CN114012791A

CN114012791A - Control method of shaver and shaver

Info

Publication number: CN114012791A
Application number: CN202111355568.1A
Authority: CN
Inventors: 王瑞
Original assignee: Foshan Shunde Leitai Electrical Appliances Manufacturing Co ltd
Current assignee: Foshan Shunde Leitai Electrical Appliances Manufacturing Co ltd
Priority date: 2021-11-16
Filing date: 2021-11-16
Publication date: 2022-02-08

Abstract

The invention relates to a control method of a shaver and the shaver. Starting a driving device, and driving the driven assembly to move through the driving device; the cutter mesh assembly is driven by the driven assembly to rotate at a first rotating speed, and when the cutter mesh assembly rotates, forward rotation and reverse rotation alternate rotation are carried out at a preset angle and a preset frequency; the inner cutter assembly is driven by the driven assembly to rotate at a second rotating speed, the second rotating speed is greater than the first rotating speed, and the inner cutter assembly abuts against the cutter net assembly when rotating and is used for cutting beards entering the cutter net assembly. The control method of the shaver provided by the invention can realize that one driving device drives a plurality of driven components to respectively rotate at different speeds, and realize that the movable cutter component and the cutter mesh component respectively rotate at different speeds. The shaver driving device using the control method has the advantages of simple structure, small volume, low production cost, high assembly efficiency, reliable performance and good beard catching capability, and can prevent the skin from being damaged due to the over-high rotating speed of the shaver net and ensure the comfort in the shaving process.

Description

Control method of shaver and shaver

Technical Field

The invention relates to the technical field of shavers, in particular to a control method of a shaver and the shaver.

Background

The electric shaver consists of a stainless steel knife net, an inner blade, a micro motor and a shell. The knife net is a fixed outer blade, and is provided with a plurality of holes into which beard can extend. The micro motor is driven by electric energy to drive the inner blade to move, and the beard extending into the hole is cut off by utilizing the shearing principle. The existing electric shaver product is small in shaving area due to the fact that the area of the shaver net is often designed to be small in order to guarantee the rigidity of the shaver net, the angle of the shaver needs to be changed continuously during use, the shaving range is enlarged, and the use and operation are troublesome. In order to solve the above problems, a razor product having a plurality of blade nets has been developed. However, the knife nets of such electric shaver products often cannot rotate, the multiple knife nets cannot rotate forward and backward independently from each other, and the multiple knife nets and the inner blade cannot rotate independently from each other. Therefore, the product has poor face-contacting performance, poor beard catching capability and beard cutting capability and low shaving efficiency.

Disclosure of Invention

Therefore, it is necessary to provide a control method of a shaver and a shaver to solve the problem that a shaver net and an inner blade rotate independently, and the shaver using the control method of the shaver has the advantages of simple structure, small volume, low production cost, high assembly efficiency, reliable performance, convenient use, strong beard catching capability and good comfort in the shaving process.

A control method of a shaver, comprising the steps of:

s01, starting a driving device, and driving the driven assembly to move through the driving device;

s02, the driven assembly drives the knife net assembly to rotate at a first rotation speed, and the knife net assembly rotates at a preset angle and a preset frequency in a forward rotation and reverse rotation alternate mode;

and S03, driving the inner cutter assembly to rotate at a second rotating speed through the driven assembly, wherein the second rotating speed is greater than the first rotating speed, and the inner cutter assembly abuts against the cutter net assembly when rotating and is used for cutting beards entering the cutter net assembly.

The invention discloses a control method of a shaver. First, the driving device drives the driven assembly to move. Subsequently, the driven assembly drives the cutter mesh assembly and the inner cutter assembly to rotate at a first rotating speed and a second rotating speed respectively. When the cutter mesh assembly rotates, the cutter mesh assembly rotates forwards and reversely alternately at a preset angle and a preset frequency. The shaver net component rotates in a positive and negative rotation mode, the beards can be captured actively by rotating in the positive and negative rotation mode, when the shaver net component rotates in one direction, part of the beards are input into the shaver net component to be cut, but part of the beards are extruded and pasted, the part of the beards are cut in the shaver net component again through the reverse rotation mode, the active capturing of the beards can be completed by the control mode, the shaving efficiency is improved, and the shaving effect is better. Combine the sword net subassembly with slow speed, interior sword subassembly with the fast degree respectively carry out pivoted control mode, interior sword subassembly offsets and cooperates with the sword net subassembly, when effectively cutting the beard in the sword net subassembly, can also effectively avoid the sword net to rotate the snatching of in-process to user's facial skin, it is effectual to shave experience. The rotating speed that makes the sword net subassembly when driving the sword net subassembly can make user's experience better at a slow speed, avoids too fast rotational speed to make skin receive the damage, guarantees the travelling comfort of the process of shaving.

