KR20240015122A - Information output apparatus - Google Patents

Abstract

One embodiment of the present invention relates to an information output device including one or more information output units, wherein the information output unit includes a coil portion connected to a power source and arranged to allow current to flow, and a base portion formed to accommodate the coil portion. , an expression part formed and arranged to be sensed by the user and disposed in the base part, spaced apart from the coil part and adjacent to the coil part, and driven by a current flowing in the coil part to make an angular or rotational movement, thereby expressing the expression. Disclosed is an information output device including a driving unit configured to move the unit in a first direction toward the coil unit and in the opposite direction.

Description

Information output apparatus {Information output apparatus}

Embodiments of the present invention relate to information output devices.

Users can perceive information in various ways. For this purpose, various types of information output devices are used.

For example, visual information output devices using printed materials and auditory information output devices using sound are being used.

In particular, in modern times, as the amount of information increases and technology develops, information output devices including electronic technology are widely used, and display devices with multiple pixels are commonly used as visual information output devices.

However, in the case of such display devices, various circuits, etc. are built in, which reduces manufacturing feasibility and causes inconvenience in control.

Meanwhile, due to technological development and diversification of lifestyle habits, various types of information output are required.

For example, a variety of information output devices may be required depending on the situation of each user, and in particular, users with weakened specific senses, for example, weak or no visual ability, require information output through the sense of touch. When outputting information through the sense of touch, it is difficult to easily control and drive it stably, so there is a limit to improving user convenience through improvements in information output devices.

Embodiments of the present invention provide an information output device that has improved durability and improves user convenience.

One embodiment of the present invention relates to an information output device including one or more information output units, wherein the information output unit includes a coil portion connected to a power source and arranged to allow current to flow, and a base portion formed to accommodate the coil portion. , an expression part formed and arranged to be sensed by the user and disposed in the base part, spaced apart from the coil part and adjacent to the coil part, and driven by a current flowing in the coil part to make an angular or rotational movement, thereby expressing the expression. Disclosed is an information output device including a driving unit configured to move the unit in a first direction toward the coil unit and in the opposite direction.

In this embodiment, magnetic parts having areas with different polarities may be disposed in the driving part.

In this embodiment, it further includes a drive control unit disposed on at least one surface of the drive unit, and the drive unit can drive the expression unit by making angular or rotational movements around the drive control unit.

*

*In this embodiment, the driving unit includes a driving surface at least on an outer surface, transmits driving force to the expression unit through the driving surface, and the driving surface may include a curved surface.

In this embodiment, the base portion may further include a first accommodating portion that accommodates the coil portion and a second accommodating portion that accommodates the driving portion and is disposed adjacent to the first accommodating portion in the first direction.

In this embodiment, it may further include a boundary portion disposed between the first accommodating part and the second accommodating part to distinguish the first accommodating part from the second accommodating part.

In this embodiment, it may further include a support part disposed on the base part and supporting the driving part when the driving part moves.

In this embodiment, the driving unit includes a driving surface at least on an outer surface, transmits driving force to the expression unit through the driving surface, and the support part may be arranged to be spaced apart from the driving surface.

In this embodiment, the information output device includes a plurality of information output units, and the plurality of information output units may be arranged to be spaced apart from each other in one direction or another direction.

Other aspects, features and advantages in addition to those described above will become apparent from the following drawings, claims and detailed description of the invention.

The information output device according to this embodiment has improved durability and can improve user convenience.

1 is a perspective front view schematically showing an information output device according to an embodiment of the present invention.
FIGS. 2 and 3 are diagrams for explaining the operation of the information output device of FIG. 1.
Figure 4 is a perspective view schematically showing an information output device according to another embodiment of the present invention.
Figure 5 is a cross-sectional view taken along line V-V of Figure 4.
FIG. 6 is a cross-sectional view taken along line VI-VI of FIG. 4.
Figure 7 is a schematic perspective view for explaining the driving unit of Figure 4.
Figure 8 is a front view seen from one direction of Figure 7.
FIG. 9 is a partial perspective view of one area of the base portion of FIG. 4 viewed from one direction.
FIGS. 10A and 10B are diagrams illustrating a support portion of the information output device of FIG. 4 and a modified example thereof.
FIGS. 11A and 11B are diagrams illustrating a representation unit of the information output device of FIG. 4 and a modified example thereof.
FIG. 12 is a diagram showing a modified example of the base portion of the information output device of FIG. 4.
Figure 13 is a perspective view schematically showing an information output device according to another embodiment of the present invention.

Since the present invention can be modified in various ways and can have various embodiments, specific embodiments will be illustrated in the drawings and described in detail in the detailed description. The effects and features of the present invention and methods for achieving them will become clear by referring to the embodiments described in detail below along with the drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various forms.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. When describing with reference to the drawings, identical or corresponding components will be assigned the same reference numerals and redundant description thereof will be omitted. .

In the following embodiments, terms such as first and second are used not in a limiting sense but for the purpose of distinguishing one component from another component.

In the following examples, singular terms include plural terms unless the context clearly dictates otherwise.

In the following embodiments, terms such as include or have mean that the features or components described in the specification exist, and do not exclude in advance the possibility of adding one or more other features or components.

In the drawings, the sizes of components may be exaggerated or reduced for convenience of explanation. For example, the size and thickness of each component shown in the drawings are arbitrarily shown for convenience of explanation, so the present invention is not necessarily limited to what is shown.

In the following embodiments, the x-axis, y-axis, and z-axis are not limited to the three axes in the Cartesian coordinate system, but can be interpreted in a broad sense including these. For example, the x-axis, y-axis, and z-axis may be orthogonal to each other, but may also refer to different directions that are not orthogonal to each other.

In cases where an embodiment can be implemented differently, a specific process sequence may be performed differently from the described sequence. For example, two processes described in succession may be performed substantially at the same time, or may be performed in an order opposite to that in which they are described.

FIG. 1 is a perspective front view schematically showing an information output device according to an embodiment of the present invention, and FIGS. 2 and 3 are diagrams for explaining the operation of the information output device of FIG. 1.

1 to 3, the information output device 100 of this embodiment includes at least one information output unit, and FIG. 1 shows one information output unit. That is, the information output device 100 of FIG. 1 may be one information output unit.

