阅读说明：本技术 一种发热陶瓷芯包棉装置及方法 (Heating ceramic core cladding cotton device and method ) 是由 潘晓戈 高波 王瑾 李剑锋 黎新文 高云峰 于 2019-11-29 设计创作，主要内容包括：本申请实施例属于电子烟制造技术领域,涉及一种发热陶瓷芯包棉装置及方法。本申请提供的技术方案包括机座、固定轮组件、第一浮动轮组件、第二浮动轮组件、弹力组件及上料组件；所述第二浮动轮组件将棉布输送至所述第一浮动轮组件的卷绕部位置,所述上料组件供发热陶瓷芯安装,所述上料组件驱动发热陶瓷芯朝向所述固定轮组件移动至与所述固定轮组件的卷绕部接触并将棉布压至凹状,所述第一浮动轮组件及第二浮动轮组件在所述弹力组件的弹力下,沿朝向发热陶瓷芯的方向滑动,以使棉布包住发热陶瓷芯。能够实现发热陶瓷芯自动卷绕包棉,结构可靠,可适应较小的发热陶瓷芯,较大程度地提升了工作效率,卷棉的松紧一致,提高了卷棉的品质。(The embodiment of the application belongs to the technical field of electronic cigarette manufacturing, and relates to a heating ceramic core cladding cotton device and a method. The technical scheme provided by the application comprises a machine base, a fixed wheel assembly, a first floating wheel assembly, a second floating wheel assembly, an elastic assembly and a feeding assembly; the unsteady subassembly of second carries the cotton to the winding part position of the unsteady subassembly of first, the ceramic core installation that generates heat is supplied to the material loading subassembly, the ceramic core orientation of generating heat of material loading subassembly drive the fixed wheel subassembly move to with the winding part contact of fixed wheel subassembly and press the cotton to the concavity, the subassembly of first unsteady subassembly and the unsteady subassembly of second is in under the elasticity of elasticity subassembly, slide along the direction of the ceramic core that generates heat of orientation to make the cotton wrap the ceramic core that generates heat. Can realize the automatic package of winding of ceramic core that generates heat cotton, the structure is reliable, adaptable less ceramic core that generates heat, has promoted work efficiency to a great extent, and the elasticity of book cotton is unanimous, has improved the quality of book cotton.)

1. A heating ceramic core cotton wrapping device, which is characterized in that,

the device comprises a machine base, a fixed wheel assembly, a first floating wheel assembly, a second floating wheel assembly, an elastic assembly and a feeding assembly;

the fixed wheel assembly, the elastic assembly and the feeding assembly are arranged on the machine base, the first floating wheel assembly and the second floating wheel assembly are connected to the machine base in a sliding mode, the second floating wheel assembly conveys cotton cloth to the winding part of the first floating wheel assembly, the feeding assembly supplies heating ceramic cores to be installed, the feeding assembly drives the heating ceramic cores to move towards the fixed wheel assembly to be in contact with the winding part of the fixed wheel assembly and press the cotton cloth into a concave shape, the heating ceramic cores are in contact with the winding part of the first floating wheel assembly and the winding part of the second floating wheel assembly through the cotton cloth, the first floating wheel assembly and the second floating wheel assembly are extruded by the heating ceramic cores in the moving process of the feeding assembly and slide on the machine base along the direction of breaking away from the heating ceramic cores, and when the heating ceramic cores are in contact with the winding part of the fixed wheel assembly, under the elasticity of the elastic component, the heating ceramic core slides along the direction towards the heating ceramic core, so that the heating ceramic core is wrapped by the cotton cloth.

2. A heat generating ceramic core cotton device according to claim 1,

the first floating wheel assembly comprises a first winding wheel, a first clutch speed reducer and a first driving motor, the first driving motor is connected with the first clutch speed reducer, the first clutch speed reducer is connected with the first winding wheel, and the first winding wheel is a winding part of the first floating wheel assembly;

the second floating wheel assembly comprises a second winding wheel, a second clutch speed reducer and a second driving motor, the second driving motor is connected with the second clutch speed reducer, the second clutch speed reducer is connected with the second winding wheel, and the second winding wheel is a winding part of the second floating wheel assembly;

the fixed wheel assembly comprises a fixed wheel, a speed reducer and a third driving motor, and the fixed wheel is a winding part of the fixed wheel assembly;

the feeding assembly comprises a winding mandrel for mounting the heating ceramic core and a driving piece for driving the winding mandrel to move.

