ring block; 405. a limiting through hole B; 5. an active drive mechanism; 501. a motor B; 502. a rotating shaft A; 503. a gear A; 504. an incomplete gear A; 6. a driven drive mechanism; 601. a rotating shaft B; 602. a gear B; 603. an incomplete gear B; 7. an auxiliary drive mechanism; 701. a rotating shaft C; 702. a gear C;

Detailed Description

The embodiments of the present invention will be described in further detail with reference to the drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing and simplifying the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the invention. Furthermore, the terms "first," "second," "third," and the like 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 is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example (b):

as shown in figures 1 to 14:

the invention provides a gear transmission type winding mechanism for high-frequency composite wire processing, which comprises: the machine frame 1 comprises a rectangular base 101, a rectangular supporting block 102, a bearing A103, a bearing B104, a bearing C105, a front baffle plate 106 and a rear baffle plate 107, wherein the right rear side of the top end face of the machine frame 1 is welded with the rectangular supporting block 102, the rectangular supporting block 102 is sequentially and rotatably connected with the bearing A103, the bearing B104 and the bearing C105 from top to bottom, two front baffle plates 106 are welded on the front sides of adjacent middle parts on the right side of the top end face of the machine frame 1, two rear baffle plates 107 are welded on the rear sides of adjacent middle parts on the right side of the top end face, the left end of the machine frame 1 is slidably connected with a group of sliding type installation mechanisms 2, each sliding type installation mechanism 2 comprises a rectangular plate 201, a motor A202, a disc A203, a limiting through hole A204, a concave type sliding block 205 and a ball 206, a concave type sliding block 205 is welded on the bottom end face of the, the top side of the rear end face of the rectangular plate 201 is provided with a motor A202, the front end face of the rectangular plate 201 is provided with a disc A203 which is rotatably connected with the motor A202, six limiting through holes A204 are formed in the disc A203 in an annular array shape, a winding drum 3 is fixedly installed between the sliding type installation mechanism 2 and the transmission type installation mechanism 4, the winding drum 3 further comprises studs 301, the left end and the right end of the winding drum 3 are welded with six studs 301 in an annular array shape, the left end face of the winding drum 3 is contacted with the right end face of the disc A203 in the installation state of the winding drum 3 and the sliding type installation mechanism 2, and the six studs 301 penetrate through the six limiting through holes A204 and are fixedly connected through nuts; the rear side of the right end of the rack 1 is sequentially and rotatably connected with a driving mechanism 5 which is meshed with each other from top to bottom, the driving mechanism 5 comprises a motor B501, a rotating shaft A502, a gear A503 and an incomplete gear A504, the motor B501 is rotatably connected with a rotating shaft A502, the rotating shaft A502 is in key connection with the gear A503 and the incomplete gear A504, an auxiliary driving mechanism 7 and a driven driving mechanism 6, the driven driving mechanism 6 comprises a rotating shaft B601, a gear B602 and an incomplete gear B603, and the rotating shaft B601 is in key connection with the gear B602 and the incomplete gear B603.

When the rack 1 and the sliding type installation mechanism 2 are installed, the concave slider 205 is slidably connected to the top end surface of the left side of the rectangular base 101, the concave end surface of the concave slider 205 is not in contact with the rectangular base 101, and the ball 206 is in sliding contact with the rectangular base 101.

The transmission type mounting mechanism 4 comprises a rack 401, a round block 402, a bearing D403, an annular block 404 and a limiting through hole B405, wherein the rack 401 with teeth on the top end surface and the bottom end surface is welded on the right end surface of the round block 402, the round block 402 and the inner end surface of the annular block 404 are rotatably connected through the bearing D403, and the annular block 404 is provided with six limiting through holes B405 in an annular array shape.

Wherein, under the installation state of driven installation mechanism 4 and bobbin 3, the left end face of annular piece 404 contacts with bobbin 3 left end face, and six double-screw bolts 301 pass through six spacing through-holes B405 and pass through nut fastening connection.

The auxiliary driving mechanism 7 includes a rotating shaft C701 and a gear C702, and the rotating shaft C701 is keyed with the gear C702.