Although one information output unit is shown in FIG. 1, the information output device 100 may include two, three or more information output units as an optional embodiment.

That is, the information output device 100 may include a varying number of information output units depending on the purpose, characteristics of the applied product, and user characteristics.

For convenience of explanation, an information output device including one information output unit as shown in FIG. 1 will be described.

The information output device 100 may include a coil unit 120, a base unit 130, a driver 140, and a representation unit 110.

The expression unit 110 can move according to the movement of the driving unit 140, which will be described later, and can move at least upward and downward based on the longitudinal direction of the expression unit 110. For example, it can move in one direction toward the coil unit 120 and in the opposite direction.

Through this, the expression unit 110 can move to protrude in one direction, and the user can sense the movement of the expression unit 110 tactilely or visually.

The expression unit 110 may include an expression surface 111 and a support surface 112.

The support surface 112 is a surface facing the driving unit 140 among the areas of the expression unit 110, forms the lower area of the expression unit 110, and can be in contact with the driving unit 140, and the driving unit 140 is the support surface 112. ) It is possible to transmit force to the expression unit 110 through. For example, while the driving surface 140a of the driving unit 140 is in contact with the support surface 112, the support surface 112 can be moved in the first direction, that is, the Z-axis direction with respect to FIG. 1.

The expression surface 111 may include an area recognized by the user as the outermost area of the expression unit 110, for example, the area furthest away from the coil unit 120.

For example, the user may recognize the entire area of the expression unit 110, but may also recognize only the expression surface 111. For example, the user can sense the movement of the expression unit 110 through contact with the expression surface 111, and the user can easily detect the movement of the expression part 110 through visual detection of the expression surface 111. You can also sense it.

As an optional embodiment, the expression surface 111 may include a curved surface.

The expression unit 110 may have various shapes and may include a column-shaped region, for example, a region similar to a cylinder.

Additionally, as an optional embodiment, the protruding area of the expression unit 110 may have a curved surface, and the corners may have a curved surface.

The expression unit 110 may include various materials and may be made of an insulating material that is lightweight and durable. For example, it may contain a resin-based organic material. As another example, it may include inorganic materials such as ceramic materials.

Additionally, as another optional embodiment, the expression unit 110 may be formed of a material such as metal or glass.

The coil unit 120 may be configured to be connected to an external power source (not shown). When current flows through the coil unit 120, a magnetic field may be formed around the coil unit 120.

The coil unit 120 may have various forms. For example, the coil unit 120 may have a form in which multiple circuits of wire are wound, and the number of turns may be controlled in various ways.

The driving unit 140 can move through the magnetic field generated by the current flowing in the coil unit 120, and the driving force for the movement of the expression unit 110 can be provided through this movement of the driving unit 140.

As an optional embodiment, the support part 170 may be further disposed, and at least one area of the support part 170 may be arranged to be adjacent to or support the coil part 120.

For example, the support part 170 includes a long extending area and may be arranged to penetrate the coil part 120. As a specific example, a plurality of coils of the coil part 120 are wound around the support part 170. It can have any form.

As an optional embodiment, one end of the support unit 170 may be extended to support the drive unit 140, which will be described later, and the movement of the drive unit 140 may proceed while being supported on one end of the support unit 170.

As an optional embodiment, the support portion 170 may be formed to correspond to the penetration portion 130H of the base portion 130.

As an optional embodiment, the support portion 170 may include a magnetic material, and as a specific example, the extension member 171 may contain a magnetic material. Through this, the size of the magnetic field can be increased when the magnetic field is generated through the coil unit 120, and the power consumption of the information output device 100 can be reduced by efficiently generating the magnetic field.

The base portion 130 may be formed to accommodate the coil portion 120. For example, the base portion 130 may include a first accommodating portion 131 and a second accommodating portion 132.

The first accommodating part 131 and the second accommodating part 132 may be arranged adjacent to each other or may be arranged not to overlap each other.

As an optional embodiment, the first accommodating part 131 and the second accommodating part 132 may be spaced apart.

As another optional embodiment, the first accommodating part 131 and the second accommodating part 132 may be connected through a through hole.

The coil portion 120 may be disposed in the first receiving portion 131. As an optional embodiment, the above-described support part 170 may be placed in the first receiving part 131, and one area of the support part 170 may be extended and placed in the second receiving part 132 through a through hole. .

Although not shown, as an optional embodiment, a driving groove (not shown) may be formed in the second receiving portion 132 of the base portion 130. For example, driving grooves (not shown) may be formed on both sides of the inner surface of the second receiving portion 132 of the base portion 130 facing each other, and as an optional embodiment, may be formed in one direction, for example, in the coil portion ( It may have a shape extending in a direction away from 120).

The base portion 130 may have an elongated shape to accommodate the coil portion 120 and the driving portion 140, and may be formed to entirely surround both the coil portion 120 and the driving portion 140.

As an optional embodiment, the base portion 130 may include a boundary portion 133 between the first accommodating portion 131 and the second accommodating portion 132.

The first accommodating part 131 and the second accommodating part 132 may be separated through the boundary portion 133.

As an optional embodiment, a through hole may be formed in the boundary portion 133 so that one area of the support portion 170 extends and passes through it.

Additionally, the base portion 130 includes an inlet portion 130a, and the inlet portion 130a may be connected to the second receiving portion 132. Through the entrance portion 130a, the expression portion 110 can move so that the length protruding out of the base portion 130 changes.

The driving unit 140 may be disposed on the base unit 130. The driving unit 140 may be disposed in the second accommodating portion 132 and may be spaced apart from the coil portion 120 disposed in the first accommodating portion 131.

The driving unit 140 is disposed adjacent to the coil unit 120 and is driven by a current flowing through the coil unit 120 to perform angular or rotational movement. Through the driving unit 140, the expression unit 110 can move up and down, for example, in one direction toward the coil unit and in the opposite direction.

As an optional embodiment, a magnetic force unit 150 may be disposed in the driving unit 140, for example, in an inner space. For example, magnetic portion 150 may contain a magnetic material, for example, a permanent magnet.

The magnetic portion 150 may have a first region (for example, N-pole or S-pole) and a second region (for example, S-pole or N-pole) of different polarities, and the first region (for example, N-pole or N-pole) may have different polarities. The region and the second region may be arranged in a direction from the coil unit 120 toward the expression unit 110 at a point during rotation of the driving unit 140, for example, in the Z-axis direction.

