KR102507739B1 - Power supply regulator and portable device therewith - Google Patents

Abstract

Disclosed is a power supply control device and a portable device having the same. The disclosed invention is characterized in that a first switching element for controlling a path connecting a battery and a controller is turned on/off by using a power switch provided for power on/off control of a device. Specifically, the first switching element is connected to one side of the power switch, and when the power switch is operated in the second mode while the first switching element is on, the control unit turns off the first switching element, and the first switching element is turned off. When the power switch is operated in the ? state, the first switching element is turned on through the second path, and power from the battery is supplied to the control unit through the third path.

Description

Power supply regulator and portable device having the same {POWER SUPPLY REGULATOR AND PORTABLE DEVICE THEREWITH}

The present invention relates to a power supply control device and a portable device having the same, and more particularly, to a power supply control device for controlling power supply through a battery installed in the portable device and a portable device having the same.

An air purifier is a device widely used in modern life, and is a device that purifies air by filtering physical particles such as dust, fine dust, and ultrafine dust, chemicals such as odor particles and harmful gases, and microorganisms such as bacteria and viruses. .

Air purifiers are positioned as indispensable devices in ordinary homes due to urbanization, industrialization, and internationalization. In addition, the demand is rapidly increasing due to the increase in fine dust, the increase in allergy patients, and the improvement of living standards.

When an air purifier is intended for an environment exceeding 100 m2 or more like a general household, the size of the device may be large. In this device, a filter corresponding to physical particles such as dust, a filter corresponding to chemicals such as gas, and a filter corresponding to microorganisms such as bacteria and viruses may be used in combination. That is, in a large space, a large-sized air purifier capable of complexly accommodating various filters may be used.

However, it is inefficient in terms of space utilization, mobility, and energy consumption to use a large-sized air purifier in a narrow space such as a studio or inside a vehicle, or in a very large space such as a public library or outdoors. In addition, for users who frequently move, an air purifier that is small in size and can be used by an individual in a portable manner is more suitable than a large sized air purifier. Under this background, portable devices that can be used by individuals are being developed.

Portable devices are provided in a small and lightweight form for easy portability. Such a portable device has an advantage in that a user can easily carry it and use it at a desired place. That is, a portable device is a device suitable for a user who has a life pattern of going out frequently or moving to various places rather than staying in one place such as home for a long time.

Such a portable device may be provided in a cordless form to increase portability. For this purpose, portable devices are generally equipped with batteries. The battery is provided to be able to be charged and discharged, and can be mounted inside the portable device. Power for operating the portable device may be supplied by a battery mounted inside the portable device.

On the other hand, portable devices may provide various other functions in addition to simple air purification based on the advantage that they are easy to carry and can be used in various places.

For example, a portable device may include a short-distance communication module such as a Bluetooth module or a mobile communication module such as an LTE module or a Wi-Fi module, through which wireless communication between the portable device and an external device may be performed. Through the wireless communication made in this way, the state of the portable device may be monitored through the external device, and a function of controlling the operation of the portable device using the external device may be provided.

In such a portable device having a communication module for wireless communication, it is required that at least a part of the operation of the communication module be continuously performed even when the power of the portable device is turned off.

For example, in the case of a portable device having a short-distance communication module such as Bluetooth, a mobile communication module such as an LTE module, or a Wi-Fi module, a function capable of controlling power on/off of the portable device by an external device may be provided. In order to enable these functions to be executed, the short-range communication module or mobile communication module must continue to operate even when the power of the portable device is turned off.

At this time, since the short-distance communication module or mobile communication module may be maintained only in a state in which the short-distance communication module or mobile communication module can receive a wireless signal transmitted from an external device, the operation of the short-distance communication module or mobile communication module causes many No amount of power is consumed.

However, as the portable device continues to consume power while the power is turned off, the actual operating time of the portable device is inevitably reduced.

