WO2016049908A1 - Device for manufacturing oil-storing cotton cores - Google Patents

Abstract

Provided is a device for manufacturing oil-storing cotton cores, used for oil-storing cotton cores in electronic cigarettes, and comprising: a melt blowing apparatus (201), and a meltblown-cotton receiving apparatus (202) used for receiving the meltblown fiber ejected by the melt blowing apparatus, in order to form a cylindrical oil-storing cotton core; the meltblown-cotton receiving apparatus is provided with a meltblown-fiber receiving rod (203) used for adhering to the meltblown fiber to form cylindrical cotton, and a first powered apparatus (204) which drives the meltblown-fiber receiving rod in rotation; the receiving section is used for receiving meltblown fiber; the device for manufacturing oil-storing cotton cores is also provided with a disengagement assembly (205); the disengagement assembly comprises a threaded sleeve (206) provided with an internal thread; when the first powered apparatus drives the meltblown-fiber receiving rod in rotation to form cylindrical cotton, the internal thread of the threaded sleeve fits tightly with the cylindrical cotton, causing the cylindrical cotton to move toward the first powered apparatus.

Description

Oil storage cotton core manufacturing equipment Technical field

The invention relates to the field of manufacturing electronic cigarette parts, in particular to an oil storage cotton core manufacturing equipment.

Background technique

In the electronic cigarette construction, the electronic cigarette includes an oil storage assembly for storing the smoke oil and an atomization assembly for atomizing the smoke oil, wherein the atomization assembly further includes an electric heating wire assembly for atomizing the smoke oil. When the electronic cigarette is in operation, the smoke oil flows from the oil storage assembly into the atomization chamber of the atomization assembly, and the heating wire is heated by the battery rod to atomize the smoke oil into smoke. In order to improve the efficiency of the atomization of the heating wire, the smoke is generally required. The oil is evenly stored around the heating wire, and in the current electronic cigarette, the component that uniformly stores the smoke oil around the heating wire is a kind of columnar cotton.

In the prior art, the apparatus for manufacturing the columnar cotton includes a meltblipping machine and a receiving device. As shown in FIG. 1 , the receiving device is provided with a base 101. The two ends of the base 101 are connected with a first fixing base 102 and a second fixing base. The first motor 104, the second motor 105, and the roller device 106 are externally connected to the first fixing base 102 and the second fixing base 103. The second fixing base 103 is further provided with a roller 108. The first motor 104 and the second motor 105 are both connected to the external thread guide 107 on the first fixing base 103 via a conveyor belt, and the external thread guide 107 of the melt blowing machine between the first fixing base 102 and the second fixing base 103 One side. When the device is in operation, the meltblipping machine blows the cotton threaded guide 107, the first motor 104 drives the external thread guide 107 to rotate, and the second motor 105 drives the external thread guide 107 to rotate and move, and rotates with the first motor. Differently, the columnar cotton on the external thread guide 107 is rotated to the other side of the second fixing base 103 through the roller device 106 on the second fixing base 103, and the cylindrical cotton is produced.

Due to the increasingly finer e-cigarette process, the requirements for the diameter of the columnar cotton are relatively small. However, in the prior art, when the columnar cotton to be produced is relatively small, an externally threaded guide rod having a small diameter is required, and the diameter of the externally threaded guide rod is too small, and the cotton and the guide rod attached to the externally threaded guide rod are The friction between the two is relatively small. When the external thread guide rod transmits the columnar cotton through the second fixing seat, the friction between the columnar cotton and the guide rod is relatively small, and when blocked, it may be hindered in the first Between the fixing seat and the second fixing seat, the columnar cotton cannot be conveyed. Moreover, the columnar cotton manufactured by the externally threaded guide rods is internally threaded to form an internal thread groove, which not only limits the smoke oil. The amount of oil stored also hinders the flow of smoke.

Summary of the invention

In view of this, the present invention provides an oil storage wick manufacturing apparatus for manufacturing an electronic cigarette component.

An oil storage cotton core manufacturing equipment, comprising:

a meltblowing device and a meltblown cotton receiving device for receiving a fuse blown by the meltblown device to form a columnar oil storage wick;

The meltblown cotton receiving device is provided with a fuse receiving rod for adhering the fuse to form the columnar cotton, and a first power device for driving the fuse receiving rod to rotate;

The fuse receiving rod is provided with a connecting section and a receiving section, the connecting section is connected with the first power device; the receiving section is for receiving a fuse;

The oil storage wick manufacturing apparatus further includes a detaching assembly for detaching the columnar cotton from the fuse receiving rod when the first power unit drives the fuse receiving rod to rotate to form a columnar cotton;

The detachment assembly includes a threaded sleeve provided with an internal thread, the fuse receiving rod being located in parallel with the threaded sleeve on the same line;

When the columnar cotton is formed on the fuse receiving rod, the internal thread in the threaded sleeve is in close contact with the columnar cotton, and the columnar cotton is detached from the fuse receiving rod.

The oil storage wick manufacturing apparatus, wherein the detaching assembly further comprises a second power device;

The second power device is configured to drive the threaded sleeve to rotate in a reverse direction with the fuse receiving rod, so that when the fuse receiving rod rotates to form a columnar cotton, the threaded sleeve is shaped by the column The fuse receiving rod is detached.

The oil storage wick manufacturing apparatus, wherein the detaching assembly further comprises a second power device;

The second power device is configured to drive the threaded sleeve to rotate in the same direction as the fuse receiving rod;

The second power device drives the threaded sleeve to rotate at a higher speed than the first power unit drives the threaded sleeve, so that when the fuse receiving rod rotates to form a columnar cotton, the threaded sleeve The column is detached from the fuse receiving rod.

The oil storage core manufacturing device, wherein

The oil storage wick manufacturing apparatus is further provided with a bottom plate for fixing the melt blowing device, the melt blown cotton receiving device, and the detaching assembly;

The oil storage wick manufacturing apparatus further includes a fuse for forming a column on the fuse receiving rod In the case of cotton, the fuse receiving rod and the moving assembly of the first power unit are moved.

The oil storage core manufacturing device, wherein

The moving component includes: a detector, a moving slot, a moving plate located in the moving slot, and a power component;

The detector is configured to detect whether the columnar cotton on the fuse receiving rod is formed before moving the fuse receiving rod and the first power device;

The fuse receiving rod and the first power device are located on the moving plate;

One end of the power component is connected to the moving plate, and the other end is fixed on the bottom plate;

When the detector detects that the cylindrical cotton on the fuse receiving rod has been formed, the power assembly acts on the moving plate, and the fuse receiving rod is embedded in the thread through the moving groove Inside the sleeve.