For example, based on FIG. 1, the first and second regions of the magnetic force unit 150 of different polarities may be arranged in a direction from the coil unit 120 toward the expression unit 110, for example, in the Z-axis direction. You can.

The driving part 140 includes a driving surface 140a on at least an outer surface, and the driving surface 140a is formed to support the expression part 110 and can provide a driving force for the up and down movement of the expression part 110. .

As an optional embodiment, the driving surface 140a of the driving unit 140 may include a curved outer surface. As a more specific example, the driving surface 140a of the driving unit 140 may include a boundary line similar to a circle.

The driving unit 140 may include a driving control unit 149.

The driving position of the driving unit 140 can be controlled through the driving control unit 149. For example, when the drive unit 140 moves by the coil unit 120, it may make angular or rotational movements centered on the drive control unit 149.

As an optional embodiment, the central axis of the drive unit 140 and the drive control unit 149 may not coincide and may be eccentric.

Additionally, as an optional embodiment, the magnetic force unit 150 may not coincide with the central axis of the drive unit 140, but may be arranged to overlap, for example, an area of the drive control unit 149.

Through this, torque force for the driving unit 140 can be easily generated, and the driving unit 240 can perform angular or rotational movement to efficiently move the expression unit 110 and provide precise information output device 100. Expression can be improved. Additionally, power consumption of the information output device 100 can be reduced.

Although not shown, the driving unit 140 may include a first driving member (not shown) and a second driving member (not shown), and may include a separation space (not shown) therebetween.

The outer surfaces of the first driving member (not shown) and the second driving member (not shown) include a driving surface 140a on at least one surface to support the expression unit 110 when the driving unit 140 moves. 110) can provide driving force. For example, the outer boundary line (e.g., circle) of the driving part 140 including the driving surface 140a shown in FIG. 1 may be the boundary line of the first driving member (not shown) or the second driving member (not shown). You can.

The outer surfaces of the optional first driving member (not shown) and the second driving member (not shown) may include a curved surface, for example, the driving surface 140a may include a curved surface.

all. For example, the first driving member (not shown) and the second driving member (not shown) may have a shape similar to a rotating body, or each may have a shape similar to a disk.

Through this, a natural driving force is provided to the support surface 112 of the expression unit 110 during rotation or angular movement of the first driving member (not shown) and the second driving member (not shown), so that the expression unit 110 is continuous and Natural exercise can be carried out efficiently.

The drive control unit 149 may be disposed on at least one side of the drive unit 140, for example, on both sides.

As an optional embodiment, the drive control unit 149 may protrude in a protruding form, that is, in a direction away from the side of the drive unit 140 (direction protruding in the drawing with respect to FIG. 1), and as an optional embodiment, this drive control unit ( The protruding shape of 149) may correspond to a driving groove (not shown) when the base portion 130 includes a driving groove (not shown).

For example, the drive unit 140 can move due to the magnetic field generated by the coil unit 120, and as a specific example, it can move up and down due to the repulsive force and attractive force on the magnetic force unit 150 within the drive unit 140. At this time, the drive unit 140 may move up and down while rotating around the drive control unit 149.

As an optional embodiment, the drive control unit 149 of the drive unit 140 is disposed in one area of the base unit 130, for example, in a drive groove (not shown) of the second accommodation unit 132. You can exercise.

A first movement area 145 and a second movement area 148 may be disposed in the space between the first driving member (not shown) and the second driving member (not shown).

The first exercise area 145 and the second exercise area 148 may be areas that serve as references for the lowest and highest points, respectively, when the driving unit 140 moves.

As an optional embodiment, a connection area 147 may be disposed between the first exercise area 145 and the second exercise area 148, and the connection area 147 may include a curved surface.

For example, as shown in Figure 1, when the first exercise area 145 is placed at the lowest point, that is, the area closest to the coil unit 120, the driving unit 120 is placed at the lowest point and the expression unit 110 is also placed at the lowest point accordingly. This may be in a placed state, specifically when the height at which the expression unit 110 protrudes from the base unit 130 is at its smallest. At this time, the first exercise area 145 may be supported by the upper end of the support part 170.

Then, as shown in FIG. 2, when a current is applied to the coil unit 120 and a magnetic field is formed, the drive unit 140 can move. For example, if a repulsive force acts on the magnetic force unit 150 disposed on the drive unit 140, The connection area 147 may be supported by the upper end of the support part 170 while one end of the magnetic part 150 (the polarity side where the repulsive force acts) is arranged away from the direction of the magnetic field. Referring to FIG. 2, the driving unit 120 rises, that is, the top surface of the driving unit 120 rises, and accordingly, the expression unit 110 also rises slightly. Referring to FIG. 2, it can rise as high as H1.

As an optional embodiment, the drive control unit 140 rotates around the drive control unit 149, so the drive control unit 149 can maintain its position.

Then, as shown in FIG. 3, when a current is applied to the coil unit 120 of FIG. 2 and a magnetic field is maintained, the drive unit 140 can continuously move, for example, the magnetic force disposed on the drive unit 140. One end of the magnetic portion 150, which exerts an attractive force according to the magnetic field generated in the region 150, is disposed close in the direction toward the coil portion 120, and the second movement region 148 is formed by the upper end of the support portion 170. It can be supported. Referring to FIG. 3, the driving unit 120 rises, that is, the top surface of the driving unit 120 rises, and accordingly, the expression unit 110 may also rise, and the state of FIG. 3 may be the highest point of the expression unit 110. there is.

As an optional embodiment, the drive control unit 140 rotates around the drive control unit 149, so the drive control unit 149 can maintain its position.

In alternative embodiments, the movement from the state of Figure 1 to the state of Figure 3 may be continuous. The state in FIG. 2 is for explaining a process. When the state in FIG. 1 changes to the state in FIG. 2, the driving unit 140 and the expression unit 110 continue to move without stopping in the state in FIG. 2. It can change to state 3.

For example, Figures 1 and 3 show a state in which the expression unit 110 can maintain a stationary state, and Figure 2 may show a state in which the expression unit 110 is in motion.

As an optional embodiment, the sequential exercise process of FIGS. 1 to 3 may also be applied to embodiments described later.