3. A heat generating ceramic core cotton device according to claim 2,

the second floating wheel assembly further comprises cotton feeding fibers and cotton pressing fibers, and the cotton feeding fibers are meshed with the gear of the second driving motor.

4. A heat generating ceramic core cotton device according to claim 2,

the base is provided with a first guide rail sliding block assembly and a second guide rail sliding block assembly, the first floating wheel assembly is installed on the first guide rail sliding block assembly and is connected to the base in a sliding mode through the first guide rail sliding block assembly, and the second floating wheel assembly is installed on the second guide rail sliding block assembly and is connected to the base in a sliding mode through the second guide rail sliding block assembly.

5. A heat generating ceramic core cotton device according to claim 2,

the first floating wheel assembly further comprises a first sliding block, the first driving motor is mounted on the first sliding block, and the first sliding block slides to enable a gear of the first driving motor to be meshed with or far away from a gear of the first clutch speed reducer.

6. A heat generating ceramic core cotton device according to claim 2,

the second floating wheel assembly further comprises a second sliding block, the second driving motor is mounted on the second sliding block, and the second sliding block slides to enable the gear of the second driving motor to be meshed with or far away from the gear of the second clutch speed reducer.

7. A heat generating ceramic core cotton device according to claim 4,

the elastic assembly comprises a first spring and a second spring, one end of the first spring and one end of the second spring are installed on the base, and the other end of the first spring and the other end of the second spring are connected with the first winding wheel assembly and the second winding wheel assembly respectively.

8. A heat generating ceramic core cotton device according to claim 7,

the center line of tight pulley is on a vertical central reference surface on the frame, first winding wheel, second winding wheel are respectively through first guide rail sliding block assembly and second guide rail sliding block assembly and frame sliding connection, first winding wheel and second winding wheel are located respectively the both sides of frame central reference surface, tight pulley center staggers with first winding wheel and second winding wheel center line and arranges, first unsteady wheel subassembly, second unsteady wheel subassembly draw close to frame central reference surface through the pulling force of first spring, second spring respectively.

9. A heat generating ceramic core cotton device according to claim 8,

the connecting line of the centers of the winding mandrel and the fixed wheel is vertical to the connecting line of the centers of the first winding wheel and the second winding wheel, and the winding mandrel can move relative to the fixed wheel along the vertical direction of the connecting line of the centers of the first winding wheel and the second winding wheel.

10. A heating ceramic core cotton wrapping method based on the heating ceramic core cotton wrapping device of any one of claims 1 to 9, which is characterized by comprising the following steps:

the heating ceramic core is arranged on the feeding assembly, and the cotton cloth is conveyed to the winding part of the first floating wheel assembly by the second floating wheel assembly;

the feeding assembly drives the heating ceramic core to move towards the fixed wheel assembly, and the first floating wheel assembly and the second floating wheel assembly are extruded by the heating ceramic core in the moving process of the feeding assembly and slide on the base along the direction of separating from the heating ceramic core;

the feeding assembly drives the heating ceramic core to move to be in contact with the winding part of the fixed wheel assembly, the first floating wheel assembly and the second floating wheel assembly slide in the direction towards the heating ceramic core under the elasticity of the elastic assembly, and the heating ceramic core is in contact with the winding part of the first floating wheel assembly and the winding part of the second floating wheel assembly through cotton cloth so that the cotton cloth wraps the heating ceramic core;

the winding part of the fixed wheel assembly, the winding part of the first floating wheel assembly and the winding part of the second floating wheel assembly rotate, cotton cloth rotates around the heating ceramic core through friction force, and winding action is finished.

Technical Field

The application relates to the technical field of electronic cigarette manufacturing, in particular to a heating ceramic core cladding cotton device and a method.