The oil storage wick manufacturing apparatus, wherein the power component comprises a cylinder and a connecting rod;

One end of the connecting rod is telescopically connected to the cylinder, and the other end is connected to the moving plate;

The cylinder is fixed to the bottom plate.

The oil storage core manufacturing device, wherein

The oil storage wick manufacturing apparatus is further provided with a bottom plate for fixing the melt blowing device, the melt blown cotton receiving device, and the detaching assembly;

The oil slick core manufacturing apparatus further includes moving the columnar cotton into the threaded sleeve before the columnar cotton on the fuse receiving rod is in close contact with the internal thread in the threaded sleeve Mobile components.

The oil storage core manufacturing device, wherein

The moving assembly includes: a moving track disposed on the bottom plate, and a moving arm located on the moving track;

The moving arm includes: a first cylinder, a second cylinder, a third cylinder, and a clamping finger;

The first cylinder is configured to extend the clamping finger to the columnar cotton before the columnar cotton on the fuse receiving rod is in close contact with the internal thread in the threaded sleeve;

The third cylinder is configured to act on the clamping finger to clamp the columnar cotton when the clamping finger moves to the columnar cotton;

The second cylinder is configured to move the clamping finger toward the end of the threaded sleeve when the clamping finger clamps the columnar cotton, so that the columnar cotton and the inner portion of the threaded sleeve Tightly threaded Combined

When the clamping finger moves the columnar cotton to fit snugly with the internal thread in the threaded sleeve, the third cylinder acts to clamp the finger to release the columnar cotton;

When the clamping finger releases the columnar cotton, the first cylinder acts to retract the clamping finger away from the columnar cotton;

The second cylinder acts to move the clamping finger away from the threaded sleeve end when the clamping finger is away from the cylindrical cotton.

The oil storage wick manufacturing apparatus, wherein the moving arm is further provided with a sliding track, a connecting block, and a moving seat;

The moving seat and the moving track;

The connecting block is located in the sliding track for connecting the clamping finger and the sliding seat.

The oil storage core manufacturing device, wherein

The oil storage wick manufacturing apparatus further includes a rolling component;

The rolling member is used to crush columnar cotton detached from the fuse receiving rod.

The oil storage core manufacturing device, wherein

The rolling component includes: a plurality of rollers, and a roller supporting block for supporting the roller;

When the columnar cotton moved by the threaded sleeve moves into the rolling member, the drum and the columnar cotton are in close contact with each other to move synchronously.

The oil storage wick manufacturing apparatus, wherein the oil wick manufacturing apparatus further comprises a receiving groove, and a fixing block for fixing the receiving groove;

The receiving slot is configured to receive columnar cotton detached from the fuse receiving rod;

The receiving groove is for conveying the cylindrical cotton to the rolling member.

The oil storage core manufacturing device, wherein

The meltblown cotton receiving device is further provided with a first connecting member for connecting the fuse receiving rod and the first power device;

The first connecting member is provided with a first gear, a first hollow shaft, and a first bearing fixing the first hollow shaft, and a first bearing seat for accommodating the first bearing, the first gear sleeve Provided on the first hollow shaft, the first hollow shaft is sleeved on the first bearing, the first bearing is sleeved on the first bearing seat, and the fuse receiving rod is connected a segment connected to the first hollow shaft;

The connecting member is further provided with a second gear, and the first power device is connected to the second gear;

The connecting member is further provided with a first conveyor belt, and the conveyor belt is sleeved on the first gear and the second gear for driving the first gear to rotate when the second gear rotates. The oil storage core manufacturing device, wherein

The detaching assembly is further provided with a second connecting member for connecting the threaded sleeve and the second power device;

The second connecting member is provided with a third gear, a second hollow shaft, and a second bearing fixing the second hollow shaft, and a second bearing seat for accommodating the second bearing, the third gear sleeve Provided on the second hollow shaft, the second hollow shaft is sleeved on the second bearing, the second bearing is sleeved on the second bearing seat, the threaded sleeve is Second bearing connection;

The second hollow shaft is further configured to fix the threaded sleeve, and the second hollow shaft is located between the second bearing and the threaded sleeve, and both are closely attached;

The second connecting member is further provided with a fourth gear, and the second power device is connected to the fourth gear;

The second connecting member is further provided with a second conveyor belt, and the second conveyor belt is sleeved on the third gear and the fourth gear for driving the third gear when the fourth gear rotates Turn. The oil storage wick manufacturing apparatus, wherein the outer peripheral surface of the receiving section is not provided with an external thread.

The oil storage wick manufacturing apparatus, wherein a cross section of the receiving section at different positions along the axial direction thereof is a convex polygon.

The oil storage core manufacturing device, wherein

The oil storage wick manufacturing apparatus further includes a cooling device, the fuse receiving rod is a metal rod, and a cooling passage is disposed in the metal rod along an axial direction thereof, and the cooling device passes the cooling passage to the The fuse receiving rod is cooled.

The oil storage wick manufacturing apparatus, wherein the threaded sleeve is a semi-threaded sleeve.

Embodiments of the present invention include an oil storage cotton core manufacturing apparatus for a storage cotton core in an electronic cigarette, comprising: a melt blowing device and a fuse for receiving the melt blowing device to form a columnar oil storage a melt blown cotton receiving device of a cotton core, the fuse blower receiving device is provided with a fuse receiving rod for adhering the fuse to form the columnar cotton, and a first power device for driving the fuse receiving rod to rotate, the fuse receiving rod is provided with a connection Segment and connection The receiving section is connected with the first power unit, the receiving section is for receiving the fuse, and the oil storage wick manufacturing apparatus is further provided for moving the columnar cotton when the first power unit drives the fuse receiving rod to rotate to form the columnar cotton. The detachment assembly includes a threaded sleeve provided with an internal thread. When the first power unit drives the fuse receiving rod to rotate to form a columnar cotton, the internal thread in the threaded sleeve closely fits the columnar cotton, and the columnar cotton is moved away from each other. The first power unit is moved. Thus, since the diameter of the threaded sleeve is larger than the diameter of the fuse receiving rod, the contact area of the internal thread in the threaded sleeve with the columnar cotton is increased, the frictional force is increased, and the conveying efficiency is improved. In addition, the inner surface of the cylindrical cotton made thereof has no thread structure, which avoids the hindrance of the flow of smoke due to the blocking of the thread structure in the prior art, and the smoke is easily condensed by the heat absorption of the smoke at the thread and the smoke oil The amount of storage is limited.

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 description of the prior art will be briefly described below. Obviously, the drawings in the following description are only It is a certain embodiment of the present invention, and other drawings can be obtained from those skilled in the art without any creative work.

