CN111093337A

CN111093337A - Sliding mobile terminal

Info

Publication number: CN111093337A
Application number: CN201811238106.XA
Authority: CN
Inventors: 韩高才; 孙信华
Original assignee: Beijing Xiaomi Mobile Software Co Ltd
Current assignee: Beijing Xiaomi Mobile Software Co Ltd
Priority date: 2018-10-23
Filing date: 2018-10-23
Publication date: 2020-05-01
Anticipated expiration: 2038-10-23
Also published as: CN111093337B

Abstract

The disclosure relates to a sliding mobile terminal, and belongs to the technical field of terminals. The slide mobile terminal includes: the display device comprises a first machine body, a display screen, a second machine body, a first sliding component, a second sliding component, a magnetic assembly and a first power assisting device. The magnetic assembly is arranged between the first sliding component and the second sliding component, the first power assisting device is arranged between the first machine body and the second machine body and is connected with the first sliding component or the second sliding component, and the first power assisting device is used for providing power for the first sliding component or the second sliding component. This disclosed embodiment sets up first booster unit between first fuselage and second fuselage, offsets the mutual acting force that magnetic force component produced for the power that first sliding part or second sliding part provided through first booster unit, has increased the power of user when sliding, has promoted the user and has slided and feel.

Description

Sliding mobile terminal

Technical Field

The present disclosure relates to the field of terminal technology. And more particularly, to a sliding mobile terminal.

Background

As the user demand increases, the screen occupation ratio of the mobile terminal increases, which becomes a development trend of the mobile terminal. In order to meet the demand of a user for increasing the screen occupation ratio, a mobile terminal in a sliding mode is produced.

The sliding mobile terminal includes a first body and a second body, a display screen is generally disposed on the first body, and some application components are generally disposed on the second body to reduce the screen space occupied by the application components. The sliding mobile terminal generally includes a first sliding member and a second sliding member disposed between a first body and a second body, and a magnetic assembly disposed between the first sliding member and the second sliding member for preventing the first sliding member or the second sliding member from sliding by itself. In order to avoid the situation that the first body or the second body slides by itself when the magnetic force of the magnetic assembly is small, the magnetic assembly with large magnetic force is generally selected. However, the magnetic assembly with a large magnetic force causes a large resistance during sliding, and a large force is applied by a user during sliding, which causes a poor sliding hand feeling of the user.

Disclosure of Invention

The embodiment of the disclosure provides a sliding mobile terminal, which can solve the problem that the magnetic assembly with larger magnetic force has larger resistance when sliding. The technical scheme is as follows:

according to a first aspect of the embodiments of the present disclosure, there is provided a sliding mobile terminal including:

the display screen comprises a first machine body, a display screen arranged on the front surface of the first machine body, a second machine body, a first sliding component, a second sliding component, a magnetic assembly arranged between the first sliding component and the second sliding component, and a first power assisting device for providing power for the first sliding component or the second sliding component;

one end of the first sliding component is connected with the back surface of the first machine body, and the other end of the first sliding component is connected with the magnetic assembly;

one end of the second sliding component is connected with the front surface of the second machine body, and the other end of the second sliding component is connected with the magnetic assembly;

the first power assisting device is arranged between the first machine body and the second machine body and is connected with the first sliding component or the second sliding component.

In one possible implementation, the magnetic assembly includes: a first magnetic member and a second magnetic member;

the first magnetic piece is connected with the first sliding component, and the second magnetic piece is connected with the second sliding component.

In one possible implementation, the first power assist device includes: a booster motor and a booster rod;

one end of the power-assisted rod is connected with one end of the power-assisted motor;

the other end of the power-assisted rod is connected with the first sliding component, and the other end of the power-assisted motor is connected with the second sliding component or the second machine body; or the other end of the power-assisted rod is connected with the second sliding component, and the other end of the power-assisted motor is connected with the first sliding component or the first machine body.

In one possible implementation manner, the sliding mobile terminal further includes: a power-assisted switch;

the power switch is arranged between the first machine body and the second machine body and is connected with the first power device;

the power switch is used for controlling the first power assisting device to start or stop.

In one possible implementation, the power switch is a hall switch;

the Hall switch is used for sensing the magnetic field change generated by the magnetic assembly and controlling the first power assisting device to start or stop based on the magnetic field change.

In one possible implementation manner, the hall switch is disposed on the back surface of the first body, the front surface of the second body, the first sliding member, or the second sliding member.

In one possible implementation, the power switch is a pressure sensor;

the pressure sensor is used for sensing pressure change between the first machine body and the second machine body and controlling the first power assisting device to start or stop based on the pressure change.

In one possible implementation, the pressure sensor is disposed on a back surface of the first body, the first sliding member, or the second sliding member.

In one possible implementation manner, the sliding mobile terminal further includes: a second booster for powering the first slide member or the second slide member;

the second power assisting device is arranged between the first machine body and the second machine body, one end of the first sliding component or the second sliding component is connected with the second power assisting device, and the other end of the first sliding component or the second sliding component is connected with the first power assisting device.

The technical scheme provided by the embodiment of the disclosure can have the following beneficial effects:

according to the sliding mobile terminal provided by the embodiment of the disclosure, the magnetic assembly is arranged between the first sliding component and the second sliding component, one end of the first sliding component is connected with the back surface of the first machine body, the other end of the first sliding component is connected with the magnetic assembly, one end of the second sliding component is connected with the front surface of the second machine body, the other end of the second sliding component is connected with the magnetic assembly, the first power assisting device is arranged between the first machine body and the second machine body, the first power assisting device is connected with the first sliding component or the second sliding component, and the first power assisting device is used for providing power for the first sliding component or the second sliding component. This slip mobile terminal sets up first booster unit between first fuselage and second fuselage, and the power that provides for first sliding part or second sliding part through first booster unit offsets the interact power that magnetic force subassembly produced, has increased the power of user when sliding, has promoted the user and has slided and feel.