Background

With the development of the technology, the way of manufacturing the electronic cigarette atomizer by winding cotton cloth on the heating ceramic core becomes more and more extensive. Because the heating ceramic core is small in size, the heating ceramic core cotton rolling mode in the market is that cotton is rolled manually through fingers, the efficiency is slow, the tightness of the rolled cotton is inconsistent, the requirement on workers is high, and the quality of the rolled cotton is difficult to improve.

Disclosure of Invention

The invention aims to provide a heating ceramic core cotton wrapping device and method, which can realize automatic winding of heating ceramic cores, have a reliable structure, can adapt to smaller heating ceramic cores, greatly improve the working efficiency, ensure consistent tightness of the winding cotton and improve the quality of the winding cotton.

In order to solve the above-mentioned problems, embodiments of the present invention provide the following technical solutions:

a heating ceramic core cladding cotton device comprises a machine base, a fixed wheel assembly, a first floating wheel assembly, a second floating wheel assembly, an elastic assembly and a feeding assembly;

the fixed wheel assembly, the elastic assembly and the feeding assembly are arranged on the machine base, the first floating wheel assembly and the second floating wheel assembly are connected to the machine base in a sliding mode, the second floating wheel assembly conveys cotton cloth to the winding part of the first floating wheel assembly, the feeding assembly supplies heating ceramic cores to be installed, the feeding assembly drives the heating ceramic cores to move towards the fixed wheel assembly to be in contact with the winding part of the fixed wheel assembly and press the cotton cloth into a concave shape, the heating ceramic cores are in contact with the winding part of the first floating wheel assembly and the winding part of the second floating wheel assembly through the cotton cloth, the first floating wheel assembly and the second floating wheel assembly are extruded by the heating ceramic cores in the moving process of the feeding assembly and slide on the machine base along the direction of breaking away from the heating ceramic cores, and when the heating ceramic cores are in contact with the winding part of the fixed wheel assembly, under the elasticity of the elastic component, the heating ceramic core slides along the direction towards the heating ceramic core, so that the heating ceramic core is wrapped by the cotton cloth.

The first floating wheel assembly comprises a first winding wheel, a first clutch speed reducer and a first driving motor, the first driving motor is connected with the first clutch speed reducer, the first clutch speed reducer is connected with the first winding wheel, and the first winding wheel is a winding part of the first floating wheel assembly;

the second floating wheel assembly comprises a second winding wheel, a second clutch speed reducer and a second driving motor, the second driving motor is connected with the second clutch speed reducer, the second clutch speed reducer is connected with the second winding wheel, and the second winding wheel is a winding part of the second floating wheel assembly;

the fixed wheel assembly comprises a fixed wheel, a speed reducer and a third driving motor, and the fixed wheel is a winding part of the fixed wheel assembly;

the feeding assembly comprises a winding mandrel for mounting the heating ceramic core and a driving piece for driving the winding mandrel to move.

Further, the second floating wheel assembly further comprises cotton feeding fibers and cotton pressing fibers, and the cotton feeding fibers are meshed with the gear of the second driving motor.

Furthermore, be equipped with first guide rail sliding block set spare and second guide rail sliding block set spare on the frame, first floating wheel subassembly install in on the first guide rail sliding block set spare, and through first guide rail sliding block set spare sliding connection in on the frame, second floating wheel subassembly install in on the second guide rail sliding block set spare, and through second guide rail sliding block set spare sliding connection in on the frame.

Further, the first floating wheel assembly further comprises a first sliding block, the first driving motor is mounted on the first sliding block, and the first sliding block slides to enable a gear of the first driving motor to be meshed with or separated from a gear of the first clutch speed reducer;

the second floating wheel assembly further comprises a second sliding block, the second driving motor is mounted on the second sliding block, and the second sliding block slides to enable the gear of the second driving motor to be meshed with or far away from the gear of the second clutch speed reducer.

Furthermore, the elastic assembly comprises a first spring and a second spring, one end of the first spring and one end of the second spring are mounted on the base, and the other end of the first spring and the other end of the second spring are respectively connected with the first winding wheel assembly and the second winding wheel assembly.