Moreover, if the portable device is left unused for a long time, the battery may be completely discharged. In this case, not only can the user not use the portable device when he wants to use it, but it is inconvenient to use it only after charging for a long time, and the battery is a lithium ion battery. In this case, a problem in that the lifespan of the battery may be rapidly shortened occurs.

In addition, it is common for portable devices to be shipped with their batteries charged after manufacturing so that users can use them immediately after purchase. In order for a user to use a portable device immediately after purchase, the remaining battery capacity of the portable device must be maintained at a predetermined level or higher for a predetermined period after product shipment. And for this, the power consumption of the portable device in the power-off state must be controlled to a minimum level.

For example, it is preferable that a portable device be provided so that the remaining battery level is 60% or more at the point of one year after the battery is shipped in a fully charged state. To this end, the short-range communication module or There is a need to minimize power consumption by components such as a mobile communication module.

Of course, if a removable battery is used in a portable device, battery consumption can be minimized by blocking the contact between the portable device and the battery. .

In prior art literature, a battery protection circuit for preventing overdischarge of a battery is disclosed.

The battery protection circuit in the prior art document includes a state detection means for detecting an overdischarge or overcharge state of a secondary battery, first and second switch means for blocking discharge current or charge current, and detection of the state detection means Based on the result, a control means for controlling the conduction and non-conduction of the first and second switch means, a power-down switch means for cutting off power and a reference voltage source supplied to the state detection means, and over-discharge by the state detection means A power-down means for turning the power-down switch means into a non-conductive state when the state is detected, and a power-down canceling means for returning the power-down switch means from a non-conductive state to a conducting state when charging is started again in an over-discharge state. include

The battery protection circuit of this configuration prevents deterioration of the battery by blocking discharge of the battery when an overdischarge state of the battery is detected.

However, the battery protection circuit in the prior art document only blocks the discharge of the battery when an over-discharge state of the battery is detected, but does not include a configuration for arbitrarily blocking the discharge of the battery.

Therefore, the battery protection circuit of the prior art document is not suitable for application as a means for maintaining the remaining battery level of a portable device at a predetermined level or more within a predetermined period after product shipment.

In addition, according to the battery protection circuit of the prior art literature, in order to return to a state in which battery discharge is possible again in a state in which battery discharge is blocked to prevent overdischarge, charging must be performed through connection terminals exposed to the outside.

That is, the battery protection circuit of the prior art document can be returned to a state in which the battery can be discharged only in a state in which charging is performed, and for this purpose, connection terminals exposed to the outside must be provided.

Therefore, the battery protection circuit in the prior art document is difficult to use in an environment where charging is difficult, and it is difficult to apply it to a portable device in which a connection terminal for charging is not exposed to the outside.

Meanwhile, battery consumption may be controlled through a separate switch provided in the portable device separately from the power switch.

That is, a separate switch for separately controlling only the connection between the battery and the device may be provided in the portable device separately from the power switch, and power consumption of the portable device in the power-off state may be controlled by operating the switch.

For example, by operating a power switch, on/off control of a portable device except for a short-distance communication module or mobile communication module is performed while the connection between the battery and the device is maintained, and by operating a separate switch, the connection between the battery and the device is By being regulated, on/off control of the entire device including the short-distance communication module or the mobile communication module can be performed.

As such, the configuration provided with a separate switch for separately controlling only whether or not the battery is connected to the device can provide a function to arbitrarily block battery discharge, can be used in an environment where charging is difficult, and has a connection terminal for charging. It can also be applied to portable devices that are not exposed to the outside.

However, due to the characteristics of a portable device that is provided in a small and lightweight form for easy portability, it is not desirable to add a separate switch to the portable device. Due to the characteristics of a small-sized portable device, it may be difficult to secure a space required to add a separate switch, and when several switches are placed in a small space, the gap between the switches is narrowed, increasing the risk of erroneous operation.