Drawings

Fig. 1 is a schematic diagram of a sliding mobile terminal provided in an embodiment of the present disclosure;

fig. 2 is a schematic diagram of another sliding mobile terminal provided by the disclosed embodiment;

fig. 3 is a schematic diagram of another sliding mobile terminal provided by the disclosed embodiment;

fig. 4 is a schematic diagram of another sliding mobile terminal provided in the embodiments of the present disclosure.

The reference numerals denote:

101-a first body, 102-a display screen, 103-a second body, 104-a first sliding member,

105-a second sliding part, 106-a magnetic assembly, 1061-a first magnetic element, 1062-a second magnetic element,

107-first power assist device, 1071-first power assist motor, 1072-first power assist lever, 108-power assist switch,

109-a second booster, 1091-a second booster motor, 1092-a second booster rod,

1010-first power switch, 1011-second power switch.

Detailed Description

In order to make the technical solutions and advantages of the present disclosure clearer, the following describes embodiments of the present disclosure in further detail.

An embodiment of the present disclosure provides a sliding mobile terminal, referring to fig. 1, the sliding mobile terminal including: the display device comprises a first body 101, a display screen 102 arranged on the front surface of the first body 101, a second body 103, a first sliding part 104, a second sliding part 105, a magnetic assembly 106 arranged between the first sliding part 104 and the second sliding part 105, and a first power assisting device 107 for providing power for the first sliding part 104 or the second sliding part 105.

One end of the first sliding member 104 is connected to the back surface of the first body 101, and the other end of the first sliding member 104 is connected to the magnetic assembly 106.

One end of the second sliding member 105 is connected to the front surface of the second body 103, and the other end of the second sliding member 105 is connected to the magnetic assembly 106.

The first power assisting device 107 is disposed between the first body 101 and the second body 103, and the first power assisting device 107 is connected to the first sliding member 104 or the second sliding member 105.

In one possible implementation, the first sliding member 104 may be disposed at a bottom end, a middle position, or a top end of the back surface of the first body 101. For example, in the embodiment of the present disclosure, the first sliding member 104 may be provided at an intermediate position on the back surface of the first body 101.

The second sliding member 105 may be disposed at a bottom end, an intermediate position, or a top end of the front surface of the second body 103. For example, in the disclosed embodiment, the second slide member 105 may be disposed at an intermediate position on the front surface of the second body 103.

The first slide member 104 and the second slide member 105 may be the same or different. In the embodiment of the present disclosure, the first slide member 104 and the second slide member 105 are not particularly limited. For example, when the first slide member 104 and the second slide member 105 are the same, the first slide member 104 and the second slide member 105 may be any slidable member, for example, the first slide member 104 and the second slide member 105 may be a slide cover or a slide rail.

The magnetic assembly 106 is disposed at an intermediate position between the first sliding member 104 and the second sliding member 105, and the magnetic assembly 106 is disposed to prevent the first sliding member 104 or the second sliding member 105 from sliding away by itself. In the disclosed embodiment, the magnetic assembly 106 is not particularly limited. For example, the magnetic assembly 106 may be a permanent magnet.

The first power assisting device 107 is arranged at the bottom end between the first body 101 and the second body 103, the first power assisting device 107 is arranged for providing power for the first sliding part 104 or the second sliding part 105, and the power provided by the first power assisting device 107 is larger than the interaction force generated by the magnetic assembly 106, so that the first body 101 or the second body 103 can be slid off with small force.

In a possible implementation manner, the size of the first body 101 and the size of the second body 103 may be the same or different. When the first body 101 and the second body 103 are the same size and in the closed state, the first body 101 and the second body 103 overlap.

When the size of the first body 101 and the size of the second body 103 are not the same, the size of the first body 101 may be larger than the size of the second body 103, and the size of the first body 101 may also be smaller than the size of the second body 103. Since the first body 101 is used to carry the display screen 102 and the second body 103 is used to carry some application components, in the embodiment of the present disclosure, the first body 101 may be set to have a size larger than that of the second body 103, and the second body 103 may be set to have a smaller size. For example, the size of the second body 103 is 1/10 or 1/15, etc. of the size of the first body 101.

The length of the first body 101 and the length of the second body 103 may be equal or unequal. When the length of the first body 101 and the length of the second body 103 are not equal, the length of the first body 101 may be greater or less than the length of the second body 103. Also, in the present disclosed embodiment, the length of the first body 101 may be set to be greater than the length of the second body 103; for example, the first body 101 has a length of 12.18 cm and the second body 103 has a length of 2 cm. Also, the length of the first body 101 and the length of the second body 103 may be set and changed as needed. When the length of the first body 101 and the length of the second body 103 are equal, for example, the length of the first body 101 and the length of the second body 103 may be 12 cm, 14 cm, or 15 cm. In the embodiment of the present disclosure, the length of the first body 101 and the length of the second body 103 are not particularly limited.

The width of the first body 101 and the width of the second body 103 may be equal or unequal, and the width of the first body 101 and the width of the second body 103 may be set and changed as needed. When the width of the first body 101 and the width of the second body 103 are not equal, the width of the first body 101 may be greater or smaller than the width of the second body 103. When the width of the first body 101 and the width of the second body 103 are equal, for example, the width of the first body 101 and the width of the second body 103 may be 8 cm, 9 cm, or 10 cm. In the embodiment of the present disclosure, the width of the first body 101 and the width of the second body 103 are not particularly limited. Also, in the present disclosed embodiment, the width of the first body 101 may be set to be greater than the width of the second body 103; for example, the width of the first body 101 is 6.85 cm, and the width of the second body 103 is 1 cm.