1 is a schematic view showing the production of a columnar cotton provided by the prior art;

2 is a schematic structural view of an oil storage cotton core manufacturing apparatus provided by the present invention;

3 is a schematic structural view of an oil storage wick manufacturing apparatus including a second power device according to the present invention;

4 is a schematic structural view of an oil storage wick manufacturing apparatus including a moving component according to the present invention;

5 is a partial structural schematic view of another oil storage wick manufacturing apparatus including a moving component according to the present invention;

6 is a schematic structural view of an oil storage wick manufacturing apparatus including a rolling device and a cooling device according to the present invention;

FIG. 7 is a partial structural schematic view of a storage wick manufacturing apparatus including a connecting component according to the present invention.

detailed description

The invention discloses a storage cotton core manufacturing device, which is provided below with reference to FIG. 2 The specific structure of the oil storage core manufacturing equipment will be described in detail.

In this embodiment, the oil storage wick manufacturing equipment comprises:

The meltblown device 201 and the meltblown cotton receiving device 202 for receiving the fuse blown by the meltblown device to form a columnar oil storage wick.

The melt blown cotton receiving device 202 is provided with a fuse receiving rod 203 for adhering the fuse to form the columnar cotton, and a first power device 204 for driving the fuse receiving rod to rotate;

The power unit can be a motor.

The fuse receiving rod 203 is provided with a connecting section and a receiving section, the connecting section is connected to the first power device 204; the receiving section is for receiving a fuse;

The meltblowing device is located on one side of the receiving section, and the meltblowing device continuously ejects the fuse to the receiving section, and the first powering device drives the receiving section to rotate, thereby forming columnar cotton.

The oil storage wick manufacturing apparatus further includes detaching the columnar cotton from the fuse receiving rod 203 when the first power unit 204 drives the fuse receiving rod 203 to rotate to form a columnar cotton. Disengaged from component 205;

The detachment assembly 205 includes a threaded sleeve 206 provided with an internal thread, the fuse receiving rod 203 being located in parallel with the threaded sleeve 206 on the same line;

When the columnar cotton is formed on the fuse receiving rod 203, the internal thread in the threaded sleeve 206 is closely adhered to the columnar cotton, and the columnar cotton is driven to be detached from the fuse receiving rod 203;

Because when the columnar cotton and the internal thread in the threaded sleeve are closely fitted, the friction between the threaded sleeve and the columnar cotton is greater than the friction between the columnar cotton and the fuse receiving rod, and when the fuse receiving rod rotates, the columnar cotton is pressed. Disengage and move from the fuse receiving rod.

In this embodiment, the threaded sleeve is provided with an internal thread and is closely attached to the columnar cotton, so that since the diameter of the threaded sleeve is larger than the diameter of the fuse receiving rod, the contact area between the internal thread and the columnar cotton in the threaded sleeve is more Increases friction and improves transmission efficiency.

In the above embodiment, it is described that the first power unit drives the fuse receiving rod to rotate, so that the columnar cotton on the fuse receiving rod and the threaded sleeve generate frictional force, thereby causing the columnar cotton to be detached from the fuse receiving rod, in practice. In an application, the detachment assembly further includes a second power unit for driving the threaded sleeve to rotate, thereby detaching the columnar cotton from the fuse receiving rod. Referring to FIG. 3, the second power unit of the detaching assembly is described below. In another embodiment of the invention, another embodiment of the oil storage wick manufacturing apparatus includes:

The meltblown device 201 and the meltblown cotton receiving device 202 for receiving the fuse blown by the meltblown device to form a columnar oil storage wick.

The melt blown cotton receiving device 202 is provided with a fuse receiving rod 203 for adhering the fuse to form the columnar cotton, and a first power device 204 for driving the fuse receiving rod to rotate;

The power unit can be a motor.

The fuse receiving rod 203 is provided with a connecting section and a receiving section, the connecting section is connected to the first power device 204; the receiving section is for receiving a fuse;

The meltblowing device is located on one side of the receiving section, and the meltblowing device continuously ejects the fuse to the receiving section, and the first powering device drives the receiving section to rotate, thereby forming columnar cotton.

The oil storage wick manufacturing apparatus further includes detaching the columnar cotton from the fuse receiving rod 203 when the first power unit 204 drives the fuse receiving rod 203 to rotate to form a columnar cotton. Disengaged from component 205;

The detachment assembly 205 includes a threaded sleeve 206 provided with an internal thread, the fuse receiving rod 203 being located in parallel with the threaded sleeve 206 on the same line;

When the columnar cotton is formed on the fuse receiving rod 203, the internal thread in the threaded sleeve 206 is closely adhered to the columnar cotton, and the columnar cotton is driven to be detached from the fuse receiving rod 203;

Because when the columnar cotton and the internal thread in the threaded sleeve are closely fitted, the friction between the threaded sleeve and the columnar cotton is greater than the friction between the columnar cotton and the fuse receiving rod, and when the fuse receiving rod rotates, the columnar cotton is pressed. Disengage and move from the fuse receiving rod.

The detachment assembly further includes a second power device 301;

The second power device 301 is configured to drive the threaded sleeve 206 to rotate in a reverse direction with the fuse receiving rod 203, so that when the fuse receiving rod 203 rotates to form a columnar cotton, the threaded sleeve will The column is detached from the fuse receiving rod;

Since the friction between the cylindrical cotton and the threaded sleeve is greater than the friction between the cylindrical cotton and the fuse receiving rod, when the threaded sleeve is opposite to the rotation of the fuse receiving rod, the cylindrical cotton is inevitably detached from the fuse receiving rod.

Correspondingly, the second power device 301 is configured to drive the threaded sleeve 206 to rotate in the same direction as the fuse receiving rod 203;

The second power device 301 drives the rotational speed of the threaded sleeve 206 to be greater than the rotational speed of the first power unit 204 to drive the fuse receiving rod 203, so that when the fuse receiving rod 203 rotates upwardly When the columnar cotton is formed, the cylindrical sleeve 206 is detached from the fuse receiving rod 203;

Since the friction between the cylindrical cotton and the threaded sleeve is greater than the friction between the cylindrical cotton and the fuse receiving rod, when there is a speed difference between the rotation of the threaded sleeve and the fuse receiving rod, the cylindrical cotton is inevitably received from the fuse receiving rod. Get out of the way.

In this embodiment, the second power device drives the threaded sleeve to rotate, and the first device drives the fuse receiving rod to rotate. The cylindrical cotton can be detached from the fuse receiving rod because the rotational speeds of the two are different or the rotating directions are opposite. Since the requirements of the columnar cotton required for the electronic cigarette are different, it is necessary to control the rotation speed of the fuse receiving rod during the manufacturing process, and a power device is respectively provided for the threaded sleeve and the fuse receiving rod, which can be used in the production process. Fine-tuning parts improves manufacturing efficiency.