When the driving unit 140 rotates, the support unit 170 may support at least one area of the connection area 147 while supporting the first movement area 145 and before supporting the second movement area 148. Through this, the driving unit 140 moves naturally, and the resulting movement of the expression unit 110 can be precisely controlled.

The distance between the driving surface 140a and the first exercise area 145 may be different from the distance between the driving surface 140a and the second exercise area 148. For example, the distance between the driving surface 140a and the first exercise area 145 may be greater than the distance between the driving surface 140a and the second exercise area 148.

As an optional embodiment, the distance between the central axis of the driving unit 140 and the first movement area 145 may be smaller than the distance between the second movement area 148 and the central axis of the driving unit 140.

As an optional embodiment, the distance from the drive control 149 to the first exercise area 145 may be the same or similar to the distance from the drive control 149 to the second exercise area 148, and as a further optional embodiment, the The distance from the control unit 149 to the connection area 147 may also be the same or similar.

For example, the connection area 147 may correspond to at least one area of the circumference having a radius around the center point of the drive control unit 149, and the first movement area 145 and the second movement each correspond to the diameter. In areas facing each other, each may have the form of a flat surface extending parallel to each other.

Through this, when the drive unit 140 rotates around the drive control unit 149 and the support unit 170 supports the first movement area 145, the second movement area 148, and the connection area 147, the drive control unit ( 149) may remain the same or similar.

In addition, when supported by the support part 170, the connection area 147 supported by the support part 170 includes a curved surface or a surface close to an arc, so that the smooth and smooth movement of the driving part 140 can be performed efficiently. .

Although not shown, the second accommodation part 132 of the base unit 130 may include a groove that is at least larger than the drive control unit 149 to accommodate the drive control unit 149.

The above description refers to a first movement area in an area including the driving surface 140a of the driving unit 140, for example, in a space spaced apart between the first driving member (not shown) and the second driving member (not shown). (145), the case where the second exercise area 148 and the connection area 147 are arranged is explained. Additionally, this also applies to the embodiments described later.

As another optional embodiment, a first movement area ( 145), a second exercise area 148, and a connection area 147 may be disposed.

In addition, as another optional embodiment, there is a region including the driving surface 140a of the driving unit 140, for example, a first driving member (not shown) or a second driving member (not shown), and a first driving member (not shown) is present on both sides. The exercise area 145, the second exercise area 148, and the connection area 147 may be disposed, and accordingly, the drive control unit 149 may be configured to operate the first exercise area 145, the second exercise area 148, and the connection area. It may be placed in an area forming area 147.

Additionally, in these various alternative embodiments, the area including the driving surface 140a, for example, a first driving member (not shown) or a first driving member (not shown) on the outer surface of the shape having a smaller size than the second driving member (not shown). The structure having the exercise area 145, the second exercise area 148, and the connection area 147 may include various modified structures. Additionally, these various embodiments are also possible in embodiments described later.

The information output device of this embodiment may include one or more information output units, and the driving part of the information output unit can move at least in the first direction or the opposite direction, and the expression unit may also move in the first direction or the same direction according to the movement of the driving part. By moving in the opposite direction, various information that can be sensed by the user can be output.

For example, the information output device of this embodiment may be an information output device in which the user senses the surface of the expression portion through tactile sense when the expression portion protrudes. More specifically, for example, it may be information output in the form of Braille output.

As an optional embodiment, the information output device may be a visually sensitive type of information output as the user senses this through vision when the expression part protrudes. In particular, this visual effect can be increased if color is formed on one side of the expression part, for example, the upper surface, or if one side of the expression part is formed to emit light.

Through this, the information output device of this embodiment can output information to the user, and as an optional embodiment, if the information output device of this embodiment is provided with a plurality of information output units, it can output various information to the user.

In addition, specifically, the driving unit can easily move in the first direction, for example, rise, by the magnetic field generated by the coil unit, and can move while rotating while maintaining a certain area by the driving control unit.

For example, if a repulsive force is generated by the magnetic field generated in the coil unit according to the polarity of the magnetic force disposed inside the driving unit, the driving unit may rotate and move upward.

Through this, the rising and falling of the driving part becomes a smooth, natural, and precise movement, thereby reducing the irregular intermittence in the rising and falling of the expressive part, and facilitating flexible and precise control of movement.

The expression unit rises and falls, making it possible to easily implement the on or off state of the information output device.

In addition, the state can be maintained even if the force applied to the drive unit is removed through support during the raising and lowering movement of the drive unit, for example, support for the first and second movement areas through the support unit.

That is, after the first movement area is supported by the magnetic field of the coil unit and the second movement area is supported by the extension part, the power connected to the coil unit is removed or the current or voltage is increased. Even if removed, the driving unit can maintain the second movement area supported on the extension unit.

In addition, after the second exercise area is lowered from the state in which the second exercise area is supported in the extension part by the magnetic field in the opposite direction through the coil part to the state in which the first exercise area is supported in the extension part, the power connected to the coil part is removed or the current is removed. Even if the voltage is removed, the driving unit can maintain the first movement region supported on the extension part.

Through this, the on and off states of the expression part of the information output device can be easily switched and maintained, the power consumption for movement of the expression part can be reduced, and the overall energy efficiency of the information output device can be improved. You can.

In addition, the drive control unit provided in the drive unit of this embodiment is eccentric from the central axis of the drive unit, and through this, torque is easily generated in the drive unit, thereby realizing rise and fall through rotational movement of the drive unit, providing precise and accurate control of the expression unit. You can achieve smooth and natural movement control.

As an optional embodiment, the magnetic force provided in the driving part may be arranged to overlap the driving control part, for example, the center of the magnetic part and the driving control part may overlap.

Through this, it is possible to reduce the change in the position of the magnetic force unit when the drive unit rotates relative to the drive control unit, and for example, the distance between the coil unit and the magnetic unit can be maintained the same or similar. As a result, the non-uniformity of the effect of the magnetic field through the coil unit on the magnetic force unit can be reduced and precise control of the movement of the driving unit can be facilitated.

Figure 4 is a perspective view schematically showing an information output device according to another embodiment of the present invention. FIG. 5 is a cross-sectional view taken along line V-V of FIG. 4, and FIG. 6 is a cross-sectional view taken along line VI-VI of FIG. 4.