When the driving mechanism 5, the driven driving mechanism 6 and the auxiliary driving mechanism 7 are installed on the rack 1, the motor B501 is installed on the rear end face of the rectangular supporting block 102, the rotating shaft a502 is rotatably connected with the bearing a103, the gear a503 is located on the rear side of the rear barrier plate 107, the front end face and the rear end face of the incomplete gear a504 are respectively contacted with the front barrier plate 106 and the rear barrier plate 107 and are meshed with the rack 401, the rotating shaft C701 is rotatably connected with the bearing B104, the gear C702 is located on the rear side of the rear barrier plate 107 and is meshed with the gear a503, the rotating shaft B601 is rotatably connected with the bearing C105, the gear B602 is located on the rear side of the rear barrier plate 107 and is meshed with the gear C702, and the front end face and the rear end face of the incomplete gear B603 are respectively contacted with the.

When in use:

when the high-frequency composite wire is processed, the finished high-frequency composite wire is wound on the bobbin 3, and when the high-frequency composite wire is applied, the motor A202 is started to drive the bobbin 3 to drive clockwise, so that the finished high-frequency composite wire wound on the bobbin 3 is driven to be wound on the bobbin 3 clockwise; meanwhile, the motor B501 and the motor A202 are started simultaneously, the motor B501 is started to drive the incomplete gear A504 to rotate clockwise, so as to drive the rack 401 meshed with the incomplete gear A504, the bobbin 3 fixedly connected with the transmission type mounting mechanism 4 and the sliding type mounting mechanism 2 fixedly connected with the bobbin 3 slide leftwards along the rectangular base 101, the gear A503 is meshed to drive the gear C702 to rotate simultaneously when the motor B501 is started, the gear C702 is meshed to drive the gear B602 to rotate simultaneously, after the tooth end of the incomplete gear A504 is separated from the rack 401, the incomplete gear B603 is meshed with the rack 401 through the initial installation position of the incomplete gear A504 and the incomplete gear B603, and after the tooth end of the incomplete gear A504 is separated from the rack 401, the incomplete gear B603 is meshed with the rack 401 and is meshed with the transmission rack 401 to drive rightwards, so that the bobbin 3 fixedly connected with the transmission type mounting mechanism 4 and the sliding type mounting mechanism 2 fixedly connected with the bobbin 3 slide rightwards along the rectangular base 101, according to the invention, the transmission type mounting mechanism 4, the driving mechanism 5, the driven driving mechanism 6 and the auxiliary driving mechanism 7 are engaged and matched in a transmission manner, so that the bobbin 3 is driven to slide left and right, the high-frequency composite wire after being finished is ensured to be uniformly wound on the bobbin 3, and the annular block 404 and the round block 402 are rotatably connected through the bearing D403, so that the normal rotation operation of the bobbin 3 is not hindered by the arrangement of the bearing D403 when the bobbin 3 is driven to slide left and right.

The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

Claims (10)

1. The utility model provides a gear drive formula wire winding mechanism based on processing of high frequency composite wire is used which characterized in that: the bobbin winder comprises a rack (1), wherein the left end of the rack (1) is connected with a group of sliding type mounting mechanisms (2) in a sliding manner, and the bobbins (3) are fixedly mounted between the sliding type mounting mechanisms (2) and a transmission type mounting mechanism (4); frame (1) right-hand member rear side rotates from last to being connected with intermeshing in proper order down initiative actuating mechanism (5), auxiliary drive mechanism (7) and driven actuating mechanism (6).

2. The gear transmission type winding mechanism for high-frequency composite wire machining according to claim 1, characterized in that: frame (1) is including rectangle base (101), rectangle supporting shoe (102), bearing A (103), bearing B (104), bearing C (105), preceding baffler (106), back baffler (107), frame (1) top face right back side welding has one rectangle supporting shoe (102), and rectangle supporting shoe (102) from last to rotating in proper order down and being connected with bearing A (103) bearing B (104) bearing C (105), the adjacent middle part front side of frame (1) top face right side welds two altogether preceding baffler (106), and the adjacent middle part rear side of top face right side welds two altogether back baffler (107).