In the above embodiment, the internal thread in the threaded sleeve is closely attached to the columnar cotton so that the columnar cotton is detached from the fuse receiving rod. In practical applications, the first section will be formed when the apparatus is just starting to work. The embodiment in which the columnar cotton is placed in the threaded sleeve includes a moving assembly, and the movable assembly is specifically described below. In the embodiment of the present invention, another embodiment of the oil storage core manufacturing apparatus includes:

A melt blown device and a meltblown cotton receiving device for receiving a fuse blown by the meltblown device to form a columnar oil storage wick.

The meltblown cotton receiving device is provided with a fuse receiving rod for adhering the fuse to form the columnar cotton, and a first power device for driving the fuse receiving rod to rotate;

The power unit can be a motor.

The fuse receiving rod is provided with a connecting section and a receiving section, the connecting section is connected with the first power device; the receiving section is for receiving a fuse;

The meltblowing device is located on one side of the receiving section, and the meltblowing device continuously ejects the fuse to the receiving section, and the first powering device drives the receiving section to rotate, thereby forming columnar cotton.

The oil storage wick manufacturing apparatus further includes a detaching assembly for detaching the columnar cotton from the fuse receiving rod when the first power unit drives the fuse receiving rod to rotate to form a columnar cotton;

The detachment assembly includes a threaded sleeve provided with an internal thread, the fuse receiving rod being located in parallel with the threaded sleeve on the same line;

When the columnar cotton is formed on the fuse receiving rod, the internal thread in the threaded sleeve is in close contact with the columnar cotton, and the columnar cotton is driven to be detached from the fuse receiving rod;

Because when the columnar cotton and the internal thread in the threaded sleeve are closely fitted, the friction between the threaded sleeve and the columnar cotton is greater than the friction between the columnar cotton and the fuse receiving rod, and when the fuse receiving rod rotates, the columnar cotton is pressed. Disengage and move from the fuse receiving rod.

The detachment assembly further includes a second power device;

The second power device is configured to drive the threaded sleeve to rotate in a reverse direction with the fuse receiving rod, such that when the fuse receiving rod rotates to form a columnar cotton, the threaded sleeve will Disengaging the fuse receiving rod;

Since the friction between the cylindrical cotton and the threaded sleeve is greater than the friction between the cylindrical cotton and the fuse receiving rod, when the threaded sleeve is opposite to the rotation of the fuse receiving rod, the cylindrical cotton is inevitably detached from the fuse receiving rod.

Correspondingly, the second power device is configured to drive the threaded sleeve to rotate in the same direction as the fuse receiving rod;

The second power device drives the threaded sleeve to rotate at a higher speed than the first power unit drives the fuse receiving rod, so that when the fuse receiving rod rotates to form a columnar cotton, the threaded sleeve The column is detached from the fuse receiving rod;

Since the friction between the cylindrical cotton and the threaded sleeve is greater than the friction between the cylindrical cotton and the fuse receiving rod, when there is a speed difference between the rotation of the threaded sleeve and the fuse receiving rod, the cylindrical cotton is inevitably received from the fuse receiving rod. Get out of the way.

The oil storage wick manufacturing apparatus is further provided with a bottom plate 401 for fixing the melt blowing device, the meltblown receiving device, and the detaching assembly;

The sump manufacturing apparatus further includes a moving assembly for moving the fuse receiving rod and the first power unit when a fuse on the fuse receiving rod forms a columnar cotton.

Preferably, the moving component comprises: a detector 402, a moving slot 403, a moving plate 404 located in the moving slot 403, and a power component 405;

The detector 402 is configured to detect whether the columnar cotton on the fuse receiving rod is formed before moving the fuse receiving rod and the first power device;

The fuse receiving rod and the first power device are located on the moving plate 404;

One end of the power component 405 is connected to the moving plate 404, and the other end is fixed on the bottom plate 401;

When the detector 402 detects that the cylindrical cotton on the fuse receiving rod has been formed, the power The assembly 405 acts on the moving plate 404 through which the fuse receiving rod is embedded in the threaded sleeve.

Preferably, the power assembly 405 includes a cylinder 406 and a connecting rod 407;

One end of the connecting rod 407 is telescopically connected to the cylinder 406, and the other end is connected to the moving plate 404;

The cylinder 406 is fixed to the bottom plate 401.

In this embodiment, when the device is just starting to work, the detecting device detects whether the fuse on the fuse receiving rod forms a columnar cotton, and then controls the moving component to embed the fuse receiving rod into the threaded sleeve, so that the columnar cotton and the thread The sleeve fits snugly. In this way, the fully automated production of the device is realized, and the usability of the device is improved.

In the above embodiment, it is described that the fuse receiving rod is moved into the threaded sleeve by moving the component, and in practical applications, the columnar cotton on the fuse receiving rod can be directly moved into the threaded sleeve by the moving component. As shown in FIG. 5, another embodiment of the mobile component manufacturing apparatus is specifically described below. In the embodiment of the present invention, another embodiment of the oil storage wick manufacturing apparatus includes:

A melt blown device and a meltblown cotton receiving device for receiving a fuse blown by the meltblown device to form a columnar oil storage wick.

The meltblown cotton receiving device is provided with a fuse receiving rod for adhering the fuse to form the columnar cotton, and a first power device for driving the fuse receiving rod to rotate;

The power unit can be a motor.

The fuse receiving rod is provided with a connecting section and a receiving section, the connecting section is connected with the first power device; the receiving section is for receiving a fuse;

The meltblowing device is located on one side of the receiving section, and the meltblowing device continuously ejects the fuse to the receiving section, and the first powering device drives the receiving section to rotate, thereby forming columnar cotton.

The oil storage wick manufacturing apparatus further includes a detaching assembly for detaching the columnar cotton from the fuse receiving rod when the first power unit drives the fuse receiving rod to rotate to form a columnar cotton;

The detachment assembly includes a threaded sleeve provided with an internal thread, the fuse receiving rod being located in parallel with the threaded sleeve on the same line;

When the columnar cotton is formed on the fuse receiving rod, the internal thread in the threaded sleeve is in close contact with the columnar cotton, and the columnar cotton is driven to be detached from the fuse receiving rod;

Because when the columnar cotton and the internal thread in the threaded sleeve are closely fitted, the friction between the threaded sleeve and the columnar cotton is greater than the friction between the columnar cotton and the fuse receiving rod, and when the fuse receiving rod rotates, the columnar cotton is pressed. Disengage and move from the fuse receiving rod.

The detachment assembly further includes a second power device;

The second power device is configured to drive the threaded sleeve to rotate in a reverse direction with the fuse receiving rod, such that when the fuse receiving rod rotates to form a columnar cotton, the threaded sleeve will Disengaging the fuse receiving rod;

Since the friction between the cylindrical cotton and the threaded sleeve is greater than the friction between the cylindrical cotton and the fuse receiving rod, when the threaded sleeve is opposite to the rotation of the fuse receiving rod, the cylindrical cotton is inevitably detached from the fuse receiving rod.