The thickness of the first body 101 and the thickness of the second body 103 may be equal or unequal, and the thickness of the first body 101 and the thickness of the second body 103 may be set and changed as needed. When the thickness of the first body 101 and the thickness of the second body 103 are not equal, the thickness of the first body 101 may be greater or less than the thickness of the second body 103. When the thickness of the first body 101 is greater than that of the second body 103, for example, the thickness of the first body 101 is 3 mm, and the thickness of the second body 103 is any value less than 3 mm. For example, the thickness of the second body 103 is 1 mm or 1.5 mm. In the embodiment of the present disclosure, the thickness of the first body 101 and the thickness of the second body 103 are not particularly limited. Also, in the present disclosed embodiment, the thickness of the first body 101 may be set to be greater than the thickness of the second body 103; for example, the first body 101 has a thickness of 0.5 cm, and the second body 103 has a thickness of 0.2 cm.

In one possible implementation, referring to fig. 2, the magnetic assembly 106 includes: a first magnetic member 1061 and a second magnetic member 1062.

A first magnetic member 1061 is connected to the first slide member 104, and a second magnetic member 1062 is connected to the second slide member 105.

The first magnetic member 1061 may be disposed at a bottom end, a middle position, or a top end of the first sliding member 104. In the disclosed embodiment, the position of the first magnetic member 1061 is not particularly limited.

The second magnetic member 1062 may be disposed at a bottom end, a middle position, or a top end of the second slide part 105. In the disclosed embodiment, the position of the second magnetic member 1062 is not particularly limited.

For example, when the first magnetic member 1061 is disposed at a middle position of the first sliding member 104, the second magnetic member 1062 may be disposed to be misaligned with the first magnetic member 1061. In the disclosed embodiment, the second magnetic member 1062 may be disposed at a middle lower end position of the second slide member 105.

The first magnetic member 1061 and the second magnetic member 1062 may be the same or different. In the disclosed embodiment, the first and second

magnetic members

1061 and 1062 are not particularly limited. When the first and second

magnetic members

1061 and 1062 are identical, both the first and second

magnetic members

1061 and 1062 may be permanent magnets.

It should be noted that there is both an attractive force and a repulsive force between the first magnetic member 1061 and the second magnetic member 1062. But the repulsive force is greater than the attractive force, and thus, the force between the first and second

magnetic members

1061 and 1062 acts as a repulsive force.

In one possible implementation, when the first body 101 is slid downward, the direction of the repulsive force between the first magnetic member 1061 and the second magnetic member 1062 is upward, and the direction of the power provided by the first power assisting device 107 is downward, so as to counteract the repulsive force between the first magnetic member 1061 and the second magnetic member 1062, and provide power for sliding the first body 101. When the first body 101 is slid upward, the direction of the repulsive force between the first magnetic member 1061 and the second magnetic member 1062 is downward, and the direction of the power provided by the first power assist device 107 is upward.

According to the sliding mobile terminal provided by the embodiment of the present disclosure, the magnetic assembly 106 is disposed between the first sliding member 104 and the second sliding member 105, one end of the first sliding member 104 is connected to the back surface of the first body 101, the other end of the first sliding member 104 is connected to the magnetic assembly 106, one end of the second sliding member 105 is connected to the front surface of the second body 103, the other end of the second sliding member 105 is connected to the magnetic assembly 106, the first power assisting device 107 is disposed between the first body 101 and the second body 103, the first power assisting device 107 is connected to the first sliding member 104 or the second sliding member 105, and the first power assisting device 107 is configured to provide power for the first sliding member 104 or the second sliding member 105. The sliding mobile terminal is provided with a first power assisting device 107 between the first body 101 and the second body 103, and the power provided by the first power assisting device 107 for the first sliding part 104 or the second sliding part 105 counteracts the interaction force generated by the magnetic assembly 106, so that the power of the user during sliding is increased, and the sliding hand feeling of the user is improved.

In one possible implementation, referring to fig. 3, the first power assisting device 107 comprises: a booster motor 1071 and a booster rod 1072.

One end of the assist lever 1072 is connected to one end of the assist motor 1071.

The other end of the assist lever 1072 is connected to the first slide member 104, and the other end of the assist motor 1071 is connected to the second slide member 105; the other end of the assist lever 1072 is connected to the first slide member 104, and the other end of the assist motor 1071 is connected to the second body 103; the other end of assist lever 1072 is connected to second slide member 105, and the other end of assist motor 1071 is connected to first slide member 104; alternatively, the other end of assist lever 1072 is connected to second slide member 105, and the other end of assist motor 1071 is connected to first body 101.

For the sake of convenience of distinction, the assist motor 1071 is referred to as a first assist motor 1071, and the assist lever 1072 is referred to as a first assist lever 1072.

The first boosting lever 1072 is provided at a bottom end, a middle position, or a top end of one side of the first boosting motor 1071. For example, when the first boosting lever 1072 is coupled to the first slide member 104, it may be provided at a tip or an intermediate position on one side of the first boosting motor 1071; when the first boosting lever 1072 is coupled to the second slide member 105, it may be disposed at a bottom end of one side of the first boosting motor 1071.

First assist lever 1072 is used to push first slide member 104 or second slide member 105, and the assist direction of first assist lever 1072 coincides with the sliding direction of first slide member 104 or second slide member 105. For example, when the first body 101 is slid downward, the first slide member 104 may be slid downward or the second slide member 105 may be slid upward. When the first slide member 104 is slid downward, the assist direction of the first assist lever 1072 coincides with the sliding direction of the first slide member 104, both downward; when the second slide member 105 is slid upward, the assist direction of the first assist lever 1072 coincides with the sliding direction of the second slide member 105, both being upward.

The shape of the first force lever 1072 may be set and changed as necessary. In the embodiment of the present disclosure, the shape of the first assist lever 1072 is not particularly limited. For example, the first boosting rod 1072 may be cylindrical or square in shape.

