CN216853505U - S-shaped wire arranging shaft and water droplet wheel - Google Patents

Abstract

The utility model discloses an S-shaped winding displacement shaft and a water droplet wheel, wherein the S-shaped winding displacement shaft comprises a shaft body, a first limiting block and a second limiting block; a stopper and No. two stopper centrosymmetries, the axis body slope sets up and is located between stopper and No. two stoppers, and the axis body and stopper, No. two stopper integrated into one piece. The water drop wheel comprises the S-shaped wire arranging shaft. The novel S-shaped winding displacement shaft is adopted to replace the original winding displacement structure; when the wire is outgoing, no pressure is applied to the wire, no friction exists between the wire and the S-shaped wire arranging shaft, the wire is outgoing from the wire off-line cup, the wire cannot be clamped, and the wire outgoing range is wide. When the winding machine is used for winding, the pressure of the wire basically cannot cause destructive influence on the S-shaped winding displacement shaft, and the winding machine has the advantages of simple structure, strong adaptability and the like.

Description

S-shaped wire arranging shaft and water droplet wheel

Technical Field

The utility model relates to a wire arranging shaft and a water drop wheel, in particular to an S-shaped wire arranging shaft and a water drop wheel.

Background

The water drop wheel belongs to one of lying wheels, and has the advantages of higher throwing precision, small volume and easy control of outgoing lines. In the water drop wheel in the prior art, the wire winding and wire arranging modes need to be realized by structures such as a wire passing ring, a wire arranging column, a reciprocating shaft and the like, a wire passes through the wire passing ring, the wire passing ring is fixedly connected to the wire arranging column, and the wire arranging column can slide left and right along the reciprocating shaft; therefore, when the wire cup rotates to take up the wire, the wire arranging column slides to arrange the wire, so that the wire is uniformly arranged on the wire cup. However, the existing wire collecting and arranging structure has the following technical defects: 1) when the wire is paid off, the wire rubs with the wire passing ring, which is not beneficial to wire outlet; 2) when the wire is paid off, the paying-off speed of the wire cup is higher than that of the wire passing ring, and the wire is easy to knot; 3) when paying off, the wire arranging column needs to be adjusted to the middle of the secondary shaft, otherwise, an included angle is formed, and wire outlet is not facilitated; 4) when the wire is taken up, the wire arranging column is easy to damage the reciprocating shaft when the wire arranging column slides to the left side and the right side; 5) the winding displacement assembly has complex structure, precise matching and difficult assembly, and is easy to lose efficacy and damage due to water inflow and sand inflow during fishing.

SUMMERY OF THE UTILITY MODEL

In order to solve the defects of the prior art, the utility model provides an S-shaped wire arranging shaft and a water drop wheel.

In order to solve the technical problems, the utility model adopts the technical scheme that: an S-shaped winding displacement shaft comprises a shaft body, a first limiting block and a second limiting block; a stopper and No. two stopper centrosymmetries, the axis body slope sets up and is located between stopper and No. two stoppers, and the axis body and stopper, No. two stopper integrated into one piece.

Further, arc-shaped triangular steps are arranged on two sides of the shaft body of the S-shaped winding displacement shaft in a central symmetry mode.

Furthermore, hemispherical bulges are respectively formed on the surfaces of one ends, connected with the main shaft, of the first limiting block and the second limiting block.

A water drop wheel comprises the S-shaped line arranging shaft.

Furthermore, the first limiting block and the second limiting block are respectively connected with a connecting shaft, a round hole used for installing the S-shaped winding displacement shaft is formed in the water droplet wheel main body, and the connecting shaft is in rotating contact with the round hole.

Furthermore, a bearing is additionally arranged at the round hole and is connected with the connecting shaft through the bearing.

Furthermore, a connecting shaft at one end is fixedly connected with the transmission gear through a flat screw, and the driven gear is meshed with the transmission gear.