Furthermore, the central line of the fixed wheel is arranged on a vertical central reference surface on the base, the first winding wheel and the second winding wheel are respectively connected with the base in a sliding mode through the first guide rail sliding block assembly and the second guide rail sliding block assembly, the first winding wheel and the second winding wheel are respectively located on two sides of the central reference surface of the base, the center of the fixed wheel is arranged in a staggered mode with the central connecting line of the first winding wheel and the second winding wheel, and the first floating wheel assembly and the second floating wheel assembly are respectively drawn close to the central reference surface of the base through the pulling force of the first spring and the pulling force of the second spring.

Furthermore, a connecting line of the centers of the winding mandrel and the fixed wheel is perpendicular to a connecting line of the centers of the first winding wheel and the second winding wheel, and the winding mandrel can move relative to the fixed wheel along the perpendicular direction of the connecting line of the centers of the first winding wheel and the second winding wheel.

In order to solve the technical problem mentioned above, an embodiment of the present invention further provides a method for heating ceramic core wrap, which adopts the following technical scheme:

a heating ceramic core cotton covering method is based on the heating ceramic core cotton covering device and comprises the following steps:

the heating ceramic core is arranged on the feeding assembly, and the cotton cloth is conveyed to the winding part of the first floating wheel assembly by the second floating wheel assembly;

the feeding assembly drives the heating ceramic core to move towards the fixed wheel assembly, and the first floating wheel assembly and the second floating wheel assembly are extruded by the heating ceramic core in the moving process of the feeding assembly and slide on the base along the direction of separating from the heating ceramic core;

the feeding assembly drives the heating ceramic core to move to be in contact with the winding part of the fixed wheel assembly, the first floating wheel assembly and the second floating wheel assembly slide in the direction towards the heating ceramic core under the elasticity of the elastic assembly, and the heating ceramic core is in contact with the winding part of the first floating wheel assembly and the winding part of the second floating wheel assembly through cotton cloth so that the cotton cloth wraps the heating ceramic core;

the winding part of the fixed wheel assembly, the winding part of the first floating wheel assembly and the winding part of the second floating wheel assembly rotate, cotton cloth rotates around the heating ceramic core through friction force, and winding action is finished.

Compared with the prior art, the embodiment of the invention mainly has the following beneficial effects:

a heating ceramic core cotton wrapping device and a method thereof, a feeding component drives a heating ceramic core to move towards a fixed wheel component until the heating ceramic core is contacted with a winding part of the fixed wheel component, a first floating wheel component and a second floating wheel component are extruded by the heating ceramic core in the moving process of the feeding component and slide on a machine base along the direction of separating from the heating ceramic core in the moving process of the heating ceramic core, when the heating ceramic core moves to be contacted with the winding part of the fixed wheel component, the first floating wheel component and the second floating wheel component slide along the direction of the heating ceramic core under the elastic force of an elastic component and enable the heating ceramic core to be contacted with the winding part of the first floating wheel component and the winding part of the second floating wheel component through cotton cloth so as to enable the cotton cloth to wrap the heating ceramic core, the winding part of the fixed wheel component, the winding part of the first floating wheel component and the winding part of the second floating wheel component to rotate, the cotton cloth is rotated around the heating ceramic core by friction force to complete the winding action. The application provides a ceramic core package cotton device generates heat can realize that the ceramic core that generates heat is automatic to be rolled up around the package cotton, and the structure is reliable, and adaptable less ceramic core that generates heat has promoted work efficiency to a great extent, and the elasticity of roll up cotton is unanimous, has improved the quality of roll up cotton.

Drawings

In order to illustrate the solution of the invention more clearly, the drawings that are needed in the description of the embodiments will be briefly described below, it being obvious that the drawings in the following description are some embodiments of the invention, and that other drawings may be derived from these drawings by a person skilled in the art without inventive effort.

Fig. 1 is a schematic view of an overall structure of a heating ceramic core cladding cotton device in an embodiment of the invention;

FIG. 2 is a schematic view showing a state where the second floating wheel assembly transports cotton according to the embodiment of the present invention;

FIG. 3 is a schematic view of the loading assembly moving toward the fixed wheel assembly according to the embodiment of the present invention;

FIG. 4 is a schematic view of the loading assembly contacting with the fixed wheel assembly in the embodiment of the present invention;

FIG. 5 is a schematic view illustrating a state of wrapping cotton wound by the heating ceramic core cotton wrapping device according to the embodiment of the present invention;

fig. 6 is a flow chart of a method for heating a ceramic core wrap in an embodiment of the present invention.