According to the control method of the shaver, the cutter mesh component and the inner cutter component can be respectively controlled by one driving device to rotate at different speeds, the number of the driving devices can be saved, the overall size of the shaver is effectively reduced, and the use convenience of the shaver is improved.

In one embodiment, the driven assemblies at least include a first driven assembly and a second driven assembly, and the step of S01 specifically includes the following steps:

s11, starting a driving device, and driving the second driven assembly to move through the driving device;

and S12, driving the first driven assembly to move through the second driven assembly or the driving device.

In the above method for controlling a shaver, the driven assembly at least comprises a first driven assembly and a second driven assembly. The steps of the first embodiment of the driving device for driving the driven assembly to move comprise: firstly, the driving device drives the second driven assembly to move; subsequently, the second driven assembly drives the first driven assembly to move. Under the driving mode, the driving device drives the second driven assembly to move, the second driven assembly transmits the rotating power in one direction, and the second driven assembly outputs the rotating power to the other direction at the same time.

The steps of the second embodiment of the driving device for driving the driven assembly to move comprise: firstly, the driving device drives the second driven assembly to move; subsequently, the driving device drives the first driven assembly to move. In this driving mode, the driving device drives the first driven assembly to move at the same time as the second driven assembly is driven to move. Namely, the second driven assembly and the first driven assembly are respectively connected with the driving device, and the driving device simultaneously controls the output of the rotating power of the first driven assembly and the second driven assembly.

In one embodiment, the specific steps of S02 and S03 are as follows:

s21, the cutter mesh component is driven to rotate at a first rotation speed through one of the first driven component and the second driven component, and the cutter mesh component rotates forwards and backwards alternately at a preset angle and a preset frequency when in operation;

and S31, driving the inner cutter assembly to rotate at a second rotating speed through the other one of the first driven assembly and the second driven assembly, wherein the inner cutter assembly and the cutter net assembly are used for cutting the beard entering the cutter net assembly when moving.

In the above control method of the shaver, further, one of the first driven assembly and the second driven assembly drives the cutter mesh assembly to rotate at a first rotation speed, and the cutter mesh assembly performs forward rotation and reverse rotation alternate motion at a preset angle and a preset frequency during operation. Namely, the first driven assembly and the second driven assembly respectively drive the inner cutter assembly and the cutter mesh assembly to rotate.

In one embodiment, the first driven assembly comprises a first speed reduction module and a first transmission coupling module, the second driven assembly comprises a second speed reduction module and a second transmission coupling module, and the control method of the shaver comprises the following specific steps:

s111, starting a driving device, driving the second speed reducing module to move through the driving device, and driving the second transmission connecting module to move through the second speed reducing module;

s112, the second speed reduction module drives the first speed reduction module to move, the first speed reduction module drives the first transmission connection module to move when moving, and when the first transmission connection module moves, one end of the first transmission connection module, which is connected with the cutter mesh assembly, performs periodic reciprocating motion;

s211, driving the cutter mesh assembly to rotate at a first rotation speed through the first transmission connection module, and carrying out forward rotation and reverse rotation alternate rotation along with the first transmission connection module at a preset angle and a preset frequency when the cutter mesh assembly rotates;

and S311, driving the inner cutter assembly to rotate at a second rotating speed through the second transmission connecting module, and cutting the beard entering the cutter mesh assembly through the rotation of the inner cutter assembly.