Correspondingly, the second power device is configured to drive the threaded sleeve to rotate in the same direction as the fuse receiving rod 203;

The second power device drives the threaded sleeve to rotate at a higher speed than the first power unit drives the fuse receiving rod, so that when the fuse receiving rod rotates to form a columnar cotton, the threaded sleeve The column is detached from the fuse receiving rod;

Since the friction between the cylindrical cotton and the threaded sleeve is greater than the friction between the cylindrical cotton and the fuse receiving rod, when there is a speed difference between the rotation of the threaded sleeve and the fuse receiving rod, the cylindrical cotton is inevitably received from the fuse receiving rod. Get out of the way.

The oil storage wick manufacturing apparatus is further provided with a bottom plate 501 for fixing the melt blowing device, the meltblown receiving device, and the detaching assembly;

The oil slick core manufacturing apparatus further includes moving the columnar cotton into the threaded sleeve before the columnar cotton on the fuse receiving rod is in close contact with the internal thread in the threaded sleeve Mobile components.

Preferably, the moving component comprises: a moving track 502 disposed on the bottom plate 501, and a moving arm located on the moving track 502;

The moving arm includes: a first cylinder 504, a second cylinder 505, a third cylinder 506, and a clamping finger 507;

The first cylinder 504 is configured to extend the clamping finger 507 to the columnar cotton before the columnar cotton on the fuse receiving rod is in close contact with the internal thread in the threaded sleeve 206;

The third cylinder 506 is used when the clamping finger 507 is moved to the columnar cotton The clamping finger 507 clamps the columnar cotton;

The second cylinder 505 is configured to move the clamping finger 507 toward the end of the threaded sleeve when the clamping finger 507 clamps the columnar cotton, so that the columnar cotton and the threaded sleeve The internal thread in 206 is closely fitted;

When the clamping finger 507 moves the columnar cotton to fit snugly with the internal thread in the threaded sleeve, the third cylinder 506 acts on the clamping finger 507 to release the columnar cotton;

When the clamping finger 507 releases the columnar cotton, the first cylinder 504 acts to retract the clamping finger 507 away from the columnar cotton;

When the clamping finger 507 is away from the cylindrical cotton, the second cylinder 505 acts to move the clamping finger 507 away from the threaded sleeve end.

Preferably, the moving arm is further provided with a sliding track 508, a connecting block 509, and a moving seat 510;

The moving base 510 and the moving track 502;

The connecting block 509 is located in the sliding rail 508 for connecting the clamping finger 507 and the sliding seat 510.

In this embodiment, when the device is just starting to work, the cylindrical cylinder is inserted into the threaded sleeve formed by the clamping of the finger on the fuse receiving rod by the three cylinders. At this time, the columnar cotton has been connected with the fuse receiving rod. The detachment begins, causing the threaded sleeve to more effectively move the subsequent columnar cotton out of the fuse receiving rod and move.

In the above embodiment, it is described that the threaded sleeve and the columnar cotton generate a large friction force, so that the columnar cotton is detached from the fuse receiving rod. In practical applications, after the columnar cotton is detached, the columnar cotton is also required to be crushed. The outer peripheral surface is smoothed to become a required component. As shown in FIG. 6, the rolling component for rolling the columnar cotton after the fuse receiving rod is detached is specifically described below. In the embodiment of the present invention, Another embodiment of a reservoir wick manufacturing apparatus includes:

The meltblown device 201 and the meltblown cotton receiving device 202 for receiving the fuse blown by the meltblown device to form a columnar oil storage wick.

The melt blown cotton receiving device 202 is provided with a fuse receiving rod 203 for adhering the fuse to form the columnar cotton, and a first power device 204 for driving the fuse receiving rod to rotate;

The power unit can be a motor.

The fuse receiving rod 203 is provided with a connecting section and a receiving section, the connecting section is connected to the first power device 204; the receiving section is for receiving a fuse;

The meltblowing device is located on one side of the receiving section, and the meltblowing device continuously ejects the fuse to the receiving section, and the first powering device drives the receiving section to rotate, thereby forming columnar cotton.

The oil storage wick manufacturing apparatus further includes detaching the columnar cotton from the fuse receiving rod 203 when the first power unit 204 drives the fuse receiving rod 203 to rotate to form a columnar cotton. Disengaged from component 205;

The detachment assembly 205 includes a threaded sleeve 206 provided with an internal thread, the fuse receiving rod 203 being located in parallel with the threaded sleeve 206 on the same line;

When the columnar cotton is formed on the fuse receiving rod 203, the internal thread in the threaded sleeve 206 is closely adhered to the columnar cotton, and the columnar cotton is driven to be detached from the fuse receiving rod 203;

Because when the columnar cotton and the internal thread in the threaded sleeve are closely fitted, the friction between the threaded sleeve and the columnar cotton is greater than the friction between the columnar cotton and the fuse receiving rod, and when the fuse receiving rod rotates, the columnar cotton is pressed. Disengage and move from the fuse receiving rod.

The detachment assembly further includes a second power device 301;

The second power device 301 is configured to drive the threaded sleeve 206 to rotate in a reverse direction with the fuse receiving rod 203, so that when the fuse receiving rod 203 rotates to form a columnar cotton, the threaded sleeve will The column is detached from the fuse receiving rod;

Since the friction between the cylindrical cotton and the threaded sleeve is greater than the friction between the cylindrical cotton and the fuse receiving rod, when the threaded sleeve is opposite to the rotation of the fuse receiving rod, the cylindrical cotton is inevitably detached from the fuse receiving rod.

Correspondingly, the second power device 301 is configured to drive the threaded sleeve 206 to rotate in the same direction as the fuse receiving rod 203;

The second power device 301 drives the rotational speed of the threaded sleeve 206 to be greater than the rotational speed of the first power unit 204 to drive the fuse receiving rod 203, so that when the fuse receiving rod 203 rotates to form a columnar cotton The threaded sleeve 206 is detached from the fuse receiving rod 203;

Since the friction between the cylindrical cotton and the threaded sleeve is greater than the friction between the cylindrical cotton and the fuse receiving rod, when there is a speed difference between the rotation of the threaded sleeve and the fuse receiving rod, the cylindrical cotton is inevitably received from the fuse receiving rod. Get out of the way.

The oil storage wick manufacturing apparatus further includes a rolling component;

The rolling member is used to crush columnar cotton detached from the fuse receiving rod.

Preferably, the rolling member comprises: a plurality of rollers 601, and a roller supporting block 602 for supporting the rollers;

When the columnar cotton moved by the threaded sleeve 206 moves into the rolling member, the drum 601 and the columnar cotton are in close contact with each other to move synchronously.