Description of reference numerals:

1. a machine base; 2. a fixed wheel assembly; 21. a fixed wheel; 22. a speed reducer; 23. a third drive motor; 3. a first floating wheel assembly; 31. a first winding wheel; 32. a first clutch reducer; 33. a first drive motor; 34. a first slider; 4. a second floating wheel assembly; 41. a second winding wheel; 42. a second clutch reducer; 43. a second drive motor; 44. feeding cotton fiber; 45. pressing cotton fiber; 46. a second slider; 5. a feeding assembly; 51. winding the mandrel; 6. a first guide rail slider assembly; 7. a second guide rail slider assembly; 8. a first spring; 9. a second spring; 10. a heating ceramic core; 11. cotton cloth; 12. a gear.

Detailed Description

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The terms "comprising" and "having," and any variations thereof, in the description and claims of the present invention and the description of the above figures are intended to cover non-exclusive inclusions. The terms "first," "second," and the like in the description and in the claims, or in the drawings, are used for distinguishing between different objects and not necessarily for describing a particular sequential order.

Reference herein to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment can be included in at least one embodiment of the invention. The appearances of the phrase in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. It is explicitly and implicitly understood by one skilled in the art that the embodiments described herein can be combined with other embodiments.

In order to make the technical solutions of the present invention better understood by those skilled in the art, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the relevant drawings.

Examples

A heating ceramic core cotton wrapping device, as shown in figures 1 and 2,

the device comprises a machine base 1, a fixed wheel 21 component 2, a first floating wheel component 3, a second floating wheel component 4, an elastic component and a feeding component 5;

the fixed wheel 21 component 2, the elastic component and the feeding component 5 are arranged on the machine base 1, the first floating wheel component 3 and the second floating wheel component 4 are connected on the machine base 1 in a sliding manner, the second floating wheel component 4 conveys cotton cloth 11 to the winding part of the first floating wheel component 3, the feeding component 5 supplies the heating ceramic core 10 to be arranged, the feeding component 5 drives the heating ceramic core 10 to move towards the fixed wheel 21 component 2 to be contacted with the winding part of the fixed wheel 21 component 2 and presses the cotton cloth 11 to be concave, and the heating ceramic core 10 is contacted with the winding part of the first floating wheel component 3 and the winding part of the second floating wheel component 4 through the cotton cloth 11, the first floating wheel component 3 and the second floating wheel component 4 are extruded by the heating ceramic core 10 in the moving process of the feeding component 5 to slide on the machine base 1 along the direction of separating from the heating ceramic core 10, when the heating ceramic core 10 contacts with the winding part of the fixed wheel 21 component 2, the first floating wheel component 3 and the second floating wheel component 4 slide along the direction towards the heating ceramic core 10 under the elastic force of the elastic component, so that the cotton cloth 11 wraps the heating ceramic core 10.

The heating ceramic core 10 is installed on the feeding component 5, the second floating wheel component 4 conveys the cotton cloth 11 to the winding part position of the first floating wheel component 3, the cotton cloth 11 exceeds the winding part position of the first floating wheel component 3, the feeding component 5 drives the heating ceramic core 10 to move towards the fixed wheel 21 component 2 until the heating ceramic core 10 is contacted with the winding part of the fixed wheel 21 component 2, in the moving process of the heating ceramic core 10, the first floating wheel component 3 and the second floating wheel component 4 are extruded by the heating ceramic core 10 in the moving process of the feeding component 5 and slide on the machine base 1 along the direction of separating from the heating ceramic core 10, when the heating ceramic core 10 moves to be contacted with the winding part of the fixed wheel 21 component 2, the first floating wheel component 3 and the second floating wheel component 4 slide along the direction of the heating ceramic core 10 under the elasticity of the elastic component, the heating ceramic core 10 is brought into contact with the winding portion of the first floating wheel assembly 3 and the winding portion of the second floating wheel assembly 4 through the cotton cloth 11, so that the cotton cloth 11 surrounds the heating ceramic core 10, the winding portion of the fixed wheel 21 assembly 2, the winding portion of the first floating wheel assembly 3, and the winding portion of the second floating wheel assembly 4 rotate, and the cotton cloth 11 rotates around the heating ceramic core 10 by a frictional force, thereby completing the winding operation. The application provides a cotton device of ceramic core package generates heat can realize that ceramic core 10 generates heat is automatic to be rolled up around the package cotton, and the structure is reliable, adaptable less ceramic core 10 that generates heat, has promoted work efficiency to a great extent, and the elasticity of roll up cotton is unanimous, has improved the quality of roll up cotton.