4 to 9, the information output device 200 of this embodiment includes at least one information output unit, and FIG. 4 shows one information output unit. That is, the information output device 200 of FIG. 4 may be one information output unit.

Although one information output unit is shown in FIG. 4, the information output device 200 may include two, three or more information output units as an optional embodiment.

That is, the information output device 200 may include a varying number of information output units depending on the purpose, characteristics of the applied product, and user characteristics.

For convenience of explanation, an information output device including one information output unit as shown in FIG. 4 will be described.

The information output device 200 may include a coil unit 220, a base unit 230, a driver unit 240, and a representation unit 210.

The expression unit 210 can move according to the movement of the driving unit 240, which will be described later, and can move its position at least upward and downward based on the longitudinal direction of the expression unit 210. For example, it can move in one direction toward the coil unit 220 and in the opposite direction.

Through this, the expression unit 210 can move to protrude in one direction, and the user can sense the movement of the expression unit 210 tactilely or visually.

The expression unit 210 may include an expression surface 211 and a support surface 212.

The support surface 212 is a surface facing the driving unit 240 among the areas of the expression unit 210, forms the lower area of the expression unit 210, and can be in contact with the driving unit 240, and the driving unit 240 is the support surface 212. ) It is possible to transmit force to the expression unit 210 through.

The expression surface 211 may include an area recognized by the user as the outermost area of the expression unit 210, for example, the area furthest away from the coil unit 220.

For example, the user may recognize the entire area of the expression unit 210, but may also recognize only the expression surface 211. For example, the user can sense the movement of the expression part 210 through contact with the expression surface 211, and the user can easily sense the movement of the expression part 210 through visual detection of the expression surface 211. You can also sense it.

As an optional embodiment, the expression surface 211 may include a curved surface.

The expression unit 210 may have various shapes and may include a column-shaped area. For example, it may include an area similar to a cylinder as shown in FIG. 4 .

Additionally, as an optional embodiment, the protruding area of the expression unit 210 may have a curved surface, and the corners may have a curved surface.

The expression unit 210 may include various materials and may be made of an insulating material that is lightweight and durable. For example, it may contain a resin-based organic material. As another example, it may include inorganic materials such as ceramic materials.

Additionally, as another optional embodiment, the expression unit 210 may be formed of a material such as metal or glass.

The coil unit 220 may be configured to be connected to an external power source (not shown). When current flows through the coil unit 220, a magnetic field may be formed around the coil unit 220.

The coil unit 220 may have various forms. For example, the coil unit 220 may have a form in which multiple circuits of wire are wound, and the number of turns, etc. may be controlled in various ways.

The driving unit 240 can be moved through the magnetic field generated by the current flowing in the coil unit 220, and the driving force for the movement of the expression unit 210 can be provided through this movement of the driving unit 240.

As an optional embodiment, the support part 270 may be further disposed, and at least one area of the support part 270 may be arranged to be adjacent to or support the coil part 220.

For example, the support part 270 includes an extension part 271, and may be arranged to penetrate the coil part 220 with respect to the extension part 271. As a specific example, the support part 270 may be arranged to penetrate the coil part 220 with the extension part 271 as the center. A plurality of coils (220) may have a wound form.

As an optional embodiment, one end of the extension part 271 may be extended long to support the driving part 240, which will be described later, and the movement of the driving part 240 may be carried out while being supported on one end of the extension part 271.

As an optional embodiment, the extension portion 271 may be formed to correspond to the through hole 230H of the base portion 230.

As an optional embodiment, the support part 270 includes a main body part 272, and the main body part 272 is connected to the extension part 271 and may be arranged to support the coil part 220. For example, the coil unit 220 may include coils wound around the extension part 271 on the main body 272.

As an optional embodiment, the main body portion 272 and the extension portion 271 of the support portion 270 may be integrated with each other.

As an optional embodiment, the main body 272 may further include a support portion 280 to be disposed.

The support portion 280 may be arranged to surround the bottom and side surfaces of the main body portion 272.

As an optional embodiment, the support unit 280 may include a protrusion 281 in one area, and one area of the protrusion 281 may be exposed to the side of the base unit 230 to facilitate handling.

The base portion 230 may be formed to accommodate the coil portion 220. For example, the base portion 230 may include a first accommodating portion 231 and a second accommodating portion 232.

The first accommodating part 231 and the second accommodating part 232 may be arranged adjacent to each other or may be arranged not to overlap each other.

As an optional embodiment, the first accommodating part 231 and the second accommodating part 232 may be spaced apart.

As another optional embodiment, the first accommodating part 231 and the second accommodating part 232 may be connected through a through hole 230H.

The coil portion 220 may be disposed in the first receiving portion 231. As an optional embodiment, the above-described support part 270 or pedestal part 280 may be disposed in the first receiving part 231.

As an optional embodiment, a driving groove 234 may be formed in the second receiving portion 232 of the base portion 230. For example, the driving groove 234 may be formed on both sides of the inner surface of the second receiving portion 232 of the base portion 230, and as an optional embodiment, may be formed in one direction, for example, in the coil portion 220. ) may have a shape extending in a direction away from the

As an optional embodiment, the driving groove 234 may be formed as a groove shape or as a penetration area penetrating to the outside. If the driving groove 234 does not penetrate the outside of the base part 230 and is formed in the form of a groove with an internal area removed, the exposure of the base part 230 to the outside is reduced, causing contamination of the driving part 240, Precise control is possible by reducing damage.

The base portion 230 may have an elongated shape to accommodate the coil portion 220 and the driving portion 240, and may be formed to entirely surround both the coil portion 220 and the driving portion 240.

As an optional embodiment, the base portion 230 may include a boundary portion 233 between the first accommodating portion 231 and the second accommodating portion 232.

The first accommodating part 231 and the second accommodating part 232 may be separated through the boundary portion 233.

As an optional embodiment, a through hole 230H may be formed in the boundary portion 233.

Additionally, the base portion 230 includes an inlet portion 230a, and the inlet portion 230a may be connected to the second receiving portion 232. Through the entrance portion 230a, the expression portion 210 can move so that the length protruding out of the base portion 230 changes.

The driving unit 240 may be disposed on the base unit 230. The driving unit 240 may be disposed in the second accommodating portion 232 and may be spaced apart from the coil portion 220 disposed in the first accommodating portion 231.