Furthermore, the device comprises a wire cup, a main shaft, spiral teeth, a large gear, a transmission shaft and a rocker arm; the wire cup is fixedly connected with the main shaft, and the main shaft is fixedly connected with the spiral teeth;

the rocker arm is fixedly arranged on the transmission shaft, the transmission shaft drives the large gear to rotate through the friction plate, the transmission shaft is fixedly connected with the transmission gear, and the large gear is meshed with the spiral gear.

Furthermore, the main shaft is erected on the water droplet wheel main body through a bearing I and a bearing II.

The utility model discloses an S-shaped winding displacement shaft and a water drop wheel, wherein the S-shaped winding displacement shaft is adopted to replace the original wire receiving and winding displacement structure without a wire passing ring structure; when the wire is outgoing, no pressure is applied to the wire, no friction exists between the wire and the S-shaped wire arranging shaft, the wire is outgoing from the wire off-line cup, no redundant limitation exists, the wire cannot be clamped, no wire outgoing included angle exists, and the wire outgoing range is wide. When the wire is wound, the pressure of the wire basically cannot cause destructive influence on the S-shaped wire arranging shaft, and the wire winding device has the advantages of simple structure, strong adaptability and the like.

Drawings

Fig. 1 is a schematic cross-sectional view of a conventional drip wheel.

Fig. 2 is a schematic view of a relationship between a winding and unwinding structure of a conventional water wheel and a wire cup.

Fig. 3 is a schematic view of the wire winding arrangement structure in fig. 1.

Fig. 4 is a schematic cross-sectional view of fig. 3.

Fig. 5 is a schematic view of the structure of the S-shaped traverse shaft of the present invention.

Fig. 6 to 9 are schematic views showing the process of changing the position of the wire on the rotating S-shaped winding displacement shaft.

Fig. 10 is a schematic cross-sectional view of a drip wheel according to the present invention.

FIG. 11 is a schematic view of the position relationship between the S-shaped winding displacement shaft and the spool according to the present invention.

In the figure: 11. a shaft body; 12. a first limiting block; 13. a second limiting block; 14. a triangular step; 2. A connecting shaft; 3. fixing screws; 101. a main body; 102. a thread cup; 103. a first bearing; 104. a second bearing; 105. a main shaft pin; 106. helical teeth; 107. a quill tube; 108. a split washer; 109. left limiting of the wire arranging column; 110. a first nut; 111. the shaft pin is replaced; 112. arranging wire columns; 113. a second axis; 114. The flat cable column is limited at the right side; 115. a driving shaft gear; 116. a wire passing ring; 117. a transmission gear; 118. a bull gear; 119. a friction plate; 120. a second screw cap; 121. a drive shaft; 122. a rocker arm; 123. and a driven tooth.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

As shown in fig. 1 and 2, which are schematic structural views of a conventional water wheel, it can be known from the structure shown in fig. 1 and 2 that the wire winding and unwinding principle of the conventional water wheel is as follows:

for the existing water drop wheel, the structure is as follows: the wire cup is fixedly connected with the main shaft, is erected on the main body through a bearing I and a bearing II and can rotate, the main shaft pin is fixed on the main shaft, and a pin hole is formed in the spiral tooth and matched with the main shaft pin to drive the wire cup to rotate;

the large gear is meshed with the spiral teeth, and when the large gear rotates, the large gear can drive the wire cup to rotate to take up wires;

the large gear device is provided with a friction plate, the large gear is driven by the transmission shaft to rotate through friction of the friction plate, and the transmission shaft is connected with the rocker arm and locked through the second nut;

the transmission shaft is also fixedly connected with transmission teeth which are meshed with the driving counterbearing teeth;

the reciprocating shaft teeth are connected with the reciprocating shaft and fixed through an open retainer ring;

as shown in fig. 3, a coming compound shaft sleeve is sleeved on the outer side of the coming compound shaft, the coming compound shaft can rotate in the coming compound shaft sleeve, and the coming compound shaft sleeve is fixedly connected with the water droplet wheel main body through the outer wall;

as shown in fig. 4, a winding displacement column is arranged outside the winding displacement sleeve, a hole is formed in the winding displacement column, a winding displacement shaft pin is arranged in the hole, the winding displacement shaft pin can slide left and right along the winding displacement shaft, and then the winding displacement column is driven by the winding displacement shaft pin to slide left and right along the winding displacement shaft;

the reset shaft pin is fixed on the wire arranging column by a first nut to ensure that the reset shaft pin cannot fall off;

the wire arranging column is fixedly connected with a wire passing ring, and a wire passes through the wire passing ring.