In the control method of the shaver, further, the first driven assembly comprises a first speed reduction module and a first transmission coupling module, and the second driven assembly comprises a second speed reduction module and a second transmission coupling module. After the driving device is started, the driving device drives the second speed reducing module to move, then the second speed reducing module drives the second transmission connecting module to move, and the second transmission connecting module drives the inner cutter assembly to rotate at a second rotating speed, so that the beard is cut. The second speed reduction module drives the first speed reduction module to move when moving, then the first speed reduction module drives the first transmission connection module to move, and the first transmission connection module is connected with the cutter net assembly and drives the cutter net assembly to rotate at a first rotating speed. And the cutter mesh assembly rotates along with the first transmission connecting module to rotate in forward and reverse angles at a preset angle and a preset frequency.

In one embodiment, the period of the alternating movement of the forward rotation and the reverse rotation of the knife net component is 30-1200 times/minute.

In some embodiments, the razor control method is such that the period of alternating forward and reverse rotation of the foil is 30 times/minute. The forward and reverse alternate motion periodic frequency enables the operation of the cutter net assembly to be stable, the failure rate can be effectively reduced, and the reliability of products is improved.

In some embodiments, the razor control method comprises a period of 1200 cycles/minute for alternating forward and reverse rotation of the foil member. The periodic frequency of the forward and reverse rotation alternate motion enables the rotating operation speed of the cutter mesh component to be high, the capturing and cutting efficiency of beards to be obviously improved, and the shaving efficiency is favorably improved.

In some embodiments, the shaving razor control method includes alternating forward and reverse rotation of the foil member for 80/min, 120/min, 500/min, 800/min, and 1000/min periods, respectively.

In one embodiment, the angle of the alternating movement of the forward rotation and the reverse rotation of the knife net component is more than or equal to 2 degrees.

In some embodiments, the alternating movement of the positive rotation and the negative rotation of the wire assembly is at an angle of 2 degrees. The angle design can ensure the stability of the rotation operation of the knife net component while ensuring the effective capturing of the beard by the knife net component.

In some embodiments, the alternating forward and reverse rotation of the foil assembly is at an angle of 30 degrees. The angle design can further enlarge the angle of the forward rotation and reverse rotation alternate motion of the cutter mesh component, the beard capturing performance is better, the capturing and cutting efficiency of the beards is favorably improved, and the shaving effect is improved.

In some embodiments, the alternating forward and reverse rotation of the foil assembly is at an angle of 90 degrees.

In one embodiment, the rotating speed range of the moving blade assembly is as follows: 1500-4500 RPM.

In some embodiments of the razor control method, the rotating speed of the moving blade assembly is 1500 RPM. The rotating speed of the moving cutter assembly can ensure effective cutting of beards, improves the running stability of the moving cutter assembly and prolongs the service life of a shaver product.

In some embodiments of the razor control method, the moving blade assembly speed is 4500 RPM. The rotating-speed movable cutter component can further improve the cutting efficiency of the movable cutter component on beards, and the use performance of products is improved.

In some embodiments of the razor control method, the rotating speed of the moving blade assembly is 2500 RPM.

A shaving razor, comprising:

the shell assembly is provided with an accommodating cavity;

the driving device is at least partially positioned in the accommodating cavity;

a knife net assembly disposed on the housing assembly;

an inner knife assembly extending at least partially into the foil assembly, the inner knife assembly being rotatable relative to the foil assembly;

the driven assembly is connected with the driving device, the driving device is used for driving the driven assembly to rotate, and the driven assembly is used for respectively driving the cutter mesh assembly and the inner cutter assembly to rotate;

a memory having a computer program stored thereon;

a processor electrically connected to the driving device, the processor being configured to implement the control method of the shaver according to any one of the preceding claims when executing the computer program.

In a second aspect of the invention, there is disclosed a shaver comprising: the device comprises a shell, a driving device, a knife net assembly, an inner knife assembly and a driven assembly. In the shaver, the driven assembly is connected with the driving device so as to output the power of the driving device outwards. The driven assembly is also used for respectively driving the cutter mesh assembly and the inner cutter assembly to respectively rotate. The shaver realizes that one driving device simultaneously controls the cutter mesh component and the inner cutter component to respectively rotate, so that the whole structure of the shaver is more compact, the volume of the product is effectively reduced, the production cost is reduced, and the use convenience of the product is also favorably improved.

Optionally, the drive means is a motor.