In addition, it may be difficult to keep the external appearance of the portable device simple due to the exposure of several switches to the outside of the portable device. Moreover, considering that the frequency of completely blocking the connection between the battery and the device is not very high, adding a separate switch with low frequency of use is not a very desirable method.

Japanese Laid-open Patent No. 1002-274945

The present invention provides a power cut-off function capable of reducing battery consumption in a power-off state of a portable device having a built-in battery, and controls power supply that can be switched from a power-off state to a power supply state without a separate power supply. An object of the present invention is to provide a device and a portable device having the same.

In addition, another object of the present invention is a power supply control device capable of switching between a power-off state and a power-supply state without adding a separate connection terminal for charging or a separate switch for separately controlling only whether the battery and the device are connected, and It is to provide a portable device having the same.

Another object of the present invention is a power supply control device capable of arbitrarily blocking battery discharge and contributing to maintaining the battery level of a portable device at a certain level or higher even after a considerable period of time has elapsed after product shipment, and a portable device having the same is providing

The power supply control device according to the present invention is characterized by using a power switch provided for power on/off control of a device to turn on/off a first switching element that regulates a path connecting a battery and a control unit. do.

Specifically, the first switching element disposed on the third path electrically connecting the battery and the control unit is connected to one side of the power switch through the second path, and when the first switching element is on, the power switch is connected to the second path. When operated in the mode, the control unit recognizes that the power switch is operated in the second mode through the first path electrically connecting the power switch and the control unit, turns off the first switching element, and turns off the first switching element. When the power switch is operated in , the first switching element is turned on through the second path and the power of the battery is supplied to the control unit through the third path.

Through this, a power cut-off function capable of reducing battery consumption in a power-off state of a portable device having a built-in battery can be provided to the portable device, and the portable device can be switched from a power-off state to a power-supply state without a separate power supply. can be converted.

In addition, another technical feature of the power supply control device of the present invention is the on/off control of the first switching element in addition to the on/off control of the device using the power switch provided for power on/off control of the device. that can be done together.

Specifically, the power switch is provided to be operable in the first mode or the second mode, and when the power switch is operated in the first mode while the first switching element is on, the control unit operates the power switch through the first path. Recognizing that it is operated in mode 1, the device is turned on/off and controlled, and when the power switch is operated in mode 2 while the first switching element is on, the control unit recognizes that the power switch is operated in mode 2 through the first path. to turn off the first switching element.

Through this, the power switch provided for power on/off control of the device can perform on/off control of the first switching element together, so that only a separate connection terminal for charging or connection between the battery and the device can be separately performed. Switching between the power-off state and the power-supply state can be made easily and quickly without adding a separate switch for regulation.

The power supply control device includes a power switch provided to be operable in a first mode or a second mode; a controller electrically connected to one side of the power switch through a first path; a first switching element electrically connected to one side of the power switch through a second path; and a battery electrically connected to the controller through a third path, wherein the first switching element is disposed on the third path to control shorting of the third path, and the first switching element is turned on. state, when the power switch is operated in the first mode, the control unit recognizes that the power switch is operated in the first mode through the first path and controls the on/off of the device, and the first switching element When the power switch is operated in the second mode in the on state, the control unit recognizes that the power switch is operated in the second mode through the first path, turns off the first switching element, and When the power switch is operated while the device is off, the first switching device is turned on through the second path and power from the battery is supplied to the controller through a third path.

In the first switching element, a gate is electrically connected to one side of the power switch through the second path, a source is electrically connected to the battery through the third path, and a drain is electrically connected to the control unit through the third path. It may include a MOS-FET switching element electrically connected to.

In addition, the other side of the power switch is connected to a first ground, and when the power switch is operated while the first switching element is off, the other side of the gate is connected to the other side of the power switch, and the first switching element can be turned on

The power supply control device may further include a connection part electrically connecting the battery and the second path, and a second switching element regulating a fourth path connecting the second path and a second ground. .

