CN220132493U - Flower braiding machine for producing kerosene heating stove lamp wick - Google Patents

Abstract

The utility model discloses a pattern braiding machine for producing a kerosene heating stove lampwick, which is characterized in that a conveying module is used for conveying a braided lamp core wire, monitoring the length of the lamp core wire at the same time, facilitating subsequent cutting, and comprises a base arranged on a main body module, a first guide pipe arranged at the top end of the base, a support symmetrically fixed at the top end of the base, a conveying wheel symmetrically arranged on the support, a synchronous gear arranged on one side of the conveying wheel, a motor arranged on the other side of the conveying wheel and an angle sensor arranged on the end part of the other conveying wheel.

Description

Flower braiding machine for producing kerosene heating stove lamp wick

Technical Field

The utility model relates to the technical field of kerosene heating furnaces, in particular to a pattern knitting machine for producing a wick of a kerosene heating furnace.

Background

The kerosene heating stove uses coal as main fuel, is mainly used for rural areas or urban and rural joints without central heating or without fuel gas heating conditions, has lower heating cost, is an ideal choice for heating, and a wick is an important component in the kerosene heating stove and is used for leading out kerosene for burning.

In the wick production process, at first need weave stranded yarn into the lamp heart yearn, later cut the lamp heart yearn according to the length of needs to the manual work again, and the manual work cuts the lamp heart yearn comparatively troublesome, and efficiency is lower, and the length of lamp heart yearn can not reach unification simultaneously, lacks the accuracy, has the space of improvement.

Disclosure of Invention

The present utility model aims to solve one of the technical problems existing in the prior art or related technologies.

The technical scheme adopted by the utility model is as follows: a pattern knitting machine for producing a kerosene heating stove wick, comprising: the conveying module comprises a base, a first guide pipe, a support, a conveying wheel, a synchronous gear, a motor and an angle sensor, wherein the base is arranged on the main body, the first guide pipe is arranged at the top end of the base, the support is symmetrically fixed at the top end of the base, the conveying wheel is symmetrically arranged on the support, the synchronous gear is arranged on one side of the conveying wheel, the motor is arranged on the other side of the conveying wheel, and the angle sensor is arranged on the end part of the other conveying wheel.

The cutting module comprises a rectangular plate fixed at the top end of the base, a second guide pipe arranged on the rectangular plate, a first electric telescopic rod symmetrically arranged on the rectangular plate, an extrusion part fixed on the end part of the first electric telescopic rod, a support fixed at the top end of the base, a third guide pipe fixed at one side of the support, a second electric telescopic rod symmetrically arranged in the inner cavity of the support and an annular blade arranged at the end part of the second electric telescopic rod and extending out of the support.

The present utility model may be further configured in a preferred example to: the main body module comprises a bottom plate and a flower braiding machine main body arranged at the top end of the bottom plate.

The present utility model may be further configured in a preferred example to: the synchronous gears on the conveying wheels are meshed with each other, and grooves are formed in the outer side face of the conveying wheels in an annular array.

The present utility model may be further configured in a preferred example to: the center points of the first guide pipe, the second guide pipe and the third guide pipe are positioned on the same horizontal line.

The present utility model may be further configured in a preferred example to: the inner wall of the extrusion part is provided with a protruding part with a trapezoid cross section, and an inner cavity of the protruding part is provided with an electric heating tube.

The present utility model may be further configured in a preferred example to: the top end of the support is provided with a rectangular groove, the second electric telescopic rod is fixed on the inner bottom wall of the rectangular groove, and the annular blade is embedded in the rectangular groove to move.

By adopting the technical scheme, the beneficial effects obtained by the utility model are as follows:

1. according to the utility model, the conveying module and the cutting module are arranged on one side of the flower braiding machine, when the motor drives the conveying wheel to rotate, the wick wire after the flower braiding machine body is braided is sent out to the cutting module, in the process of rotating the conveying wheel, the rotating number of turns of the conveying wheel is monitored through the angle sensor, the length of a lamp core wire passing through the conveying wheel can be accurately calculated after the number of turns is multiplied by the peripheral diameter of the conveying wheel, when the length reaches a preset value, the second electric telescopic rod drives the annular blade to move downwards to cut the lamp core wire, and the cutting module is arranged on the flower braiding machine, so that the trouble of cutting the lamp core wire manually is effectively avoided, the functionality and the practicability of the flower braiding machine are improved, and the production efficiency of the flower braiding machine is further improved.