The length of the first force lever 1072 may be set and changed as needed. In the disclosed embodiment, the length of the first force lever 1072 is not particularly limited. For example, first assist lever 1072 may have a length of 0.5 cm, 1 cm, or 2 cm.

First assist motor 1071 is used to power first slide member 104 or second slide member 105. The process type of the first force-aid motor 1071 may be set and changed as needed, and in the embodiment of the present disclosure, the process type of the first force-aid motor 1071 is not particularly limited. For example, the process type of the first assist motor 1071 may be a wire type, a leaf spring contact type, or a patch type. The shape of the first assist motor 1071 may be set and modified as needed, and in the embodiment of the present disclosure, the shape of the first assist motor 1071 is not particularly limited. For example, the first assist motor 1071 may be cylindrical or flat button in shape. The size of the first assist motor 1071 may be set and changed as needed, and in the embodiment of the present disclosure, the size of the first assist motor 1071 is not particularly limited. For example, when first assist motor 1071 is flat button shaped, first assist motor 1071 can be sized 6 mm in diameter and 2 mm thick; diameter 7 mm, thickness 2.2 mm; diameter 8 mm and thickness 2.5 mm. The type, power, etc. of the first assist motor 1071 may be set and changed as needed, and in the embodiment of the present disclosure, the type, power, etc. of the first assist motor 1071 are not particularly limited.

In one possible implementation manner, the sliding mobile terminal further includes: a boost switch 108.

The power switch 108 is disposed between the first body 101 and the second body 103, and the power switch 108 is connected to the first power device 107; the boost switch 108 is used to control the first boost device 107 to start or stop.

The power switch 108 may be provided on the rear surface of the first body 101, the front surface of the second body 103, on the first slide member 104, or on the second slide member 105. When the first body 101 or the second body 103 slides away, the power switch 108 detects that relative displacement is generated between the first body 101 and the second body 103 or pressure between the first body 101 and the second body 103 is changed, the power switch 108 sends a first starting instruction to the first power assisting device 107, and the first power assisting device 107 is started after the first power assisting device 107 receives the first starting instruction. When the first assisting lever 1072 of the first assisting device 107 pushes the first sliding member 104 or the second sliding member 105 to slide by a first preset distance, the assisting switch 108 sends a first stop instruction to the first assisting device 107, and after the first assisting device 107 receives the first stop instruction, the first assisting lever 1072 of the first assisting device 107 stops pushing the first sliding member 104 or the second sliding member 105, and at this time, the first body 101 or the second body 103 is in a sliding open state. When the first body 101 or the second body 103 is closed, the power switch 108 detects that a relative displacement is generated between the first body 101 and the second body 103 or a pressure between the first body 101 and the second body 103 is changed, the power switch 108 sends a second starting instruction to the first power assisting device 107, and the first power assisting device 107 is started after the first power assisting device 107 receives the second starting instruction. When the first assisting lever 1072 of the first assisting device 107 pushes the first sliding member 104 or the second sliding member 105 to slide by a first preset distance, the assisting switch 108 sends a second stop instruction to the first assisting device 107, and after the first assisting device 107 receives the second stop instruction, the first assisting lever 1072 of the first assisting device 107 stops pushing the first sliding member 104 or the second sliding member 105, and at this time, the first body 101 or the second body 103 is in a closed state.

The first preset distance is a relative sliding distance between the first body 101 and the second body 103. For example, when the first body 101 is slid, the first preset distance is a distance between when the first body 101 is in the closed state and in the slide-open state; when the second body 103 is slid, the first preset distance is a distance between when the second body 103 is in a closed state and in a slid-open state. The size of the first preset distance may need to be set and changed. In the embodiments of the present disclosure, the first preset distance is not particularly limited. For example, the first predetermined distance may be 1 cm, 1.5 cm, or 2 cm.

In one possible implementation, the boost switch 108 may be a hall switch or a pressure sensor. When the power assisting switch 108 is a hall switch, the hall switch is used for sensing the magnetic field intensity between the first magnetic member 1061 and the second magnetic member 1062, when the first body 101 and the second body 103 generate relative displacement, the magnetic field intensity between the first magnetic member 1061 and the second magnetic member 1062 changes, and when the magnetic field intensity changes, the hall switch controls the first power assisting device 107 to start or stop. The hall switch may be provided on the rear surface of the first body 101, the front surface of the second body 103, the first slide member 104, or the second slide member 105. When the hall switch is disposed on the back surface of the first body 101 or the front surface of the second body 103, it may be disposed at any position on the back surface of the first body 101 or any position on the front surface of the second body 103. When the hall switch is provided on the first slide member 104 or the second slide member 105, it may be provided at any position on the first slide member 104 or any position on the second slide member 105. In the embodiments of the present disclosure, the position where the hall switch is provided is not particularly limited.

It should be noted that the hall switch has the characteristics of no contact, low power consumption, long service life, high response frequency, wide application range, and the like, so that when the power switch 108 is a hall switch, the response sensitivity and the response life of the sliding mobile terminal can be enhanced.

When the boost switch 108 is a hall switch, for the sake of convenience of distinction, the first start command is referred to as a third start command, the first stop command is referred to as a third stop command, the second start command is referred to as a fourth start command, and the second stop command is referred to as a fourth stop command.