When the power switch is operated in the second mode while the first switching element is on, the controller turns off the second switching element so that the second path is separated from the second ground, and the first switching element When the power switch is operated in an OFF state, the controller turns on the second switching element so that the second path can be connected to the second ground.

In addition, when the second switching device is turned off, the voltage of the battery is applied to the gate of the first switching device through the connection part and the second path, so that the first switching device may remain turned off.

When the second switching element is turned on, the gate of the first switching element is connected to the second ground through the second path and the fourth path, so that the first switching element can remain turned on. .

In addition, when one side and the other side of the power switch are connected for less than the set time, the power switch operates in the first mode, and when one side and the other side of the power switch are connected for more than the set time, the power switch operates in the second mode. mod can work.

A resistor disposed between the controller and one side of the power switch and connected to the controller through the first path;

The control unit determines a connection time between one side and the other side of the power switch by measuring a time when no voltage is applied to the resistor.

The power supply control device may further include a power supply unit receiving power from an external power source and supplying the received power to at least one of the battery and the control unit.

In addition, the power supply control device may further include an external power detection unit for detecting whether or not power is supplied to the power supply unit.

The control unit may not turn off the first switching element even when the power switch is operated in the second mode when the external power detection unit detects power supply to the power supply unit.

In addition, the controller may turn on the first switching device when the external power detection unit detects power supply to the power supply unit while the first switching device is off.

The power supply unit is electrically connected to the control unit through the third path, and the control unit may operate by receiving power from the power supply unit through the third path.

In addition, the power supply unit is electrically connected to the battery via the first switching device through the third path, and the battery can be charged by receiving power from the power supply unit through the third path. .

In addition, the power supply control device may further include a converter for converting the power supplied through the power supply unit into a direct current form.

The portable device including the power supply regulator may include a first function unit that receives power from the power supply regulator, performs a first function, and is controlled on/off by the control unit.

Such a portable device may further include a second functional unit provided for communication between an external device and the portable device.

As described above, in the portable device including the first function unit and the second function unit, when the power switch is operated in the first mode while the first switching element is on, the control unit operates the second function unit except for the second function unit. Only one functional part can be turned on/off.

The second functional unit may include at least one of a Bluetooth communication module, an NFC communication module, an LTE communication module, a Wi-Fi communication module, and a GPS.

The portable device may include a case and a filter module installed inside the case, and the first function unit may include a fan assembly that generates a flow of air outside the case passing through the filter module. can

In addition, the first function unit may further include a sensor module, and the sensor module may include a sensor for detecting air quality.

According to the power supply control device of the present invention and a portable device having the same, it is possible to provide a power cut-off function capable of reducing battery consumption in a power-off state of a portable device having a built-in battery, and to cut off power without a separate power supply. It is possible to provide further improved convenience of use by allowing the state to be switched to the power supply state.

In addition, according to the present invention, it is easy to switch between a power-off state (sleep mode) and a power-supply state (operable state) without adding a separate connection terminal for charging or a separate switch for separately controlling only whether the battery and the device are connected. By enabling this to be done quickly, it is possible to prevent the occurrence of problems in which the product size increases due to the increase in switches and the risk of erroneous operation of the switches increases, and it is possible to provide a portable device having a simple and beautiful appearance to increase user satisfaction. can

In addition, the present invention provides a portable device that can further improve consumer satisfaction because battery discharge can be arbitrarily blocked and the remaining battery power of the portable device can be maintained at a certain level or higher even after a considerable amount of time has elapsed after product shipment. can do.