The first floating wheel assembly 3 comprises a first winding wheel 31, a first clutch speed reducer 32 and a first driving motor 33, the first driving motor 33 is connected with the first clutch speed reducer 32, the first clutch speed reducer 32 is connected with the first winding wheel 31, and the first winding wheel 31 is a winding part of the first floating wheel assembly 3.

The first floating wheel assembly 3 further includes a first slider 34, the first driving motor 33 is mounted on the first slider 34, and the first slider 34 slides to engage or separate the gear 12 of the first driving motor 33 with or from the gear 12 of the first clutch reducer 32.

The second floating wheel assembly 4 includes a second winding wheel 41, a second clutch speed reducer 42 and a second driving motor 43, the second driving motor 43 is connected to the second clutch speed reducer 42, the second clutch speed reducer 42 is connected to the second winding wheel 41, and the second winding wheel 41 is a winding portion of the second floating wheel assembly 4.

The second floating wheel assembly 4 further comprises a cotton feeding fiber 44 and a cotton pressing fiber 45, and the cotton feeding fiber 44 is meshed with the gear 12 of the second driving motor 43.

The second floating wheel assembly 4 further includes a second sliding block 46, the second driving motor 43 is mounted on the second sliding block 46, and the second sliding block 46 slides to enable the gear 12 of the second driving motor 43 to be engaged with or separated from the gear 12 of the second clutch reducer 42.

As shown in fig. 2, the heating ceramic core 10 is mounted on the feeding assembly 5, the first slider 34 moves in a direction away from the second floating wheel assembly 4, so that the gear 12 of the first driving motor 33 is disengaged from the gear 12 of the first clutch reducer 32, and the first winding wheel 31 can follow; the second slider 46 moves in a direction away from the first floating wheel assembly 3, so that the gear 12 of the second driving motor 43 and the gear 12 of the second clutch reducer 42 are disengaged, and the second winding wheel 41 can follow; the gear 12 of the second driving motor 43 is meshed with the cotton feeding wheel, the second driving motor 43 drives the cotton feeding wheel to rotate, under the action of the cotton feeding wheel 44 and the cotton pressing wheel 45, the cotton cloth 11 is conveyed towards the first floating wheel assembly 3 until the cotton cloth 11 exceeds the first cotton rolling wheel for a certain distance, and the second driving motor 43 stops rotating to realize preliminary feeding of the cotton cloth 11.

The fixed wheel 21 assembly 2 comprises a fixed wheel 21, a speed reducer 22 and a third driving motor 23, and the fixed wheel 21 is a winding part of the fixed wheel 21 assembly 2;

the feeding assembly 5 includes a winding mandrel 51 for mounting the heating ceramic core 10 and a driving member for driving the winding mandrel 51 to move.

As shown in fig. 3 and 4, the driving member drives the winding mandrel 51 and the heating ceramic core 10 sleeved on the winding mandrel 51 to move in the direction exceeding the fixed wheel 21 assembly 2 until the heating ceramic core 10 contacts the fixed wheel 21, and during the moving process, the heating ceramic core 10 presses the cotton cloth 11 into a concave shape, and contacts with the first winding wheel 31 and the second winding wheel 41 through the cotton cloth 11 to generate thrust on the first floating wheel assembly 3 and the second floating wheel assembly 4, and the first floating wheel assembly 3 and the second floating wheel assembly 4 are pressed by the heating ceramic core 10 to slide on the machine base 1 in the direction of separating from the heating ceramic core 10.