When the first body 101 or the second body 103 slides away, relative displacement is generated between the first body 101 and the second body 103, and when the hall switch senses the magnetic field intensity change generated by the first magnetic member 1061 and the second magnetic member 1062 caused by the relative displacement, the hall switch sends a third starting instruction to the first power assisting device 107, wherein the third starting instruction is used for controlling the starting of the first power assisting device 107; after receiving the third activation command, the first power assist device 107 activates the first power assist device 107. When the first assisting lever 1072 of the first assisting device 107 pushes the first sliding member 104 or the second sliding member 105 to slide by a first preset distance, the hall switch sends a third stop instruction to the first assisting device 107, and after the first assisting device 107 receives the third stop instruction, the first assisting lever 1072 of the first assisting device 107 stops pushing the first sliding member 104 or the second sliding member 105, and at this time, the first body 101 or the second body 103 is in a slide-open state.

When the first body 101 or the second body 103 is closed, relative displacement is generated between the first body 101 and the second body 103, and when the hall switch senses the magnetic field intensity change generated by the first magnetic member 1061 and the second magnetic member 1062 caused by the relative displacement, the hall switch sends a fourth starting instruction to the first power assisting device 107, wherein the fourth starting instruction is used for controlling the starting of the first power assisting device 107; after receiving the fourth activation command, the first power assist device 107 activates the first power assist device 107. When the first assisting lever 1072 of the first assisting device 107 pushes the first sliding member 104 or the second sliding member 105 to slide to reach the first preset distance, the hall switch sends a fourth stop instruction to the first assisting device 107, and after the first assisting device 107 receives the fourth stop instruction, the first assisting lever 1072 of the first assisting device 107 stops pushing the first sliding member 104 or the second sliding member 105, and at this time, the first body 101 and the second body 103 are in a closed state.

When the power assisting switch 108 is a pressure sensor, the pressure sensor is used for sensing the pressure between the first body 101 and the second body 103, and when the pressure changes, the pressure sensor controls the first power assisting device 107 to start or stop. The pressure sensor may be provided on the back surface of the first body 101, on the first slide member 104, or on the second slide member 105. When the pressure sensor is disposed on the back surface of the first body 101, a first designated area may be disposed on the back surface of the first body 101, the first designated area corresponding to the second designated area up and down. The second designated area is a corresponding area located on the front side of the first body 101 and pressed by a finger when the user slides or closes the sliding mobile terminal. When the pressure sensor is provided on the first slide member 104 or the second slide member 105, it may be provided at any position on the first slide member or at any position on the second slide member.

When the assist switch 108 is a pressure sensor, for the sake of convenience of distinction, the first start command is referred to as a fifth start command, the first stop command is referred to as a fifth stop command, the second start command is referred to as a sixth start command, and the second stop command is referred to as a sixth stop command.

When the first body 101 or the second body 103 slides away, the pressure sensor senses that the pressure between the first body 101 and the second body 103 changes, and the pressure sensor sends a fifth starting instruction to the first power assisting device 107, wherein the fifth starting instruction is used for controlling the starting of the first power assisting device 107; after receiving the fifth activation command, the first power assist device 107 activates the first power assist device 107. When the first assisting lever 1072 of the first assisting device 107 pushes the first sliding member 104 or the second sliding member 105 to slide by a first preset distance, the pressure sensor sends a fifth stop instruction to the first assisting device 107, and after the first assisting device 107 receives the fifth stop instruction, the first assisting lever 1072 of the first assisting device 107 stops pushing the first sliding member 104 or the second sliding member 105, and at this time, the first body 101 or the second body 103 is in a slide-open state.

When the first body 101 or the second body 103 is closed, the pressure sensor senses that the pressure between the first body 101 and the second body 103 changes, the pressure sensor sends a sixth starting instruction to the first power assisting device 107, and the first power assisting device 107 is started after the first power assisting device 107 receives the sixth starting instruction. When the first assisting lever 1072 of the first assisting device 107 pushes the first sliding member 104 or the second sliding member 105 to slide by the first preset distance, the pressure sensor sends a sixth stop instruction to the first assisting device 107, and after the first assisting device 107 receives the sixth stop instruction, the first assisting lever 1072 of the first assisting device 107 stops pushing the first sliding member 104 or the second sliding member 105, and at this time, the first body 101 and the second body 103 are in a closed state.

To further save the user the force used when sliding open or closing the sliding mobile terminal, in one possible implementation, see fig. 4, the sliding mobile terminal further comprises: a second booster 109 for powering the first slide member 104 or the second slide member 105.

The second booster 109 is provided between the first body 101 and the second body 103, one end of the first slide member 104 or the second slide member 105 is connected to the second booster 109, and the other end of the first slide member 104 or the second slide member 105 is connected to the first booster 107.

When the sliding mobile terminal further comprises a second force aid 109, the second force aid 109 and the first force aid 107 may be the same or different. In the disclosed embodiment, the second power assist device 109 may be provided identical to the first power assist device 107. When the second booster 109 is the same as the first booster 107, the second booster 109 also includes: a second assist motor 1091 and a second assist lever 1092.

The second power assisting device 109 may be disposed at a bottom end or a top end between the first body 101 and the second body 103. When the sliding mobile terminal further includes the second assistor 109, the number of assistor switches 108 may be set and changed as needed. In the disclosed embodiment, the number of the power switches 108 is not particularly limited. For example, the number of boost switches 108 may be one or two. When the number of the assist switches 108 is one, the first assist apparatus 107 and the second assist apparatus 109 may share one assist switch 108. Accordingly, the boost switch 108 is also used to control the second boost device 109 to start or stop. When the number of the assist switches 108 is two, one assist switch 108 is used to control the first assist device 107 to start or stop, and the other assist switch 108 is used to control the second assist device 109 to start or stop.