The driving unit 240 is disposed adjacent to the coil unit 220 and is driven by a current flowing in the coil unit 220 to perform angular or rotational movement. Through the driving unit 240, the expression unit 210 can move up and down, for example, in one direction toward the coil unit and in the opposite direction.

As an optional embodiment, a magnetic force unit 250 may be disposed in the driving unit 240, for example, in an inner space. For example, magnetic portion 250 may contain a magnetic material, for example a permanent magnet.

The magnetic portion 250 may have a first region (for example, N-pole or S-pole) and a second region (for example, S-pole or N-pole) of different polarities, and the first region (for example, N-pole or N-pole) may have different polarities. The region and the second region may be arranged in a direction from the coil unit 220 toward the expression unit 210 at a point during rotation of the driving unit 240, for example, in the Z-axis direction.

For example, based on FIGS. 5 and 6 , the first and second regions of the magnetic force unit 250 of different polarities are oriented in a direction from the coil unit 220 to the expression unit 210, for example, in the Z-axis direction. It can be arranged as

The driving part 240 includes a driving surface 241a on at least an outer surface, and the driving surface 241a is formed to support the expression part 210 and can provide a driving force for the up and down movement of the expression part 210. .

As an optional embodiment, the driving surface 241a of the driving unit 240 may include a curved outer surface. As a more specific example, the driving surface 241a of the driving unit 240 may include a boundary line similar to a circle.

The driving unit 240 may include a driving control unit 249.

The driving position of the driving unit 240 can be controlled through the driving control unit 249. For example, when the drive unit 240 moves by the coil unit 220, it may make angular or rotational movements centered on the drive control unit 249.

As an optional embodiment, the central axis of the drive unit 240 and the drive control unit 249 may not coincide and may be eccentric.

Additionally, as an optional embodiment, the magnetic force unit 250 may not be aligned with the central axis of the drive unit 240, but may be arranged to overlap, for example, an area of the drive control unit 249.

Through this, torque force for the driving unit 240 can be easily generated, and the driving unit 240 can perform angular or rotational movement to efficiently move the expression unit 210 and provide precise information output device 200. Expression can be improved. Additionally, power consumption of the information output device 200 can be reduced.

To describe the driving unit 240 in more detail, refer to FIGS. 7 to 9.

FIG. 7 is a schematic perspective view for explaining the driving unit of FIG. 4, and FIG. 8 is a front view seen from one direction of FIG. 7. FIG. 9 is a partial perspective view of one area of the base portion of FIG. 4 viewed from one direction.

Referring to FIGS. 7 and 8 , the driving unit 240 may include a first driving member 243 and a second driving member 244, and may include a separation space (SA) therebetween.

The outer surfaces of the first driving member 243 and the second driving member 244 include a driving surface 241a on at least one surface to support the expression part 210 when the driving part 240 moves. It can provide driving force to .

As an optional embodiment, the outer surfaces of the first driving member 243 and the second driving member 244 may include a curved surface. For example, the first driving member 243 and the second driving member 244 may have a shape similar to a rotating body, or each may have a shape similar to a disk.

Through this, a natural driving force is provided to the support surface 212 of the expression unit 210 during rotation or angular movement of the first driving member 243 and the second driving member 244, so that the expression unit 210 can move continuously and naturally. can be carried out efficiently.

The drive control unit 249 is located on at least one side of the first drive member 243 and the second drive member 244, for example, on the side of the first drive member 243 and the second drive member 244 facing each other. It can be placed on each of the opposite sides.

As an optional embodiment, the drive control unit 249 may have a protruding shape, and this protruding shape may correspond to the driving groove 234 of the base unit 230.

For example, the driving unit 240 can move due to the magnetic field generated by the coil unit 220, and as a specific example, it can move up and down due to the repulsive force and attractive force on the magnetic force unit 250 within the driving unit 240. At this time, the drive unit 240 can move up and down while rotating around the drive control unit 249, and the drive control unit 249 of the drive unit 240 can rotate while being disposed in the drive groove 234. there is. For example, the drive control unit 249 may rotate within the drive groove 234. Additionally, as an optional embodiment, the drive control unit 249 may rotate and slightly move up and down within the drive groove 234.

A first movement area 245 and a second movement area 248 may be disposed in the space SA between the first driving member 243 and the second driving member 244.

The first exercise area 245 and the second exercise area 248 may be areas that serve as standards for the lowest and highest points, respectively, when the driving unit 240 moves.

For example, when the first exercise area 245 is placed at the lowest point, that is, the area closest to the coil unit 220, the driving unit 220 is placed at the lowest point, and the expression unit 210 is also placed at the lowest point accordingly. This may be when the height at which the expression part 210 protrudes from the base part 230 is the smallest.

In addition, when the second exercise area 248 is placed at the lowest point, that is, the area closest to the coil unit 220, the driving unit 220 is placed at the highest point and the expression unit 210 is also placed at the highest point, specifically. This may be when the height at which the expression part 210 protrudes from the base part 230 is the greatest.

As an optional embodiment, the first exercise area 245 and the second exercise area 248 may be supported on the extension 271 described above. That is, when the driving part 240 moves, the extension part 271 is arranged to correspond to the space SA between the first driving member 243 and the second driving member 244, thereby forming the first movement area 245 and The second exercise area 248 can be supported over time.

As an optional embodiment, a connection area 247 may be disposed between the first exercise area 245 and the second exercise area 248, and the connection area 247 may include a curved surface.

When the driving unit 240 rotates, the extension part 271 may support the first movement area 245 and at least one area of the connection area 247 before supporting the second movement area 248, Through this, the driving unit 240 moves naturally, and the resulting movement of the expression unit 210 can be precisely controlled.

The distance between the driving surface 241a and the first exercise area 245 may be different from the distance between the driving surface 241a and the second exercise area 248. For example, the distance between the driving surface 241a and the first exercise area 245 may be greater than the distance between the driving surface 241a and the second exercise area 248.

As an optional example, the distance between the first movement area 245 and the central axis of the driving unit 240 may be smaller than the distance between the second movement area 248 and the central axis of the driving unit 240.