In one embodiment, the cutter mesh components comprise a first cutter mesh component and a second cutter mesh component, the first cutter mesh component is provided with a through hole, and the second cutter mesh component is positioned at the through hole;

the inner blade assembly including a first inner blade assembly extending at least partially into the first blade screen assembly for cutting a hair entering the first blade screen assembly, and a second inner blade assembly extending at least partially into the second blade screen assembly for cutting a hair extending into the second blade screen assembly;

the driven assembly comprises a first driven assembly and a second driven assembly, the first driven assembly is connected with the first knife net assembly, the first driven assembly is used for driving the first knife net assembly to rotate in the forward direction and rotate in the reverse direction alternately, the second driven assembly is connected with the first inner knife assembly and the second inner knife assembly, and the second driven assembly is used for driving the first inner knife assembly and the second inner knife assembly to rotate.

According to the shaver, the cutter mesh components comprise the first cutter mesh component and the second cutter mesh component, and the second cutter mesh component is located on the inner side of the first cutter mesh component. The inner blade assembly includes a first inner blade assembly extending at least partially into the first blade screen assembly for cutting hairs passing into the first blade screen assembly, and a second inner blade assembly extending at least partially into the second blade screen assembly for cutting hairs extending into the second blade screen assembly. The first driven assembly of the driven assembly is connected with the first knife net assembly to drive the first knife net assembly to rotate forwards and rotate reversely to move alternatively, and then the second knife net assembly is driven to rotate forwards and rotate reversely to move alternatively. The second driven assembly is connected with the first inner cutter assembly and the second inner cutter assembly to drive the first inner cutter assembly and the second inner cutter assembly to rotate. The shaver drives the two cutter mesh components to rotate forwards and reversely at the same time through the driving device, and also drives the first inner cutter component and the second inner cutter component to rotate at the same time, so that the shaver is simple in structure, stable in operation and good in reliability.

Optionally, the second blade mesh assembly is disposed on the first blade mesh assembly.

Optionally, the second wire mesh assembly and the second wire mesh assembly may rotate relatively.

Optionally, the system further comprises a battery energy storage module electrically connected with the processor.

In one embodiment, the number of the knife net assemblies is multiple, the number of the inner knife assemblies is multiple, the number of the driven assemblies is multiple, the multiple inner knife assemblies respectively extend into the multiple knife net assemblies, and the driven assemblies are respectively connected with the knife net assemblies and the inner knife assemblies.

In the shaver, the number of the cutter mesh components is multiple, the number of the inner cutter components is multiple, and the number of the driven components is multiple. The inner cutter assemblies extend into the cutter mesh assemblies respectively, and the driven assemblies are connected with the cutter mesh assemblies and the inner cutter assemblies respectively. The shaver with the structure can effectively increase the shaving area by arranging the plurality of cutter net components, improves the laminating property of the cutter net components and the face, and improves the use convenience. According to the shaver, the plurality of cutter net components and the plurality of inner cutter components are respectively driven to rotate by the driving device, so that the capturing capacity of the shaver on beards can be further improved, the structural space of the shaver can be greatly improved, and the production cost can be saved.

A computer-readable storage medium, on which a computer program is stored which, when being executed by a processor, carries out a method of controlling a shaver as claimed in any one of the preceding claims.

Drawings

Fig. 1 is a schematic view of an assembled shaver according to the present invention;

fig. 2 is an exploded view of the structure of the shaver according to the present invention.

Wherein, the corresponding relation between the reference signs and the component names is as follows:

100 a housing assembly;

200 a driving device;

300 cutter mesh components, 301 first cutter mesh components, 302 second cutter mesh components;

400 inner knife assembly, 401 first inner knife assembly, 402 second inner knife assembly;

500 driven assembly, 501 first driven assembly, 502 second driven assembly.

Detailed Description

In order that the above objects, features and advantages of the present invention can be more clearly understood, a more particular description of the invention will be rendered by reference to the appended drawings. It should be noted that the embodiments and features of the embodiments of the present application may be combined with each other without conflict.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, however, the present invention may be practiced in other ways than those specifically described herein, and therefore the scope of the present invention is not limited by the specific embodiments disclosed below.

A method of controlling a shaver and a shaver according to some embodiments of the present invention will be described below with reference to the accompanying drawings.