2. According to the utility model, the first electric telescopic rods are symmetrically arranged between the conveying wheel and the cutting module, the extrusion part is arranged at the end part of the first electric telescopic rods, the protruding part is arranged on the inner wall of the extrusion part, the electric heating pipe is arranged in the inner cavity of the protruding part, the extrusion part is used for extruding and heating the cutting position of the lamp core wire, so that the cutting positions of the lamp core wire are fused together, the end part of the lamp core wire is prevented from being scattered when the subsequent cutting module is used for cutting, the attractive end is increased, and the practical performance is further improved.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic diagram of a conveying module and a cutting module according to the present utility model;

FIG. 3 is a schematic view of a portion of a transport module according to the present utility model;

FIG. 4 is a schematic illustration of the extrusion construction of the present utility model;

FIG. 5 is a schematic cross-sectional view of an extrusion of the present utility model

FIG. 6 is a schematic view of a partial cutting module according to the present utility model;

FIG. 7 is a schematic cross-sectional view of a partial cut module according to the present utility model.

Reference numerals:

100. a main body module; 110. a bottom plate; 120. a flower braiding machine main body;

200. a transport module; 210. a base; 220. a first guide tube; 230. a bracket; 240. a conveying wheel; 241. a groove; 250. a synchronizing gear; 260. a motor; 270. an angle sensor;

300. a cutting module; 310. a rectangular plate; 320. a second guide tube; 330. a first electric telescopic rod; 340. an extrusion; 341. a protruding portion; 342. an electric heating tube; 350. a support; 360. a third guide tube; 370. a second electric telescopic rod; 380. an annular blade.

Detailed Description

The objects, technical solutions and advantages of the present utility model will become more apparent by the following detailed description of the present utility model with reference to the accompanying drawings. It should be noted that, without conflict, the embodiments of the present utility model and features in the embodiments may be combined with each other.

Some embodiments of the utility model are described below with reference to the accompanying drawings,

example 1:

referring to fig. 1-7, this embodiment provides a pattern knitting machine for producing a wick of a kerosene heating stove, comprising: a main body module 100, a conveying module 200, and a cutting module 300.

The main body module 100 comprises a bottom plate 110 and a flower braiding machine main body 120 arranged at the top end of the bottom plate 110, wherein the bottom plate 110 is used for installing the flower braiding machine main body 120, the stability of the flower braiding machine main body 120 in operation is kept, and the flower braiding machine main body 120 is used for braiding a plurality of yarns into one strand to form a lamp core wire.

The conveying module 200 is used for conveying the braided lamp core wire and monitoring the length of the lamp core wire at the same time, and is convenient for subsequent cutting, and comprises a base 210 arranged on the main body module 100, a first guide pipe 220 arranged at the top end of the base 210, a bracket 230 symmetrically fixed at the top end of the base 210, a conveying wheel 240 symmetrically arranged on the bracket 230, a synchronous gear 250 arranged on one side of the conveying wheel 240, a motor 260 arranged on the other side of the conveying wheel 240 and an angle sensor 270 arranged on the end part of the other conveying wheel 240.

The base 210 is used for mounting other components to maintain stability of each component, the first guide tube 220 is used for introducing the braided lamp core wire into the delivery wheel 240, and the bracket 230 is used for mounting the delivery wheel 240 to maintain stability of the delivery wheel 240.

The rotating shaft of the conveying wheel 240 is arranged on the brackets 230 on two sides, so that the conveying wheel 240 can conveniently rotate, and the outer side surface of the conveying wheel 240 is provided with grooves 241 in an annular array for increasing the friction force between the conveying wheel 240 and the lamp core wire and conveniently driving the lamp core wire to move.

The synchronizing gears 250 are fixedly sleeved on the rotating shafts of the conveying wheels 240 extending out of the support 230, and the synchronizing gears 250 on the two conveying wheels 240 are meshed with each other so as to keep rotation between the two conveying wheels 240 synchronous.

The motor 260 is mounted on the bracket 230, and has a shaft connected with the rotation shaft of the upper conveyor wheel 240 for driving the conveyor wheel 240 to rotate, thereby driving the wick wire to convey to the cutting module 300, and the angle sensor 270 is connected with the rotation shaft of the lower conveyor wheel 240 for monitoring the number of rotation turns of the conveyor wheel 240 and multiplying the number of turns by the peripheral circumference of the conveyor wheel 240, so that the length of the wick wire passing through the conveyor wheel 240 can be calculated.

The cutting module 300 is used for cutting the braided lamp core wire, and comprises a rectangular plate 310 fixed at the top end of the base 210, a second guide tube 320 installed on the rectangular plate 310, a first electric telescopic rod 330 symmetrically installed on the rectangular plate 310, an extrusion 340 fixed on the end of the first electric telescopic rod 330, a support 350 fixed at the top end of the base 210, a third guide tube 360 fixed at one side of the support 350, a second electric telescopic rod 370 symmetrically installed in the inner cavity of the support 350, and an annular blade 380 installed on the end of the second electric telescopic rod 370 and extending out of the support 350.

The rectangular plate 310 is used for installing other components of the cutting module 300, the second guide tube 320 is used for guiding the lamp core wire, and the first electric telescopic rod 330 is used for installing the extrusion 340 and driving the extrusion to move.