3. The gear transmission type winding mechanism for high-frequency composite wire machining according to claim 1, characterized in that: slidingtype installation mechanism (2) is including rectangular plate (201), motor A (202), disc A (203), spacing through-hole A (204), concave type slider (205), ball (206), the welding of rectangular plate (201) bottom end face has one concave type slider (205), and concave type slider (205) indent terminal surface embedding rotation is connected with two rows, five per row ball (206), install rectangular plate (201) rear end face top side motor A (202), rectangular plate (201) preceding terminal surface be provided with motor A (202) rotates and is connected disc A (203), be annular array form on disc A (203) and seted up six the spacing through-hole A (204) altogether.

4. The gear transmission type winding mechanism for high-frequency composite wire machining according to claim 1, characterized in that: frame (1) with under slidingtype installation mechanism (2) installation state, concave type slider (205) sliding connection on rectangle base (101) left side top end face, and concave type slider (205) indent terminal surface not with rectangle base (101) contact, ball (206) with rectangle base (101) sliding contact.

5. The gear transmission type winding mechanism for high-frequency composite wire machining according to claim 1, characterized in that: bobbin (3) are still including double-screw bolt (301), both ends all are the annular array form and weld six altogether about bobbin (3) double-screw bolt (301), bobbin (3) with under slidingtype installation mechanism (2) the installation state, bobbin (3) left end face with disc A (203) right-hand member face contacts, and six double-screw bolt (301) alternate six the spacing through-hole A (204) and pass through nut fastening connection.

6. The gear transmission type winding mechanism for high-frequency composite wire machining according to claim 1, characterized in that: transmission formula installation mechanism (4) is including rack (401), circle piece (402), bearing D (403), annular piece (404), spacing through-hole B (405), the right-hand member face welding of circle piece (402) has top end face and bottom end face to be the tooth rack (401), and circle piece (402) with the interior terminal surface of annular piece (404) passes through bearing D (403) rotate and are connected, be annular array form on annular piece (404) and seted up six these spacing through-holes B (405) altogether.

7. The gear transmission type winding mechanism for high-frequency composite wire machining according to claim 1, characterized in that: under the installation state of the transmission type installation mechanism (4) and the winding reel (3), the left end face of the annular block (404) is in contact with the left end face of the winding reel (3), and six studs (301) penetrate through six limiting through holes B (405) and are fixedly connected through nuts.

8. The gear transmission type winding mechanism for high-frequency composite wire machining according to claim 1, characterized in that: the active driving mechanism (5) comprises a motor B (501), a rotating shaft A (502), a gear A (503) and an incomplete gear A (504), wherein the motor B (501) is rotatably connected with one rotating shaft A (502), and the rotating shaft A (502) is in key connection with the gear A (503) and the incomplete gear A (504); the driving mechanism (5), the driven driving mechanism (6) and the auxiliary driving mechanism (7) are mounted on the rack (1), the motor B (501) is mounted on the rear end face of the rectangular supporting block (102), the rotating shaft A (502) is rotatably connected with the bearing A (103), the gear A (503) is located on the rear side of the rear blocking plate (107), the front end face and the rear end face of the incomplete gear A (504) are respectively contacted with the front blocking plate (106) and the rear blocking plate (107) and meshed with the rack (401), the rotating shaft C (701) is rotatably connected with the bearing B (104), the gear C (702) is located on the rear side of the rear blocking plate (107) and meshed with the gear A (503), the rotating shaft B (601) is rotatably connected with the bearing C (105), and the gear B (602) is located on the rear side of the rear blocking plate (107) and meshed with the gear C (702), the front end face and the rear end face of the incomplete gear B (603) are respectively contacted with the front blocking plate (106) and the rear blocking plate (107) and meshed with the rack (401).

9. The gear transmission type winding mechanism for high-frequency composite wire machining according to claim 1, characterized in that: the driven driving mechanism (6) comprises a rotating shaft B (601), a gear B (602) and an incomplete gear B (603), and the gear B (602) and the incomplete gear B (603) are in keyed connection with the rotating shaft B (601).

10. The gear transmission type winding mechanism for high-frequency composite wire machining according to claim 1, characterized in that: the auxiliary driving mechanism (7) comprises a rotating shaft C (701) and a gear C (702), and the gear C (702) is connected to the rotating shaft C (701) in a key mode.

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