An embodiment of a first aspect of the invention discloses a control method of a shaver, comprising the following steps:

and S03, the driven assembly drives the inner cutter assembly to rotate at a second rotating speed, the second rotating speed is greater than the first rotating speed, and the inner cutter assembly abuts against the cutter mesh assembly when rotating and is used for cutting beards entering the cutter mesh assembly.

In addition to the features of the above embodiments, the present embodiment further defines: the driven assembly at least comprises a first driven assembly and a second driven assembly, and the step of S01 specifically comprises the following steps:

s11, starting a driving device, and driving a second driven assembly to move through the driving device;

Further, in the present embodiment, the specific steps of S02 and S03 are as follows:

In this embodiment, the first driven assembly comprises a first speed reduction module and a first transmission coupling module, the second driven assembly comprises a second speed reduction module and a second transmission coupling module, and the control method of the shaver comprises the following specific steps:

s111, starting a driving device, driving a second speed reducing module to move through the driving device, and driving a second transmission connecting module to move through the second speed reducing module;

s112, driving the first speed reducing module to move through the second speed reducing module, driving the first transmission connecting module to move when the first speed reducing module moves, and carrying out periodic reciprocating motion on one end of the first transmission connecting module, which is connected with the cutter mesh assembly, when the first transmission connecting module moves;

In the embodiment, the period of the alternating movement of the forward rotation and the reverse rotation of the knife net component is 30-1200 times/minute.

Alternatively, the period of the alternating movement of the forward rotation and the reverse rotation of the knife net is 30 times/min. The forward and reverse alternate motion periodic frequency enables the operation of the cutter net assembly to be stable, the failure rate can be effectively reduced, and the reliability of products is improved.

Optionally, the period of the alternating movement of the forward rotation and the reverse rotation of the knife net assembly is 1200 times/minute. The periodic frequency of the forward and reverse rotation alternate motion enables the rotating operation speed of the cutter mesh component to be high, the capturing and cutting efficiency of beards to be obviously improved, and the shaving efficiency is favorably improved.

Alternatively, the periods of the alternating forward and reverse rotation motions of the knife net assembly are respectively 80/min, 120/min, 500/min, 800/min and 1000/min.

In this embodiment, the angle of the alternating movement of the forward rotation and the reverse rotation of the knife net assembly is greater than or equal to 2 degrees.

Optionally, the angle of the alternate movement of the positive rotation and the reverse rotation of the knife net assembly is 2 degrees. The angle design can ensure the stability of the rotation operation of the knife net component while ensuring the effective capturing of the beard by the knife net component.

Optionally, the angle of the alternate movement of the positive rotation and the reverse rotation of the knife net assembly is 30 degrees. The angle design can further enlarge the angle of the forward rotation and reverse rotation alternate motion of the cutter mesh component, the beard capturing performance is better, the capturing and cutting efficiency of the beards is favorably improved, and the shaving effect is improved.

Optionally, the angle of the alternate movement of the positive rotation and the reverse rotation of the knife net assembly is 90 degrees.

In this embodiment, the rotating speed range of the moving blade assembly is as follows: 1500-4500 RPM.

Optionally, the rotating speed of the moving blade assembly is 1500 RPM. The rotating speed of the moving cutter assembly can ensure effective cutting of beards, improves the running stability of the moving cutter assembly and prolongs the service life of a shaver product.

Optionally, the moving blade assembly speed is 4500 RPM. The rotating-speed movable cutter component can further improve the cutting efficiency of the movable cutter component on beards, and the use performance of products is improved.

Optionally, the rotating speed of the moving blade assembly is 2500 RPM.

An embodiment of the second aspect of the present invention provides a shaver, as shown in fig. 1 and 2, comprising:

the shell assembly 100, the shell assembly 100 has holding cavities;

the driving device 200, at least part of the driving device 200 is positioned in the accommodating cavity;

a knife net assembly 300, the knife net assembly 300 being disposed on the housing assembly 100;

an inner blade assembly 400, the inner blade assembly 400 extending at least partially into the foil assembly 300, the inner blade assembly 400 being rotatable relative to the foil assembly 300;

the driven assembly 500, the driven assembly 500 is connected with the driving device 200, the driving device 200 is used for driving the driven assembly 500 to rotate, and the driven assembly 500 is used for respectively driving the knife net assembly 300 and the inner knife assembly 400 to rotate;

a memory having a computer program stored thereon;

a processor electrically connected to the driving device 200, the processor being configured to implement the control method of the shaver as in any one of the preceding claims when executing the computer program.