Preferably, the oil storage wick manufacturing apparatus further includes a receiving groove 603, and a fixing block 604 for fixing the receiving groove;

The receiving groove 603 is configured to receive the columnar cotton detached from the fuse receiving rod 203;

The receiving groove 603 is for conveying the columnar cotton to the rolling member.

In this embodiment, a plurality of rollers are synchronously rotated with the columnar cotton, and the roller uniformly welds the outer peripheral surface of the columnar cotton, so that the outer peripheral surface of the columnar cotton after the rolling is smooth.

In the above embodiment, the first power unit is driven to drive the fuse receiving rod to rotate, and the second power unit drives the threaded sleeve to rotate. The rotation speed is different or the rotation direction is different, so that the threaded sleeve acts to remove the cylindrical cotton from the fuse receiving. In a practical application, a first connecting component for connecting the first power device and the fuse receiving rod and a second connecting component for connecting the second power device and the threaded sleeve are further included, as shown in FIG. In the embodiment of the present invention, another embodiment of the oil storage wick manufacturing apparatus includes:

A melt blown device and a meltblown cotton receiving device for receiving a fuse blown by the meltblown device to form a columnar oil storage wick.

The meltblown cotton receiving device is provided with a fuse receiving rod 203 for adhering the fuse to form the columnar cotton, and a first power device 204 for driving the fuse receiving rod to rotate;

The power unit can be a motor.

The fuse receiving rod 203 is provided with a connecting section and a receiving section, the connecting section is connected to the first power device 204; the receiving section is for receiving a fuse;

The meltblowing device is located on one side of the receiving section, and the meltblowing device continuously ejects the fuse to the receiving section, and the first powering device drives the receiving section to rotate, thereby forming columnar cotton.

The oil storage wick manufacturing apparatus further includes detaching the columnar cotton from the fuse receiving rod 203 when the first power unit 204 drives the fuse receiving rod 203 to rotate to form a columnar cotton. Out of the component;

The detachment assembly includes a threaded sleeve 206 provided with an internal thread, the fuse receiving rod 203 being located in parallel with the threaded sleeve 206 on the same line;

When the columnar cotton is formed on the fuse receiving rod 203, the internal thread in the threaded sleeve 206 is closely adhered to the columnar cotton, and the columnar cotton is driven to be detached from the fuse receiving rod 203;

Because when the columnar cotton and the internal thread in the threaded sleeve are closely fitted, the friction between the threaded sleeve and the columnar cotton is greater than the friction between the columnar cotton and the fuse receiving rod, and when the fuse receiving rod rotates, the columnar cotton is pressed. Disengage and move from the fuse receiving rod.

The detachment assembly further includes a second power device 301;

The second power device 301 is configured to drive the threaded sleeve 206 to rotate in a reverse direction with the fuse receiving rod 203, so that when the fuse receiving rod 203 rotates to form a columnar cotton, the threaded sleeve will The column is detached from the fuse receiving rod;

Since the friction between the cylindrical cotton and the threaded sleeve is greater than the friction between the cylindrical cotton and the fuse receiving rod, when the threaded sleeve is opposite to the rotation of the fuse receiving rod, the cylindrical cotton is inevitably detached from the fuse receiving rod.

Correspondingly, the second power device 301 is configured to drive the threaded sleeve 206 to rotate in the same direction as the fuse receiving rod 203;

The second power device 301 drives the rotational speed of the threaded sleeve 206 to be greater than the rotational speed of the first power unit 204 to drive the fuse receiving rod 203, so that when the fuse receiving rod 203 rotates to form a columnar cotton The threaded sleeve 206 is detached from the fuse receiving rod 203;

Since the friction between the cylindrical cotton and the threaded sleeve is greater than the friction between the cylindrical cotton and the fuse receiving rod, when there is a speed difference between the rotation of the threaded sleeve and the fuse receiving rod, the cylindrical cotton is inevitably received from the fuse receiving rod. Get out of the way.

The meltblown cotton receiving device is further provided with a first connecting member for connecting the fuse receiving rod 203 and the first power device 204;

The first connecting member is provided with a first gear (not shown), a first hollow shaft 702, and a first bearing 703 that fixes the first hollow shaft 702, and a portion for accommodating the first bearing 703 a bearing block 704, the first gear sleeve is sleeved on the first hollow shaft 702, the first hollow shaft 702 is sleeved on the first bearing 703, and the first bearing 703 is sleeved in the The first bearing block 704, the connecting portion of the fuse receiving rod 203 is connected to the first hollow shaft 702;

The connecting member is further provided with a second gear 705, the first power device 204 and the second Gear 705 is connected;

The connecting member is further provided with a first conveyor belt 706, and the conveyor belt 706 is sleeved on the first gear and the second gear 705 for driving the first gear when the second gear 705 rotates Turn.

Preferably, the detaching assembly is further provided with a second connecting component for connecting the threaded sleeve 206 and the second power device 301;

The second connecting member is provided with a third gear (not shown), a second hollow shaft (not shown), and a second bearing (not shown) for fixing the second hollow shaft, and for the capacity a second bearing seat 707 of the second bearing, the third gear sleeve is sleeved on the second hollow shaft, and the second hollow shaft is sleeved on the second bearing, the second bearing Nested on the second bearing seat 707, the threaded sleeve 206 is connected to the second bearing;

The second hollow shaft is further configured to fix the threaded sleeve, and the second hollow shaft is located between the second bearing and the threaded sleeve, and both are closely attached;

The second connecting member is further provided with a fourth gear (not shown), and the second power device 301 is connected to the fourth gear;

The second connecting member is further provided with a second conveyor belt 708, and the second conveyor belt 708 is sleeved on the third gear and the fourth gear for driving the fourth gear when the fourth gear rotates The three gears rotate.

In this embodiment, the first power unit is connected to the fuse receiving rod by providing a bearing and a conveyor belt, and the second power unit is connected to the threaded sleeve, so that the disassembly and installation are facilitated, and the maintenance efficiency is improved.

In the above embodiment, it is described that the rotation of the fuse receiving rod causes the fuse on the fuse receiving rod to rotate to form a columnar cotton. In practical applications, the outer peripheral surface of the fuse receiving rod can also be provided with a protrusion for adhesion. The fuse, the oil storage wick manufacturing apparatus may further be provided with a cooling device for cooling the fuse receiving rod, and the fuse receiving rod and the cooling device are specifically described below. Referring to FIG. 6, in the embodiment of the present invention, Another embodiment of a reservoir wick manufacturing apparatus includes:

The meltblown device 201 and the meltblown cotton receiving device 202 for receiving the fuse blown by the meltblown device to form a columnar oil storage wick.