When the heat generating ceramic core 10 is in contact with the fixed wheel 21, the first winding wheel 31 and the second winding wheel 41 slide in a direction toward the heat generating ceramic core 10 by the elastic force of the elastic member, and the heat generating ceramic core 10 is brought into contact with the winding portion of the first floating wheel assembly 3 and the winding portion of the second floating wheel assembly 4 via the cotton cloth 11 so that the cotton cloth 11 wraps the heat generating ceramic core 10.

The first slider 34 moves in a direction approaching the second floating wheel assembly 4, so that the gear 12 of the first driving motor 33 is meshed with the gear 12 of the first clutch reducer 32; the second slider 46 moves in a direction approaching the first floating wheel assembly 3, so that the gear 12 of the second driving motor 43 is engaged with the gear 12 of the second clutch reducer 42; the third driving motor 23 drives the fixed wheel 21 to rotate, the first driving motor 33 drives the first winding wheel 31 to rotate, the second driving motor 43 drives the second winding wheel 41 to rotate, and the heating ceramic core 10 and the cotton cloth 11 rotate together through friction force to complete the winding action.

Be equipped with first guide rail sliding block set spare 6 and second guide rail sliding block set spare 7 on the frame 1, first floating wheel subassembly 3 install in on the first guide rail sliding block set spare 6, and pass through first guide rail sliding block set spare 6 sliding connection in on the frame 1, second floating wheel subassembly 4 install in on the second guide rail sliding block set spare 7, and pass through second guide rail sliding block set spare 7 sliding connection in on the frame 1.

In the embodiment of the invention, the first guide rail sliding block assembly 6 and the second guide rail sliding block assembly 7 both comprise a guide rail and a sliding block, the guide rail is fixed on the machine base 1, the sliding block is connected on the guide rail in a sliding manner, the first guide rail sliding block assembly 6 is arranged on the sliding block of the first guide rail sliding block assembly 6, and the second guide rail sliding block assembly 7 is arranged on the sliding block of the second guide rail sliding block assembly 7.

The elastic component comprises a first spring 8 and a second spring 9, one end of the first spring 8 and one end of the second spring 9 are installed on the machine base 1, and the other end of the first spring 8 and the other end of the second spring 9 are respectively connected with the first winding wheel 31 component and the second winding wheel 41 component.

Referring to fig. 5, the driving member drives the heating ceramic core 10 to contact the first winding wheel 31 and the second winding wheel 41 to generate a thrust force on the first floating wheel assembly 3 and the second floating wheel assembly 4, the first floating wheel assembly 3 slides in a direction away from the heating ceramic core 10 through the first guide rail slider assembly 6, the second floating wheel assembly 4 slides in a direction away from the heating ceramic core 10 through the second guide rail slider assembly 7, when the heating ceramic core 10 contacts the fixed wheel 21, the first floating wheel assembly 3 slides in a direction toward the heating ceramic core 10 under the elastic force of the first spring 8 to attach the first winding wheel 31 to the heating ceramic core 10, the second floating wheel assembly 4 slides in a direction toward the heating ceramic core 10 under the elastic force of the second spring 9 to attach the second winding wheel 41 to the heating ceramic core 10, so that the heating ceramic core 10 contacts the first winding wheel 31 and the second winding wheel 41 through the cotton cloth 11, so that the cotton cloth 11 encases the heating ceramic core 10.

The center line of tight pulley 21 is on a vertical central reference surface on frame 1, first coiling wheel 31, second coiling wheel 41 are respectively through first guide rail sliding block set 6 and second guide rail sliding block set 7 and frame 1 sliding connection, first coiling wheel 31 and second coiling wheel 41 are located respectively the both sides of frame 1 central reference surface, tight pulley 21 center and first coiling wheel 31 and second coiling wheel 41 central connection line stagger the arrangement, first floating wheel subassembly 3, second floating wheel subassembly 4 draw close to frame 1 central reference surface through the pulling force of first spring 8, second spring 9 respectively.

The connecting line of the centers of the winding mandrel 51 and the fixed wheel 21 is perpendicular to the connecting line of the centers of the first winding wheel 31 and the second winding wheel 41, and the winding mandrel 51 can move relative to the fixed wheel 21 along the perpendicular direction of the connecting line of the centers of the first winding wheel 31 and the second winding wheel 41.