In a second aspect of the invention, there is disclosed a shaver comprising: a housing 100, a driving device 200, a knife net assembly 300, an inner knife assembly 400 and a driven assembly 500. In the shaver, the driven assembly 500 is connected to the driving device 200 to output the power of the driving device. The driven assembly 500 is also used to drive the rotation of the wire assembly 300 and the inner blade assembly 400, respectively. Namely, the shaver realizes that one driving device simultaneously controls the cutter mesh component 300 and the inner cutter component 400 to respectively rotate, so that the whole structure of the shaver is more compact, the volume of the product is effectively reduced, the production cost is reduced, and the use convenience of the product is also favorably improved.

Optionally, the driving device 200 is a motor.

In the shaver of the present embodiment, as shown in fig. 1 and 2, the cutter net assembly 300 includes a first cutter net assembly 301 and a second cutter net assembly 302, the first cutter net assembly 301 is provided with through holes, and the second cutter net assembly 302 is located at the through holes;

the inner blade assembly 400 includes a first inner blade assembly 401 and a second inner blade assembly 402, the first inner blade assembly 401 extending at least partially into the first blade screen assembly 301, the first inner blade assembly 401 being for cutting a hair entering the first blade screen assembly 301, the second inner blade assembly 402 extending at least partially into the second blade screen assembly 302, the second inner blade assembly 402 being for cutting a hair extending into the second blade screen assembly 302;

the driven assembly 500 comprises a first driven assembly 501 and a second driven assembly 502, the first driven assembly 501 is connected with the first knife net assembly 301, the first driven assembly 501 is used for driving the first knife net assembly 301 to rotate in the forward direction and the reverse direction, the second driven assembly 502 is connected with the first inner knife assembly 401 and the second inner knife assembly 402, and the second driven assembly 502 is used for driving the first inner knife assembly 401 and the second inner knife assembly 402 to rotate.

In the shaver, the cutter net assembly 300 comprises a first cutter net assembly 301 and a second cutter net assembly 302, and the second cutter net assembly 302 is positioned inside the first cutter net assembly 301. The inner blade assembly 400 includes a first inner blade assembly 401 and a second inner blade assembly 402, the first inner blade assembly 401 extending at least partially into the first blade screen assembly 301, the first inner blade assembly 401 being for cutting a hair entering the first blade screen assembly 301, the second inner blade assembly 402 extending at least partially into the second blade screen assembly 302, the second inner blade assembly 402 being for cutting a hair extending into the second blade screen assembly 302. The first driven component 501 of the driven component 500 is connected with the first knife net component 301 to drive the first knife net component 301 to rotate forward and rotate backward alternately, and further drive the second knife net component 302 to rotate forward and rotate backward alternately. The second driven assembly 502 is coupled to the first inner blade assembly 401 and the second inner blade assembly 402 to drive the first inner blade assembly 401 and the second inner blade assembly 402 to rotate. According to the shaver, the two cutter mesh components are driven by one driving device 200 to rotate forwards and reversely alternately, and the first inner cutter component 401 and the second inner cutter component 402 are driven to rotate simultaneously, so that the shaver is simple in structure, stable in operation and good in reliability.

Optionally, a second blade mesh assembly 302 is disposed on the first blade mesh assembly 301.

Optionally, the second wire assembly 302 and the second wire assembly 301 may rotate relatively.

Optionally, the system further comprises a battery energy storage module, and the battery energy storage module is electrically connected with the processor.

In the shaver of the present embodiment, the number of the cutter net assemblies 300 is plural, the number of the inner cutter assemblies 400 is plural, the number of the driven assemblies 500 is plural, the plural inner cutter assemblies 400 extend into the plural cutter net assemblies 300, respectively, and the driven assemblies 500 are connected to the cutter net assemblies 300 and the inner cutter assemblies 400, respectively.