The meltblown cotton receiving device 202 is provided with a fuse receiving rod for adhering a fuse to form a columnar cotton 203, and the first power device 204 that drives the fuse receiving rod to rotate;

The power unit can be a motor.

The fuse receiving rod 203 is provided with a connecting section and a receiving section, the connecting section is connected to the first power device 204; the receiving section is for receiving a fuse;

The meltblowing device is located on one side of the receiving section, and the meltblowing device continuously ejects the fuse to the receiving section, and the first powering device drives the receiving section to rotate, thereby forming columnar cotton.

The oil storage wick manufacturing apparatus further includes detaching the columnar cotton from the fuse receiving rod 203 when the first power unit 204 drives the fuse receiving rod 203 to rotate to form a columnar cotton. Disengaged from component 205;

The detachment assembly 205 includes a threaded sleeve 206 provided with an internal thread, the fuse receiving rod 203 being located in parallel with the threaded sleeve 206 on the same line;

When the columnar cotton is formed on the fuse receiving rod 203, the internal thread in the threaded sleeve 206 is closely adhered to the columnar cotton, and the columnar cotton is driven to be detached from the fuse receiving rod 203;

Because when the columnar cotton and the internal thread in the threaded sleeve are closely fitted, the friction between the threaded sleeve and the columnar cotton is greater than the friction between the columnar cotton and the fuse receiving rod, and when the fuse receiving rod rotates, the columnar cotton is pressed. Disengage and move from the fuse receiving rod.

The detachment assembly further includes a second power device 301;

The second power device 301 is configured to drive the threaded sleeve 206 to rotate in a reverse direction with the fuse receiving rod 203, so that when the fuse receiving rod 203 rotates to form a columnar cotton, the threaded sleeve will The column is detached from the fuse receiving rod;

Since the friction between the cylindrical cotton and the threaded sleeve is greater than the friction between the cylindrical cotton and the fuse receiving rod, when the threaded sleeve is opposite to the rotation of the fuse receiving rod, the cylindrical cotton is inevitably detached from the fuse receiving rod.

Correspondingly, the second power device 301 is configured to drive the threaded sleeve 206 to rotate in the same direction as the fuse receiving rod 203;

The second power device 301 drives the rotational speed of the threaded sleeve 206 to be greater than the rotational speed of the first power unit 204 to drive the fuse receiving rod 203, so that when the fuse receiving rod 203 rotates to form a columnar cotton The threaded sleeve 206 is detached from the fuse receiving rod 203;

Since the friction between the cylindrical cotton and the threaded sleeve is greater than the friction between the cylindrical cotton and the fuse receiving rod, when there is a speed difference between the rotation of the threaded sleeve and the fuse receiving rod, the cylindrical cotton is inevitably received from the fuse. The rod is detached.

The outer peripheral surface of the receiving section is not provided with an external thread;

Because the prior art removes the columnar cotton by providing an external thread on the fuse receiving rod, and the fuse receiving rod of the present invention is not provided with an external thread, and a threaded sleeve is provided to disengage the columnar cotton. Therefore, the present invention is substantially different from the prior art in technical features.

The cross section of the receiving section at different positions along its axial direction is a convex polygon.

Referring to FIG. 6, preferably, the oil storage wick manufacturing apparatus further includes a cooling device 801, the fuse receiving rod 203 is a metal rod, and a cooling passage is disposed in the metal rod along the axial direction thereof. Cooling device 801 cools fuse receiving rod 203 through the cooling passage;

Since the fuse receiving rod continuously receives the melt blowing of the meltblipping machine, the temperature is continuously increased, so that the columnar cotton is not easily cooled and formed, and the fuse receiving rod is cooled by the cooling device, which can facilitate the formation of the columnar cotton on the fuse receiving rod. The cooling passage is also provided, and the liquid of the cooling device is also prevented from contaminating the columnar cotton on the fuse receiving rod.

Preferably, the threaded sleeve is a semi-threaded sleeve;

Because the threaded sleeve and the columnar cotton act, thread marks will be formed on the outer peripheral surface of the columnar cotton, so that the outer peripheral surface of the columnar cotton is not smooth. In order to reduce the thread marks of the columnar cotton, the threaded sleeve can be set as a semi-threaded sleeve. . When it is necessary to explain, the internal thread in the threaded sleeve can be arbitrarily set when the friction between the threaded sleeve and the columnar cotton is sufficiently large.

In this embodiment, the fuse receiving rod is not provided with an external thread, so that there is no thread mark on the inner side of the detached columnar cotton, which prevents the columnar cotton from obstructing the flow of the smoke and limiting the amount of smoke when used in the electronic cigarette device. The oil storage core manufacturing equipment is also provided with a cooling device for cooling the fuse receiving rod, so that the columnar cotton is more easily cooled and formed, and the production quality is improved.

The above embodiments are only used to illustrate the technical solutions of the present invention, and are not intended to be limiting; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that The technical solutions are described as being modified, or equivalent to some of the technical features, and the modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present invention.

Claims (18)

1. An oil storage wick manufacturing apparatus, comprising: a melt blowing device and a melt blown cotton receiving device for receiving a fuse sprayed by the melt blowing device to form a columnar oil storage wick;

   The meltblown cotton receiving device is provided with a fuse receiving rod for adhering the fuse to form the columnar cotton, and a first power device for driving the fuse receiving rod to rotate;

   The fuse receiving rod is provided with a connecting section and a receiving section, the connecting section is connected with the first power device; the receiving section is for receiving a fuse;

   The oil storage wick manufacturing apparatus further includes a detaching assembly for detaching the columnar cotton from the fuse receiving rod when the first power unit drives the fuse receiving rod to rotate to form a columnar cotton;

   The detachment assembly includes a threaded sleeve provided with an internal thread, the fuse receiving rod being located in parallel with the threaded sleeve on the same line;

   When the columnar cotton is formed on the fuse receiving rod, the internal thread in the threaded sleeve is in close contact with the columnar cotton, and the columnar cotton is detached from the fuse receiving rod.
2. A slick core manufacturing apparatus according to claim 1, wherein said detachment assembly further comprises a second power unit;

   The second power device is configured to drive the threaded sleeve to rotate in a reverse direction with the fuse receiving rod, such that when the fuse receiving rod rotates to form a columnar cotton, the threaded sleeve will The fuse is detached from the receiving rod.
3. The oil storage wick manufacturing apparatus according to claim 1, wherein the detaching assembly further comprises a second power device;

   The second power device is configured to drive the threaded sleeve to rotate in the same direction as the fuse receiving rod;