In order to solve the technical problem mentioned above, an embodiment of the present invention further provides a method for heating ceramic core wrap, which adopts the following technical scheme:

a method for heating a ceramic core wrap, as shown in fig. 6, includes the following steps:

the heating ceramic core is arranged on the feeding assembly, and the cotton cloth is conveyed to the winding part of the first floating wheel assembly by the second floating wheel assembly;

the feeding assembly drives the heating ceramic core to move towards the fixed wheel assembly, and the first floating wheel assembly and the second floating wheel assembly are extruded by the heating ceramic core in the moving process of the feeding assembly and slide on the base along the direction of separating from the heating ceramic core;

the feeding assembly drives the heating ceramic core to move to be in contact with the winding part of the fixed wheel assembly, the first floating wheel assembly and the second floating wheel assembly slide in the direction towards the heating ceramic core under the elasticity of the elastic assembly, and the heating ceramic core is in contact with the winding part of the first floating wheel assembly and the winding part of the second floating wheel assembly through cotton cloth so that the cotton cloth wraps the heating ceramic core;

the winding part of the fixed wheel assembly, the winding part of the first floating wheel assembly and the winding part of the second floating wheel assembly rotate, cotton cloth rotates around the heating ceramic core through friction force, and winding action is finished.

The heating ceramic core is arranged on the feeding assembly, the first sliding block moves towards the direction far away from the second floating wheel assembly, so that the gear of the first driving motor is disengaged from the gear of the first clutch speed reducer, and the first winding wheel can follow up; the second sliding block moves towards the direction far away from the first floating wheel component, so that the gear of the second driving motor is disengaged from the gear of the second clutch speed reducer, and the second winding wheel can follow up; the gear of second driving motor with send the cotton wheel meshing, the second driving motor drive send the cotton wheel to rotate, send cotton fibre and press under cotton fibre's effect, the cotton is carried to the direction of first unsteady wheel subassembly, and until the cotton surpasses first cotton wheel certain distance, second driving motor stall realizes the preliminary material loading of cotton.

The driving piece drives the heating ceramic core to contact with the first winding wheel and the second winding wheel, and generates thrust to the first floating wheel assembly and the second floating wheel assembly, the first floating wheel assembly slides along the direction of separating from the heating ceramic core through the first guide rail sliding block assembly, the second floating wheel assembly slides along the direction of separating from the heating ceramic core through the second guide rail sliding block assembly, when the heating ceramic core contacts with the fixed wheel, the first floating wheel assembly slides along the direction of facing to the heating ceramic core under the elastic force of the first spring, so that the first winding wheel is attached to the heating ceramic core, the second floating wheel assembly slides along the direction of facing to the heating ceramic core under the elastic force of the second spring, so that the second winding wheel is attached to the heating ceramic core, thereby the heating ceramic core contacts with the first winding wheel and the second winding wheel through cotton cloth, and the heating ceramic core is wrapped by the cotton cloth.

The first sliding block moves towards the direction close to the second floating wheel component, so that a gear of the first driving motor is meshed with a gear of the first clutch speed reducer; the second sliding block moves towards the direction close to the first floating wheel assembly, so that a gear of the second driving motor is meshed with a gear of the second clutch speed reducer; the third driving motor drives the fixed wheel to rotate, the first driving motor drives the first winding wheel to rotate, the second driving motor drives the second winding wheel to rotate, the heating ceramic core and the cotton cloth rotate together through friction force, and winding action is completed.

It is to be understood that the above-described embodiments are merely illustrative of some, but not restrictive, of the broad invention, and that the appended drawings illustrate preferred embodiments of the invention without limiting its scope. This invention may be embodied in many different forms and, on the contrary, these embodiments are provided so that this disclosure will be thorough and complete. Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that various changes in the embodiments and modifications can be made, and equivalents may be substituted for elements thereof. All equivalent structures made by using the contents of the specification and the attached drawings of the invention can be directly or indirectly applied to other related technical fields, and are also within the protection scope of the patent of the invention.