The extrusion 340 is semi-annular for the lamp core line is cut the position and is pressurized, makes its pressurized fusion together, avoids cutting back lamp core line and scatter.

Further, a protruding portion 341 with a trapezoid cross section is arranged on the inner wall of the extrusion piece 340 and used for reducing caliber, so that a larger extruder can be arranged on the lamp core wire, an electric heating tube 342 is arranged in the inner cavity of the protruding portion 341 and used for heating the lamp core wire, the lamp core wires are fused together, and the lamp core wire is further prevented from being scattered after being cut off.

The support 350 is used for installing annular blade 380, and open on the top of support 350 has the rectangular channel, and second electric telescopic handle 370 is fixed in the interior diapire in rectangular channel for install annular blade 380 and drive annular blade 380 and remove, annular blade 380 gomphosis is movable in the rectangular channel, makes annular blade 380 remain stability when removing, and annular blade 380 is used for removing under the drive of second electric telescopic handle 370 and cuts the lamp heart yearn, and third guide pipe 360 is used for introducing the lamp heart yearn to support 350 top, makes things convenient for annular blade 380 to cut.

The working principle and the using flow of the utility model are as follows: when the yarn winding machine is used, the yarn winding wheel is arranged on the flower braiding machine main body 120, one end of the yarn passes through the first guide pipe 220, the second guide pipe 320 and the third guide pipe 360, the flower braiding machine main body 120 is started, the yarn is braided to form a lamp core wire, meanwhile, the motor 260 rotates to drive the conveying wheels 240 to rotate, under the action of the synchronous gears 250, the two conveying wheels 240 keep synchronous rotation to convey the braided yarn to the cutting module 300, meanwhile, the angle sensor 270 monitors the rotating number of turns of the conveying wheels 240 in real time, the number of turns is multiplied by the peripheral circumference of the conveying wheels 240, the length of the lamp core wire passing through the conveying wheels 240 can be accurately calculated, when the length reaches a preset value, the first electric telescopic rod 330 drives the extrusion piece 340 to stretch out, the cutting position of the lamp core wire is pressurized, the lamp core wires at the position are fused together, then the second electric telescopic rod 370 drives the annular blade 380 to move downwards, the lamp core wire is cut from the cutting position, and the production of a lamp core wire is completed.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the spirit and scope of the utility model as defined by the appended claims and their equivalents.

Claims (6)

1. A pattern knitting machine for producing a kerosene heating stove wick, comprising: the device comprises a main body module (100), a conveying module (200) and a cutting module (300), and is characterized in that the conveying module (200) comprises a base (210) arranged on the main body module (100), a first guide pipe (220) arranged at the top end of the base (210), a bracket (230) symmetrically fixed at the top end of the base (210), a conveying wheel (240) symmetrically arranged on the bracket (230), a synchronous gear (250) arranged at one side of the conveying wheel (240), a motor (260) arranged at the other side of the conveying wheel (240) and an angle sensor (270) arranged at the end part of the other conveying wheel (240);

the cutting module (300) comprises a rectangular plate (310) fixed at the top end of the base (210), a second guide tube (320) arranged on the rectangular plate (310), a first electric telescopic rod (330) symmetrically arranged on the rectangular plate (310), an extrusion part (340) fixed on the end part of the first electric telescopic rod (330), a support (350) fixed at the top end of the base (210), a third guide tube (360) fixed on one side of the support (350), a second electric telescopic rod (370) symmetrically arranged in the inner cavity of the support (350) and an annular blade (380) symmetrically arranged on the end part of the second electric telescopic rod (370) and extending out of the support (350).

2. The pattern knitting machine for producing a kerosene heating stove wick according to claim 1, characterized in that the main body module (100) includes a base plate (110) and a pattern knitting machine main body (120) mounted on the top end of the base plate (110).

3. The pattern knitting machine for producing a kerosene heating stove lamp wick according to claim 1, characterized in that the synchronizing gears (250) on the conveying wheels (240) are meshed with each other, and grooves (241) are formed on the outer side surfaces of the conveying wheels (240) in an annular array.

4. The pattern knitting machine for producing a kerosene heating stove wick according to claim 1, characterized in that the center points of the first guide pipe (220), the second guide pipe (320) and the third guide pipe (360) are located on the same horizontal line.

5. The pattern knitting machine for producing a kerosene heating stove lamp wick according to claim 1, characterized in that a protruding part (341) with a trapezoid cross section is arranged on the inner wall of the extrusion part (340), and an electric heating tube (342) is arranged in the inner cavity of the protruding part (341).

6. The pattern knitting machine for producing a kerosene heating stove wick according to claim 1, characterized in that a rectangular groove is formed at the top end of the support (350), the second electric telescopic rod (370) is fixed at the inner bottom wall of the rectangular groove, and the annular blade (380) is embedded in the rectangular groove for movement.