   The second power device drives the threaded sleeve to rotate at a higher speed than the first power unit drives the fuse receiving rod, so that when the fuse receiving rod rotates to form a columnar cotton, the threaded sleeve The barrel detaches the column from the fuse receiving rod.
4. The oil storage wick manufacturing apparatus according to any one of claims 1 to 3, characterized in that

   The oil storage wick manufacturing apparatus is further provided with a bottom plate for fixing the melt blowing device, the melt blown cotton receiving device, and the detaching assembly;

   The oil storage wick manufacturing apparatus further includes a fuse for forming a column on the fuse receiving rod In the case of cotton, the fuse receiving rod and the moving assembly of the first power unit are moved.
5. The oil storage wick manufacturing apparatus according to claim 4, wherein

   The moving component includes: a detector, a moving slot, a moving plate located in the moving slot, and a power component;

   The detector is configured to detect whether the columnar cotton on the fuse receiving rod is formed before moving the fuse receiving rod and the first power device;

   The fuse receiving rod and the first power device are located on the moving plate;

   One end of the power component is connected to the moving plate, and the other end is fixed on the bottom plate;

   When the detector detects that the cylindrical cotton on the fuse receiving rod has been formed, the power assembly acts on the moving plate, and the fuse receiving rod is embedded in the thread through the moving groove Inside the sleeve.
6. A storage wick manufacturing apparatus according to claim 5, wherein said power assembly comprises a cylinder and a connecting rod;

   One end of the connecting rod is telescopically connected to the cylinder, and the other end is connected to the moving plate;

   The cylinder is fixed to the bottom plate.
7. The oil storage wick manufacturing apparatus according to any one of claims 1 to 3, characterized in that

   The oil storage wick manufacturing apparatus is further provided with a bottom plate for fixing the melt blowing device, the melt blown cotton receiving device, and the detaching assembly;

   The oil slick core manufacturing apparatus further includes moving the columnar cotton into the threaded sleeve before the columnar cotton on the fuse receiving rod is in close contact with the internal thread in the threaded sleeve Mobile components.
8. The oil storage wick manufacturing apparatus according to claim 7, wherein

   The moving assembly includes: a moving track disposed on the bottom plate, and a moving arm located on the moving track;

   The moving arm includes: a first cylinder, a second cylinder, a third cylinder, and a clamping finger;

   The first cylinder is configured to extend the clamping finger to the columnar cotton before the columnar cotton on the fuse receiving rod is in close contact with the internal thread in the threaded sleeve;

   The third cylinder is configured to act on the clamping finger to clamp the columnar cotton when the clamping finger moves to the columnar cotton;

   The second cylinder is configured to move the clamping finger toward the end of the threaded sleeve when the clamping finger clamps the columnar cotton, so that the columnar cotton and the inner portion of the threaded sleeve The threads are tightly fitted;

   When the clamping finger moves the columnar cotton to fit snugly with the internal thread in the threaded sleeve, the third cylinder acts to clamp the finger to release the columnar cotton;

   When the clamping finger releases the columnar cotton, the first cylinder acts to retract the clamping finger away from the columnar cotton;

   The second cylinder acts to move the clamping finger away from the threaded sleeve end when the clamping finger is away from the cylindrical cotton.
9. The oil storage wick manufacturing apparatus according to claim 8, wherein the moving arm is further provided with a sliding rail, a connecting block, and a moving seat;

   The moving seat is within the moving track;

   The connecting block is located in the sliding track for connecting the clamping finger and the sliding seat.
10. The oil storage wick manufacturing apparatus according to any one of claims 1 to 3, characterized in that

    The oil storage wick manufacturing apparatus further includes a rolling component;

    The rolling member is used to crush columnar cotton detached from the fuse receiving rod.
11. The oil storage wick manufacturing apparatus according to claim 10, wherein

    The rolling component includes: a plurality of rollers, and a roller supporting block for supporting the roller;

    When the columnar cotton moved by the threaded sleeve moves into the rolling member, the drum and the columnar cotton are in close contact with each other to move synchronously.
12. The oil storage wick manufacturing apparatus according to claim 10, wherein the oil scum core manufacturing apparatus further comprises a receiving groove, and a fixing block for fixing the receiving groove;

    The receiving slot is configured to receive columnar cotton detached from the fuse receiving rod;

    The receiving groove is for conveying the cylindrical cotton to the rolling member.
13. The oil storage wick manufacturing apparatus according to any one of claims 1 to 3, characterized in that

    The meltblown cotton receiving device is further provided with a first connecting member for connecting the fuse receiving rod and the first power device;

    The first connecting member is provided with a first gear, a first hollow shaft, and a first bearing fixing the first hollow shaft, and a first bearing seat for accommodating the first bearing, the first gear sleeve Provided on the first hollow shaft, the first hollow shaft is sleeved on the first bearing, the first bearing is sleeved on the first bearing seat, and the fuse receiving rod is connected a segment connected to the first hollow shaft;

    The connecting member is further provided with a second gear, and the first power device is connected to the second gear;

    The connecting member is further provided with a first conveyor belt, and the conveyor belt is sleeved on the first gear and the second gear for driving the first gear to rotate when the second gear rotates.
14. The oil storage wick manufacturing apparatus according to any one of claims 1 to 3, characterized in that

    The detaching assembly is further provided with a second connecting member for connecting the threaded sleeve and the second power device;

    The second connecting member is provided with a third gear, a second hollow shaft, and a second bearing fixing the second hollow shaft, and a second bearing seat for accommodating the second bearing, the third gear sleeve Provided on the second hollow shaft, the second hollow shaft is sleeved on the second bearing, the second bearing is sleeved on the second bearing seat, the threaded sleeve is Second bearing connection;

    The second hollow shaft is further configured to fix the threaded sleeve, and the second hollow shaft is located between the second bearing and the threaded sleeve, and both are closely attached;

    The second connecting member is further provided with a fourth gear, and the second power device is connected to the fourth gear;

    The second connecting member is further provided with a second conveyor belt, and the second conveyor belt is sleeved on the third gear and the fourth gear for driving the third gear when the fourth gear rotates Turn.
15. The oil storage wick manufacturing apparatus according to any one of claims 1 to 3, characterized in that the outer peripheral surface of the receiving section is not provided with an external thread.
16. The oil-storage wick manufacturing apparatus according to claim 5, wherein the receiving section has a convex polygonal shape in a cross section at different positions in the axial direction.
17. The oil storage wick manufacturing apparatus according to any one of claims 1 to 3, characterized in that

    The oil storage wick manufacturing apparatus further includes a cooling device, the fuse receiving rod is a metal rod, and a cooling passage is disposed in the metal rod along an axial direction thereof, and the cooling device passes the cooling passage to the The fuse receiving rod is cooled.
18. The oil storage wick manufacturing apparatus according to any one of claims 1 to 3, wherein the threaded sleeve is a semi-threaded sleeve.

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