When the first power assisting device 107 and the second power assisting device 109 share one power assisting switch 108, the power assisting switch 108 is further configured to detect that a relative displacement between the first body 101 and the second body 103 or a pressure change between the first body 101 and the second body 103 occurs when the first body 101 or the second body 103 slides away, the power assisting switch 108 sends a seventh starting instruction to the second power assisting device 109, and the second power assisting device 109 starts the second power assisting device 109 after receiving the seventh starting instruction. When the second power assisting lever 1092 of the second power assisting device 109 pushes the first sliding member 104 or the second sliding member 105 to slide to reach the second preset distance, the power assisting switch 108 further sends a seventh stop command to the second power assisting device 109, and after the second power assisting device 109 receives the seventh stop command, the power assisting lever 1092 of the second power assisting device 109 stops pushing the first sliding member 104 or the second sliding member 105, and at this time, the first body 101 or the second body 103 is in a sliding open state. When the first body 101 or the second body 103 is closed, the power switch 108 detects that a relative displacement is generated between the first body 101 and the second body 103 or a pressure between the first body 101 and the second body 103 is changed, the power switch 108 sends an eighth start instruction to the second power assisting device 109, and the second power assisting device 109 starts the second power assisting device 109 after receiving the eighth start instruction. When the assist lever 1092 of the second assisting apparatus 109 pushes the first sliding member 104 or the second sliding member 105 to slide to reach the second preset distance, the assist switch 108 further sends an eighth stop command to the second assisting apparatus 109, and after the second assisting apparatus 109 receives the eighth stop command, the assist lever 1092 of the second assisting apparatus 109 stops pushing the first sliding member 104 or the second sliding member 105, and at this time, the first body 101 and the second body 103 are in a closed state.

When the first booster 107 and the second booster 109 share one booster switch 108, the booster switch 108 may be a hall switch or a pressure sensor. In the disclosed embodiment, the type of the boost switch 108 is not particularly limited.

When the first booster 107 and the second booster 109 share one booster switch 108, and the booster switch 108 is a hall switch, the direction of boosting of the booster rod 1072 in the first booster 107 and the direction of boosting of the booster rod 1072 in the second booster 109 may be the same or opposite. When the assisting direction of assisting lever 1072 of first assisting device 107 is the same as the assisting direction of assisting lever 1072 of second assisting device 109 and first body 101 is slid downward, assisting lever 1072 of first assisting device 107 and assisting lever 1092 of second assisting device 109 may be both connected to first sliding member 104 or both connected to second sliding member 105. When the first body 101 slides downwards, the assisting rod 1072 of the first assisting device 107 and the assisting rod 1092 of the second assisting device 109 are both connected with the first sliding part 104, the hall switch senses the change of the magnetic field strength between the first magnetic element 1061 and the second magnetic element 1062, and sends a third starting instruction and a seventh starting instruction to the first assisting device 107 and the second assisting device 109, after the first assisting device 107 and the second assisting device 109 receive the third starting instruction and the seventh starting instruction, the first assisting device 107 and the second assisting device 109 are respectively started, and the assisting rod 1072 of the first assisting device 107 and the assisting rod 1092 of the second assisting device 109 push the first sliding part 104 to slide downwards for a second preset distance; when the second preset distance is reached, the hall switch sends a third stop command and a seventh stop command to the first power assisting device 107 and the second power assisting device 109, and after the first power assisting device 107 and the second power assisting device 109 receive the third stop command and the seventh stop command, the assisting rod 1072 of the first power assisting device 107 and the assisting rod 1092 of the second power assisting device 109 stop pushing the first sliding part 104. At this time, the first body 101 is in a slide-open state.

When the first body 101 is closed, the hall switch senses that the magnetic field intensity between the first magnetic member 1061 and the second magnetic member 1062 changes, and sends a fourth starting instruction and an eighth starting instruction to the first power assisting device 107 and the second power assisting device 109, respectively, after the first power assisting device 107 and the second power assisting device receive the fourth starting instruction and the eighth starting instruction, the first power assisting device 107 and the second power assisting device 109 are respectively started, and the power assisting rod 1072 of the first power assisting device 107 and the power assisting rod 1092 of the second power assisting device 109 both push the first sliding part 104 to slide upwards by a second preset distance; when the second preset distance is reached, the hall switch sends a fourth stop command and an eighth stop command to the first power assisting device 107 and the second power assisting device 109, and after the first power assisting device 107 and the second power assisting device 109 receive the fourth stop command and the eighth stop command, the assisting rod 1072 of the first power assisting device 107 and the assisting rod 1092 of the second power assisting device 109 both stop pushing the first sliding part 104. At this time, the first body 101 is in a closed state.

When the assisting direction of the assisting lever 1072 of the first assisting device 107 is the same as the assisting direction of the assisting lever 1072 of the second assisting device 109, the second preset distance is equal to the first preset distance in magnitude.

For the sake of convenience of distinction, when the first booster 107 and the second booster 109 share one booster switch 108, and the booster switch 108 is a pressure sensor, the fifth start command is referred to as a ninth start command, the fifth stop command is referred to as a ninth stop command, the sixth start command is referred to as a tenth start command, and the sixth stop command is referred to as a tenth stop command.

When the first assisting device 107 and the second assisting device 109 share one assisting switch 108, the assisting switch 108 is a pressure sensor, the direction of the power provided by the first assisting device 107 is opposite to the direction of the power provided by the second assisting device 109, and the first assisting device 107 can be connected with the first sliding part 104 and the second assisting device 109 is connected with the second sliding part 105 when the first body 101 is slid downwards; alternatively, the first booster 107 is connected to the second slide member 105, and the second booster 109 is connected to the first slide member 104. When the first body 101 slides downwards, the first power assisting device 107 is connected with the first sliding part 104, and the second power assisting device 109 is connected with the second sliding part 105, the pressure sensor senses the pressure change between the first body 101 and the second body 103, and sends a fifth starting instruction and a ninth starting instruction to the first power assisting device 107 and the second power assisting device 109 respectively, after receiving the fifth starting instruction and the ninth starting instruction, the first power assisting device 107 and the second power assisting device 109 respectively start the first power assisting device 107 and the second power assisting device 109, the power assisting rod 1072 of the first power assisting device 107 pushes the first sliding part 104 to slide downwards for a third preset distance, and the power assisting rod 1092 of the second power assisting device 109 pushes the second sliding part 105 to slide upwards for a fourth preset distance. When the third preset distance and the fourth preset distance are reached, the pressure sensor sends a fifth stop command and a ninth stop command to the first power assisting device 107 and the second power assisting device 109, respectively, and after the fifth stop command and the ninth stop command are received by the first power assisting device 107 and the second power assisting device 109, respectively, the assisting rod 1072 of the first power assisting device 107 stops pushing the first sliding part 104, and the assisting rod 1092 of the second power assisting device 109 stops pushing the second sliding part 105. At this time, the first body 101 is in a slide-open state.