In the above-described shaver, the number of the cutter net assemblies 300 is plural, the number of the inner cutter assemblies 400 is plural, and the number of the driven assemblies 500 is plural. The plurality of inner blade assemblies 400 extend into the plurality of foil assemblies 300, respectively, and the driven assemblies 500 are connected to the foil assemblies 300 and the inner blade assemblies 400, respectively. The shaver with the structure can effectively increase the shaving area by arranging the plurality of cutter mesh components 300, improves the laminating property of the cutter mesh components and the face, and improves the use convenience. According to the shaver, the plurality of cutter net assemblies 300 and the plurality of inner cutter assemblies 400 are respectively driven to rotate by the driving device 200, so that the beard catching capacity of the shaver can be further improved, the structural space of the shaver can be greatly improved, and the production cost can be saved.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims

1. A method of controlling a shaving razor, comprising the steps of:

2. The method for controlling a shaver as set forth in claim 1, wherein the driven assemblies include at least a first driven assembly and a second driven assembly, and the step of S01 includes the steps of:

3. The method for controlling a shaver as set forth in claim 2, wherein the specific steps of S02 and S03 are as follows:

4. The method for controlling a shaver as set forth in claim 3, wherein the first driven assembly comprises a first speed reduction module and a first transmission coupling module, and the second driven assembly comprises a second speed reduction module and a second transmission coupling module, and the method for controlling the shaver comprises the following steps:

5. The control method of a shaver as set forth in claim 1, wherein the period of the alternating movement of the net assembly in the forward rotation and the reverse rotation is 30-1200 times/min.

6. The method of controlling a shaving razor of claim 1, wherein the angle of alternating movement of the foil member in forward and reverse rotation is 2 degrees or more.

7. The method of controlling a shaving razor according to claim 1, wherein the range of rotational speeds of the movable blade assembly is: 1500-4500 RPM.

8. A shaving razor, comprising:

the shell assembly (100), the shell assembly (100) is provided with an accommodating cavity;

a driving device (200), wherein the driving device (200) is at least partially positioned in the accommodating cavity;

a knife net assembly (300), the knife net assembly (300) disposed on the housing assembly (100);

an inner knife assembly (400), the inner knife assembly (400) extending at least partially into the foil assembly (300), the inner knife assembly (400) being rotatable relative to the foil assembly (300);

the driven assembly (500), the driven assembly (500) is connected with the driving device (200), the driving device (200) is used for driving the driven assembly (500) to rotate, and the driven assembly (500) is used for respectively driving the cutter mesh assembly (300) and the inner cutter assembly (400) to rotate;

a memory having a computer program stored thereon;

a processor electrically connected to the driving device (200), the processor being configured to implement the control method of a shaver according to any one of claims 1 to 7 when executing the computer program.

9. The shaving razor of claim 8,

the cutter mesh assembly (300) comprises a first cutter mesh assembly (301) and a second cutter mesh assembly (302), a through hole is formed in the first cutter mesh assembly (301), and the second cutter mesh assembly (302) is located at the through hole;

the inner blade assembly (400) comprises a first inner blade assembly (401) and a second inner blade assembly (402), the first inner blade assembly (401) extending at least partially into the first blade net assembly (301), the first inner blade assembly (401) being for cutting a hair entering the first blade net assembly (301), the second inner blade assembly (402) extending at least partially into the second blade net assembly (302), the second inner blade assembly (402) being for cutting a hair extending into the second blade net assembly (302);

the driven assembly (500) comprises a first driven assembly (501) and a second driven assembly (502), the first driven assembly (501) is connected with the first knife net assembly (301), the first driven assembly (501) is used for driving the first knife net assembly (301) to perform forward rotation and reverse rotation alternating movement, the second driven assembly (502) is connected with the first inner knife assembly (401) and the second inner knife assembly (402), and the second driven assembly (502) is used for driving the first inner knife assembly (401) and the second inner knife assembly (402) to rotate.

10. The shaving razor of claim 7,

the quantity of sword net subassembly (300) is a plurality of, the quantity of interior sword subassembly (400) is a plurality of, the quantity of driven subassembly (500) is a plurality of, and is a plurality of interior sword subassembly (400) extends respectively to a plurality of in the sword net subassembly (300), driven subassembly (500) respectively with sword net subassembly (300) with interior sword subassembly (400) are connected.