Therefore, the winding and unwinding process of the existing water droplet wheel is as follows: the rocker arm is rotated to drive the transmission shaft to rotate, and the transmission shaft drives the large gear and the transmission gear to rotate together; the large gear drives the spiral teeth to rotate so as to drive the line cup to rotate, the transmission teeth drive the line returning teeth to rotate so as to drive the line returning teeth to rotate, the line returning teeth rotate and drive the line arranging column to slide left and right through the tooth pattern structure on the shaft, the line cup rotates to take up the line, and the line arranging column slides to arrange the line on the line cup uniformly.

However, for the existing water wheel wire collecting and arranging structure, a plurality of technical defects that the appearance is not facilitated, the wire is easy to knot, the incoming and outgoing shaft is easy to damage and the like exist, and based on the technical defects, the utility model discloses an S-shaped wire arranging shaft to replace the traditional wire collecting and arranging structure;

as shown in fig. 5, which is a schematic structural view of an S-shaped winding displacement shaft, the S-shaped winding displacement shaft includes a shaft body 11, a first limit block 12 and a second limit block 13; no. one stopper 12 and No. two stopper 13 central symmetry, the axis body 11 slope setting and lie in No. one stopper 12 and No. two stopper 13 between, the axis body 11 forms the major structure of S-shaped winding displacement axle with No. one stopper 12, No. two stopper 13 integrated into one piece.

Similarly, arc-shaped triangular steps are symmetrically arranged at the centers of both sides of the shaft body 11 of the S-shaped traverse shaft 1, so that the shaft body 11 has a relo triangular structure, and the line is always at the same-position high point. For the first limiting block 12 and the second limiting block 13, in order to reduce the friction damage to the wire, a smooth hemispherical protrusion is formed on the surface of one end of the limiting block connected with the shaft body 11.

With this novel disclosed S-shaped winding displacement axle be applied to the water droplet and take turns, when the line cup rotates and receives the line, S-shaped winding displacement axle rotates and makes the line slide from side to side on S-shaped winding displacement axle, realizes the winding displacement.

As shown in fig. 6 to 9, showing the process of changing the position of the wire on the rotating S-shaped traverse shaft, when the wire is under tension (i.e. when the wire is taken up), the wire will sink, the lowest point of the shaft will change continuously from left to right along with the rotation of the S-shaped traverse shaft, but the wire will always be at the highest point and continuously slide to the lower point, when the wire slides to the limit, the lowest point becomes the highest point through the rotation of the S-shaped traverse shaft, and the wire slides from the highest point to the lowest point again; when the S-shaped winding displacement shaft rotates, the wire slides left and right on the S-shaped winding displacement shaft, and left and right winding displacement is achieved.

As shown in fig. 10 and 11, which are schematic structural diagrams of a water droplet wheel where an S-shaped winding displacement shaft is located, connecting shafts 2 are arranged at two ends (namely a first limiting block 12 and a second limiting block 13) of the S-shaped winding displacement shaft, and the connecting shafts at one ends are fixedly connected with driven teeth through flat screws, so that the S-shaped winding displacement shaft synchronously rotates along with the driven teeth; the driven teeth are meshed with the transmission teeth, and the transmission teeth drive the driven teeth to rotate.

A round hole for installing an S-shaped winding displacement shaft is formed in the water droplet wheel main body, and connecting shafts at two ends of the S-shaped winding displacement shaft are in rotary contact with the round hole and are locked by fixing screws 3; in order to keep the S-shaped winding displacement shaft to stably and evenly rotate, a bearing can be additionally arranged at the round hole and is connected with the connecting shaft 2.