When the first body 101 is closed, the pressure sensor senses that the pressure between the first body 101 and the second body 103 changes, and sends a sixth start instruction and a tenth start instruction to the first power assisting device 107 and the second power assisting device 109, respectively, after the first power assisting device 107 and the second power assisting device receive the sixth start instruction and the tenth start instruction, the first power assisting device 107 and the second power assisting device 109 are started, respectively, the power assisting rod 1072 of the first power assisting device 107 pushes the first sliding component 104 to slide upwards for a third preset distance, and the power assisting rod 1092 of the second power assisting device 109 pushes the second sliding component 105 to slide downwards for a fourth preset distance. After the third preset distance and the fourth preset distance are reached, the pressure sensor sends a sixth stop command and a tenth stop command to the first power assisting device 107, and after the first power assisting device 107 and the second power assisting device 109 receive the sixth stop command and the tenth stop command, respectively, the assisting rod 1072 of the first power assisting device 107 stops pushing the first sliding part 104, and the assisting rod 1092 of the second power assisting device 109 stops pushing the second sliding part 105. At this time, the first body 101 is in a closed state.

When the number of the power assist switches 108 is two, the two power assist switches 108 are referred to as a first power assist switch 1010 and a second power assist switch 1011, respectively, for convenience of distinction. The first assist switch 1010 is used for controlling the first assist device 107 to start or stop, and the second assist switch 1011 is used for controlling the second assist device 109 to start or stop.

When the first assist switch 1010 controls the first assist device 107 and the second assist switch 1011 controls the second assist device 109, the assist direction of the assist lever 1072 in the first assist device 107 and the assist direction of the assist lever 1072 in the second assist device 109 may be the same or opposite.

When the number of the power switches 108 is two, the first power switch 1010 controls the first power device 107, and the second power switch 1011 controls the second power device 109, when the first body 101 or the second body 103 slides away, the second power switch 1011 detects that a relative displacement is generated between the first body 101 and the second body 103 or a pressure between the first body 101 and the second body 103 is changed, the second power switch 1011 sends an eleventh start instruction to the second power device 109, and the second power device 109 starts the second power device 109 after receiving the eleventh start instruction. When the assisting rod 1092 of the second assisting device 109 pushes the first sliding member 104 or the second sliding member 105 to slide by a fifth preset distance, the second assisting switch 1011 further sends an eleventh stop command to the second assisting device 109, and after the second assisting device 109 receives the eleventh stop command, the assisting rod 1092 of the second assisting device 109 stops pushing the first sliding member 104 or the second sliding member 105, and at this time, the first body 101 or the second body 103 is in a sliding-open state. When the first body 101 or the second body 103 is closed, the second power switch 1011 detects that a relative displacement is generated between the first body 101 and the second body 103 or a pressure change occurs between the first body 101 and the second body 103, the second power switch 1011 sends a twelfth starting instruction to the second power assisting device 109, and the second power assisting device 109 starts the second power assisting device 109 after receiving the twelfth starting instruction. When the assisting rod 1092 of the second assisting device 109 pushes the first sliding member 104 or the second sliding member 105 to slide to reach the fifth preset distance, the assisting switch further sends a twelfth stop command to the second assisting device 109, and after the second assisting device 109 receives the twelfth stop command, the assisting rod 1092 of the second assisting device 109 stops pushing the first sliding member 104 or the second sliding member 105, and at this time, the first body 101 and the second body 103 are in a closed state.

In one possible implementation, when the number of the power switches 108 is two, there are a first power switch 1010 and a second power switch 1011, respectively. The first power switch 1010 may be a hall switch or a pressure sensor, and the second power switch 1011 may also be a hall switch or a pressure sensor. In the disclosed embodiment, the first boost switch 1010 and the second boost switch 1011 are not particularly limited. For example, the first boost switch 1010 is a hall switch, and the second boost switch 1011 is a pressure sensor; the first power switch 1010 and the second power switch 1011 are both hall switches; the first power switch 1010 is a pressure sensor, and the second power switch 1011 is a hall switch; alternatively, the first power switch 1010 and the second power switch 1011 are both pressure sensors.