As an optional embodiment, the distance from the drive control 249 to the first exercise area 245 may be the same or similar to the distance from the drive control 249 to the second exercise area 248, and as a further optional embodiment, the The distance from the control unit 249 to the connection area 247 may also be the same or similar.

For example, the connection area 247 may correspond to at least one area of the circumference having a radius centered around the center point of the drive control unit 249, and the first movement area 245 and the second movement area 248 are each Each may have the form of a flat surface extending parallel to each other in areas facing each other corresponding to the diameter.

Through this, when the drive unit 240 rotates around the drive control unit 249 and the support unit 270 supports the first movement area 245, the second movement area 248, and the connection area 247, the drive control unit ( 249) may remain the same or similar.

Additionally, when supported by the support unit 270, the connection area 247 may include a curved surface or a surface close to an arc, allowing the driving unit 240 to move smoothly and efficiently.

Referring to FIG. 9 , the second receiving portion 232 of the base portion 230 may include a first groove 233c and a second groove 233d.

The first groove 233c and the second groove 233d may extend long in the direction of the coil portion 220. The first driving member 243 and the second driving member 244 may be arranged to correspond to the first groove 233c and the second groove 233d, respectively, and through this, the coil unit 220 is connected to the driving unit 240. When the driving force is transmitted through the driving unit 240, the first driving member 243 and the second driving member 244 are disposed in correspondence with the first groove 233c and the second groove 233d. Can perform angular or rotational movement, and can also perform up and down movement. Through this, stable movement of the driving unit 240 is possible, thereby facilitating precise movement control of the expression unit 210.

As an optional embodiment, a protruding area PT may be formed between the first groove 233c and the second groove 233d. For example, the above-described through hole 230H may be formed in the protruding area PT.

The extension portion 271 of the support portion 270 may correspond to the through hole 230H. At this time, the extension part 271 may protrude into the through hole 230H and protrude further than the protrusion area PT. In this case, the first exercise area 245 and the second exercise area (245) are formed through the extension part 271. 248) can be supported depending on time.

As an optional embodiment, the extension portion 271 may not protrude further than the protruding region PT, in which case the first exercise region 245 and the second exercise region 248 are connected in time through the protrusion region PT. Therefore, it can be supported.

In addition, as an optional embodiment, the extension part 271 or the protruding area PT may not support the driving part 240 or may only temporarily support the driving part 240, and in this case, the driving control part 249 may be connected to the second part of the base part 230. It may be supported by one area of the space 232 and, as an example, may be supported by the boundary surface of the driving groove 234.

FIGS. 10A and 10B are diagrams illustrating a support portion of the information output device of FIG. 4 and a modified example thereof.

Referring to FIG. 10A, as described above, the support portion 270 of this embodiment includes a main body portion 272, and the main body portion 272 is connected to the extension portion 271 and may be arranged to support the coil portion 220. there is.

Also, referring to FIG. 10B as a modified example, the support portion 270' includes a main body portion 272', and the main body portion 272' is connected to the extension portion 271' and is arranged to support the coil portion 220. It can be. Additionally, an upper member 271b' may be formed at one end of the extension portion 271', and the upper member 271b' may be formed of a different material than the extension portion 271'.

As an optional embodiment, the top member 271b' may include a material such as plastic or ceramic. For example, the extension portion 271' may include a magnetic material and the top member 271b' may include plastic.

The embodiment of FIG. 10B can be selectively applied to all other embodiments of the present specification.

FIGS. 11A and 11B are diagrams illustrating a representation unit of the information output device of FIG. 4 and a modified example thereof.

Referring to FIG. 11A, the expression unit 210 of the present embodiment described above may include an expression surface 211 and a support surface 212.

Also, referring to FIG. 11B as a modified example, the expression unit 210' may include an expression surface 211' and a support surface 212', and may include a magnetic material (IMT) therein. Through the magnetic material (IMT) of the expression unit 210', the expression unit 210' can be driven more efficiently through the drive unit 240 and power consumption can be reduced.

The embodiment of FIG. 11B can be selectively applied to all other embodiments of the present specification.

FIG. 12 is a diagram showing a modified example of the base portion of the information output device of FIG. 4.

Referring to FIG. 12, the base portion 230' of this embodiment may include a top base member 230T' and a bottom base member 230B'. The base portion 230' may be formed in an upper and lower manner, and the top base member 230T' and bottom base member 230B' may include a first accommodating portion and a second accommodating portion, respectively.

Through this, each member can be easily placed in each of the first and second accommodating parts of the top base member 230T' and the bottom base member 230B', that is, the driving part, coil part, support part, and expression part can be easily arranged. You can.

As an optional embodiment, after arranging the driving part, coil part, support part, and expression part in each of the second receiving part of the top base member 230T' and the first receiving part of the bottom base member 230B', the top base member 230T' and the bottom base member 230B', thereby manufacturing the information output device to improve convenience.

The embodiment of FIG. 12 can be selectively applied to all other embodiments of the present specification.

The information output device of this embodiment may include one or more information output units, and the driving part of the information output unit can move at least in the first direction or the opposite direction, and the expression unit may also move in the first direction or the same direction according to the movement of the driving part. By moving in the opposite direction, various information that can be sensed by the user can be output.

For example, the information output device of this embodiment may be an information output device in which the user senses the surface of the expression portion through tactile sense when the expression portion protrudes. More specifically, for example, it may be information output in the form of Braille output.

As an optional embodiment, the information output device may be a visually sensitive type of information output as the user senses this through vision when the expression part protrudes. In particular, this visual effect can be increased if color is formed on one side of the expression part, for example, the upper surface, or if one side of the expression part is formed to emit light.

Through this, the information output device of this embodiment can output information to the user, and as an optional embodiment, if the information output device of this embodiment is provided with a plurality of information output units, it can output various information to the user.

In addition, specifically, the driving unit can easily move in the first direction, for example, rise, by the magnetic field generated by the coil unit, and can move while rotating while maintaining a certain area by the driving control unit.

For example, when a repulsive force is generated by the magnetic field generated in the coil part according to the polarity of the magnetic force placed inside the driving part, the driving part rises and there is support for the first and second exercise areas and the connection area between them. Then, rotational movement can be performed.

Through this, the rising and falling of the driving part becomes a smooth, natural, and precise movement, thereby reducing the irregular intermittence in the rising and falling of the expressive part, and facilitating flexible and precise control of movement.