To the setting of rocking arm, transmission shaft, gear wheel, line cup isotructure, then the same with traditional water droplet wheel, from this, this novel disclosed water droplet wheel, its receipts winding displacement process is: the rocker arm is rotated to drive the transmission shaft to rotate, and the transmission shaft drives the large gear and the transmission gear to rotate together; the large gear drives the spiral teeth to rotate so as to drive the line cup to rotate, the transmission teeth drive the driven teeth to rotate so as to drive the S-shaped line arranging shaft to rotate, the line cup rotates to take up the line, and the line slides left and right on the S-shaped line arranging shaft, so that the line is evenly arranged on the line cup.

Therefore, the S-shaped wire arranging shaft and the water drop wheel disclosed by the utility model have the following technical advantages: because the S-shaped winding displacement shaft is adopted to replace the original winding and winding displacement structure, a wire passing ring structure is not needed; when the wire is outgoing, the wire off-line cup is the outgoing wire, no redundant limitation exists, and the wire cannot be clamped; when the wire is led out, no pressure is applied to the wire, the wire basically has no friction with the S-shaped wire arranging shaft, the wire can be freely led out, and the problem of the friction of the wire is solved; and moreover, the wire outlet range is wide, and no wire outlet included angle exists. When the winding machine is used for winding, the pressure of the wire basically cannot cause destructive influence on the S-shaped winding displacement shaft, and the problem that the traditional winding displacement shaft is easy to damage is solved. In addition, the S-shaped winding displacement shaft replaces the traditional winding displacement structure assembly, and has the advantages of simple structure, strong adaptability, capability of coping with various complex environments, no influence on winding displacement performance due to contamination of impurities such as water, sand, mud and the like, and the like.

The above embodiments are not intended to limit the present invention, and the present invention is not limited to the above examples, and those skilled in the art may make variations, modifications, additions or substitutions within the technical scope of the present invention.

Claims (9)

1. An S-shaped winding displacement shaft characterized in that: comprises a shaft body (11), a first limit block (12) and a second limit block (13); no. one stopper (12) and No. two stopper (13) central symmetry, axis body (11) slope setting is located No. one stopper (12) and No. two stopper (13) between, and axis body (11) and No. one stopper (12), No. two stopper (13) integrated into one piece.

2. The S-shaped winding displacement shaft according to claim 1, wherein: arc-shaped triangular steps (14) are arranged on the two sides of the shaft body (11) of the S-shaped winding displacement shaft in a central symmetry manner.

3. An S-shaped winding displacement shaft according to claim 2, wherein: hemispherical bulges are respectively formed on the surfaces of one ends of the first limiting block (12) and the second limiting block (13) connected with the shaft body (11).

4. A drip wheel, comprising: comprising an S-shaped winding displacement shaft according to any one of claims 1-3.

5. The drip wheel of claim 4, wherein: no. one stopper (12), No. two stoppers (13) are connected with connecting axle (2) respectively, offer the round hole that is used for the installation of S-shaped winding displacement axle in the water droplet wheel main part, and connecting axle (2) rotate with the round hole and contact.

6. The drip wheel of claim 5, wherein: and a bearing is additionally arranged at the round hole and is connected with the connecting shaft (2).

7. The drip wheel of claim 5 or 6, wherein: the connecting shaft at one end is fixedly connected with the driven gear through the flat screw, and the driven gear is meshed with the transmission gear.

8. The drip wheel of claim 7, wherein: the wire cup comprises a wire cup, a main shaft, spiral teeth, a large gear, a transmission shaft and a rocker arm; the wire cup is fixedly connected with the main shaft, and the main shaft is fixedly connected with the spiral teeth;

the rocking arm fixed mounting passes through the friction disc and drives the gear wheel rotation on the transmission shaft, and the transmission shaft links firmly with the driving tooth, gear wheel and helical tooth meshing.

9. The drip wheel of claim 8, wherein: the main shaft is erected on the water droplet wheel main body through a bearing I and a bearing II.

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