When the number of the power-assisted switches is two, the first power-assisted switch 1010 and the second power-assisted switch 1011 are respectively a hall switch and a pressure sensor, the power-assisted direction of the power-assisted rod 1072 in the first power-assisted device 107 is opposite to the power-assisted direction of the power-assisted rod 1072 in the second power-assisted device 109, and the first body 101 slides downwards, the first power-assisted device 107 can be connected with the first sliding part 104, and the second power-assisted device 109 is connected with the second sliding part 105; alternatively, the first booster 107 is connected to the second slide member 105, and the second booster 109 is connected to the first slide member 104. The hall switch is used for controlling the first booster 107 to start or stop, and the pressure sensor is used for controlling the second booster 109 to start or stop. When the first body 101 is slid downward, the first power assist device 107 is connected to the first slide member 104, the second power assist device 109 is connected to the second slide member 105, the hall switch senses the change of the magnetic field intensity between the first magnetic element 1061 and the second magnetic element 1062, and sends a third starting instruction to the first power assisting device 107, the pressure sensor senses the change of the pressure between the first body 101 and the second body 103, and sends an eleventh starting instruction to the second power assisting device 109, the first power assisting device 107 receives the third starting instruction, and after the second power assisting device 109 receives the eleventh starting instruction, when the first assisting device 107 and the second assisting device 109 are respectively activated, the assisting rod 1072 of the first assisting device 107 pushes the first sliding member 104 to slide downward by a third preset distance, and the assisting rod 1092 of the second assisting device 109 pushes the second sliding member 105 to slide upward by a fourth preset distance. When the third preset distance and the fourth preset distance are reached respectively, the hall switch sends a third stop instruction to the first power assisting device 107, the pressure sensor sends an eleventh stop instruction to the second power assisting device 109, the first power assisting device 107 receives the third stop instruction, the second power assisting device 109 receives the eleventh stop instruction, the assisting rod 1072 of the first power assisting device 107 stops pushing the first sliding part 104, and the assisting rod 1092 of the second power assisting device 109 stops pushing the second sliding part 105. At this time, the first body 101 is in a slide-open state.

When the first body 101 is closed, the hall switch senses that the magnetic field intensity between the first magnetic member 1061 and the second magnetic member 1062 changes, a fourth starting instruction is sent to the first power assisting device 107, the pressure sensor senses that the pressure between the first body 101 and the second body 103 changes, a twelfth starting instruction is sent to the second power assisting device 109, the first power assisting device 107 receives the fourth starting instruction, the second power assisting device 109 respectively starts the first power assisting device 107 and the second power assisting device 109 after receiving the twelfth starting instruction, the power assisting rod 1072 of the first power assisting device 107 pushes the first sliding member 104 to slide upwards for a third preset distance, and the power assisting rod 1092 of the second power assisting device 109 pushes the second sliding member 105 to slide downwards for a fourth preset distance. When the third preset distance and the fourth preset distance are reached, the hall switch sends a fourth stop command to the first power assisting device 107, the pressure sensor sends a twelfth stop command to the second power assisting device 109, the first power assisting device 107 receives the fourth stop command, and the second power assisting device 109 receives the twelfth stop command, the power assisting rod 1072 of the first power assisting device 107 stops pushing the first sliding part 104, and the power assisting rod 1092 of the second power assisting device 109 stops pushing the second sliding part 105. At this time, the first body 101 is in a closed state.

When the direction of the power provided by the second power assisting device 109 is the same as the direction of the power provided by the first power assisting device 107, the magnitude of the fifth preset distance is equal to the magnitude of the first preset distance. When the assisting direction of the assisting lever 1072 of the second assisting device 109 is opposite to the assisting direction of the assisting lever 1072 of the first assisting device 107, the magnitude of the fifth preset distance is equal to the magnitude of the fourth preset distance.

When the assisting direction of the assisting lever 1072 of the second assisting device 109 and the assisting direction of the assisting lever 1072 of the first assisting device 107 are opposite, the value of the first preset distance is equal to the sum of the third preset distance and the fourth preset distance. The third preset distance and the fourth preset distance can be set and changed as required. In the embodiments of the present disclosure, the third preset distance and the fourth preset distance are not particularly limited.

In the sliding mobile terminal provided by the embodiment of the present disclosure, the magnetic assembly 106 is disposed between the first sliding member 104 and the second sliding member 105, one end of the first sliding member 104 is connected to the back surface of the first body 101, the other end of the first sliding member 104 is connected to the magnetic assembly 106, one end of the second sliding member 105 is connected to the front surface of the second body 103, the other end of the second sliding member 105 is connected to the magnetic assembly 106, the first power assisting device 107 is disposed between the first body 101 and the second body 103, and the first power assisting device 107 is connected to the first sliding member 104 or the second sliding member 105. The second booster 109 is also disposed between the first body 101 and the second body 103, one end of the first sliding member 104 or the second sliding member 105 is connected to the second booster 109, the other end of the first sliding member 104 or the second sliding member 105 is connected to the first booster 107, and both the first booster 107 and the second booster 109 are used for providing power for the first sliding member 104 or the second sliding member 105. The sliding mobile terminal is provided with a first power assisting device 107 and a second power assisting device 109 between the first body 101 and the second body 103, and the power provided by the first power assisting device 107 and the second power assisting device 109 for the first sliding part 104 or the second sliding part 105 counteracts the interaction force generated by the magnetic assembly 106, so that the power of a user during sliding is increased, and the sliding hand feeling of the user is improved.

The above description is only for the purpose of facilitating understanding of the technical solutions of the present disclosure by those skilled in the art, and is not intended to control the present disclosure. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present disclosure should be included in the protection scope of the present disclosure.

Claims

1. A sliding mobile terminal, characterized in that the sliding mobile terminal comprises:

2. The sliding mobile terminal of claim 1, wherein the magnetic assembly comprises: a first magnetic member and a second magnetic member;

3. The sliding mobile terminal according to claim 1, wherein said first power assist means comprises: a booster motor and a booster rod;

4. The sliding mobile terminal according to claim 1 or 3, wherein said sliding mobile terminal further comprises: a power-assisted switch;

5. The sliding mobile terminal of claim 4 wherein the power switch is a Hall switch;

6. The sliding mobile terminal according to claim 5, wherein the Hall switch is disposed on a back surface of the first body, a front surface of the second body, the first sliding member, or the second sliding member.

7. The sliding mobile terminal of claim 4 wherein the power switch is a pressure sensor;

8. The sliding mobile terminal according to claim 7 wherein said pressure sensor is disposed on a back surface of said first body, on said first sliding member or on said second sliding member.

9. The sliding mobile terminal according to claim 1, further comprising: a second booster for powering the first slide member or the second slide member;