The expression unit rises and falls so that the on or off state of the information output device can be easily implemented.

In addition, the state can be maintained even if the force applied to the driving unit is removed through support during the raising and lowering movement of the driving unit, for example, support for the first and second movement areas through the extension part.

That is, even if the power connected to the coil unit is removed or the current or voltage is removed after the first movement area is supported by the magnetic field of the coil unit and the second movement area is supported in the state, the drive unit does not It can stay that way.

In addition, after the second exercise area is supported in the extension part by a magnetic field in the opposite direction through the coil part and the first exercise area is lowered in the supported state, the power connected to the coil part is removed or the current or voltage is removed. The drive unit can also maintain its state.

Through this, the on and off states of the expression part of the information output device can be easily switched and maintained, the power consumption for movement of the expression part can be reduced, and the overall energy efficiency of the information output device can be improved. You can.

In addition, the drive control unit provided in the drive unit of this embodiment is eccentric from the central axis of the drive unit, and through this, torque is easily generated in the drive unit, thereby realizing rise and fall through rotational movement of the drive unit, providing precise and accurate control of the expression unit. You can achieve smooth and natural movement control.

As an optional embodiment, the magnetic force provided in the driving part may be arranged to overlap the driving control part, for example, the center of the magnetic part and the driving control part may overlap.

Through this, it is possible to reduce the change in the position of the magnetic force unit when the drive unit rotates relative to the drive control unit, and for example, the distance between the coil unit and the magnetic unit can be maintained the same or similar. As a result, the non-uniformity of the effect of the magnetic field through the coil unit on the magnetic force unit can be reduced and precise control of the movement of the driving unit can be facilitated.

Figure 13 is a perspective view schematically showing an information output device according to another embodiment of the present invention.

Referring to FIG. 13, the information output device 1000 of this embodiment includes a plurality of information output units (IU1, IU2 to IU9).

Although nine information output units are shown in FIG. 13, the information output device 1000 may include a various number of information output units as an optional embodiment.

That is, the information output device 1000 may include a varying number of information output units depending on the purpose, characteristics of the applied product, and user characteristics.

Meanwhile, the information output device 1000 may include a housing 1002 to protect a plurality of information output units (IU1, IU2 to IU9), and the housing 1002 has a via hole 1002a corresponding to each information output unit. It can be provided.

The description of each information output unit is omitted as it is the same as the above-described embodiment.

The base portions 130 and 230 in the above-described embodiment may have an elongated shape to correspond to at least a plurality of information output units. Additionally, as another example, the base portions 130 and 230 may be formed integrally to correspond to a plurality of overall information output units.

Additionally, separate base units 130 and 230 may be formed to correspond to each of the plurality of information output units.

For example, each information output unit (IU1, IU2 to IU9) may be provided with the first accommodating parts 131 and 231 and the second accommodating parts 132 and 232 of the above-described embodiment.

In addition, as an optional embodiment, the above-described information output devices 100 and 200 may be included as individual units inside the housing 1002 shown in FIG. 13.

The information output device of this embodiment may include a plurality of information output units, each unit as described in the above-described embodiments.

The information output device of this embodiment can control the driving units included in each unit to move each expression unit, and output various information that can be sensed by the user through the movement of the expression unit.

For example, the information output device of this embodiment may be an information output device in which the user senses the surface of the expression portion through tactile sense when the expression portion protrudes. More specifically, for example, it may be information output in the form of Braille output.

As an optional embodiment, the information output device may be a visually sensitive type of information output as the user senses this through vision when the expression part protrudes. In particular, this visual effect can be increased if color is formed on one side of the expression part, for example, the upper surface, or if one side of the expression part is formed to emit light.

As such, the present invention has been described with reference to the embodiments shown in the drawings, but these are merely illustrative, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. . Therefore, the true scope of technical protection of the present invention should be determined by the technical spirit of the attached patent claims.

Specific implementations described in the embodiments are examples and do not limit the scope of the embodiments in any way. For the sake of brevity of the specification, descriptions of conventional electronic components, control systems, software, and other functional aspects of the systems may be omitted. In addition, the connections or connection members of lines between components shown in the drawings exemplify functional connections and/or physical or circuit connections, and in actual devices, various functional connections or physical connections may be replaced or added. Can be represented as connections, or circuit connections. Additionally, if there is no specific mention such as “essential,” “important,” etc., it may not be a necessary component for the application of the present invention.

In the specification of the embodiment (particularly in the claims), the use of the term “above” and similar referential terms may refer to both the singular and the plural. In addition, when a range is described in an example, the invention includes the application of individual values within the range (unless there is a statement to the contrary), and is the same as describing each individual value constituting the range in the detailed description. . Lastly, unless the order of the steps constituting the method according to the embodiment is clearly stated or there is no description to the contrary, the steps may be performed in an appropriate order. The embodiments are not necessarily limited by the order of description of the steps above. The use of any examples or illustrative terms (e.g., etc.) in the embodiments is merely for describing the embodiments in detail, and unless limited by the claims, the scope of the embodiments is not limited by the examples or illustrative terms. That is not the case. Additionally, those skilled in the art will recognize that various modifications, combinations and changes may be made depending on design conditions and factors within the scope of the appended claims or their equivalents.

100, 200, 1000: Information output device
110, 210: Expression part
120, 220: Coil part
130, 230: Base part
140, 240: driving unit

Claims (1)

Relating to an information output device comprising one or more information output units,
The information output unit is,
coil part;
a representation portion formed and arranged to be perceived by a user;
A base portion formed to accommodate at least one area of the coil portion and the expression portion, and
A driving unit that is spaced apart from the coil unit and is driven by a current flowing in the coil unit to perform angular or rotational movement around one or more rotation axes,
The expression unit is formed to move while being supported by a side area that moves during angular or rotational movement of the driving unit,
After the expression unit moves through the drive unit, it is controlled to have a maintained time even when no current flows through the coil unit,
The coil unit has a shape in which a plurality of turns of wire are wound around one direction,
The rotation axis of the driving unit includes at least one that intersects the one direction in which the coil unit is wound,
An information output device comprising a structure in which the direction in which the coil unit is wound intersects the rotation axis of the drive unit but does not intersect the direction of movement of the expression unit.