1 is a front perspective view showing a front side of a portable device according to an embodiment of the present invention.
FIG. 2 is a rear perspective view showing the rear side of the portable device shown in FIG. 14;
3 is a cross-sectional view along line III-III of FIG. 1;
4 is a configuration diagram showing the configuration of a portable device according to an embodiment of the present invention.
5 is a configuration diagram schematically showing the configuration of a power supply control device according to an embodiment of the present invention.
FIG. 6 is a diagram showing a circuit configuration of the power supply regulator shown in FIG. 5 .
FIG. 7 is a diagram showing a first path among the circuit configurations shown in FIG. 6 .
FIG. 8 is a diagram showing a second path among the circuit configurations shown in FIG. 6 .
9 is a diagram showing a third path among the illustrated circuit configurations.
10 is a diagram showing a fourth path in the illustrated circuit configuration.
11 is a flowchart illustrating a control operation related to entering a sleep mode of a power supply regulator according to an embodiment of the present invention.
12 is a configuration diagram showing a control operation state of the power supply regulator according to an embodiment of the present invention in power-off mode operation.
13 is a diagram showing a circuit operating state when the power supply regulator operates in a power-off mode according to an embodiment of the present invention.
14 is a configuration diagram showing a control operation state when the power supply regulator enters a sleep mode according to an embodiment of the present invention.
15 is a diagram showing a circuit operating state when the power supply regulator enters a sleep mode according to an embodiment of the present invention.
16 is a flowchart illustrating a control operation related to release of a sleep mode of a power supply regulator according to an embodiment of the present invention.
17 and 18 are configuration diagrams showing a control operation state of a power supply regulator according to an embodiment of the present invention during a sleep mode release operation.
19 and 20 are diagrams showing circuit operation states when the power supply controller according to an embodiment of the present invention releases a sleep mode.
21 and 22 are configuration diagrams showing another example of a control operation state during a sleep mode release operation of the power supply regulator according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an embodiment of a power supply control device according to the present invention and a portable device having the same will be described with reference to the accompanying drawings. For convenience of description, thicknesses of lines or sizes of components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of a user or operator. Therefore, definitions of these terms will have to be made based on the content throughout this specification.

[Overall structure of portable device]

1 is a front perspective view showing the front side of a portable device according to an embodiment of the present invention, FIG. 2 is a rear perspective view showing the rear side of the portable device shown in FIG. 1, and FIG. 3 is III of FIG. It is a cross-sectional view along line III.

In this embodiment, a case where the portable device 50 is a portable air purifier will be described as an example.

Referring to FIGS. 1 to 3 , a portable device 50 according to an embodiment of the present invention may be formed in a substantially hexahedral shape. The portable device 50 includes a front panel 510, a case 520, a fan cover 530, fan assemblies 540 and 545, a filter module 550, a battery 560, a rear panel 570, and a rear cover. (580).

The case 520 forms the outer skeleton of the portable device 50 . A number of parts are accommodated in the case 520 .

The front panel 510 is coupled to the front of the case 520 . This front panel 510 forms the front appearance of the portable device 50 .

The rear panel 570 is coupled to the rear of the case 520 . This rear panel 570 forms the rear exterior of the portable device 50 .

The portable device 50 as a whole may be formed in an upright hexahedral shape with a long length in the vertical direction. Accordingly, the user can use the portable device 50 standing or laying it down. In addition, even when the portable device 50 is used in a lying state in a place where shaking occurs, such as inside a vehicle, the portable device 50 can stably maintain its position without rolling.

define the direction "Front" means the direction in which the front panel 510 is positioned from the case 520, and "rear" means the opposite direction, in which the rear panel 520 is positioned from the case 520. means the direction

The front panel 510 is disposed at the forefront of the portable device 50 to form the front appearance of the portable device 50 . The air purified by the portable device 50 is discharged to the outside through the front panel 510 . To this end, a plurality of discharge ports 510a are provided on the front panel 510 .

The case 520 forms the outer skeleton of the portable device 50 . The exterior of the top, side, and bottom of the portable device 50 is formed by the case 520 . An accommodation space is formed inside the case 520 . Various parts constituting the portable device 50, such as the fan cover 530, the fan assemblies 540 and 545, the battery 550, and the filter module 560, are accommodated in this accommodation space. The case 520 is preferably formed to have sufficient strength to protect the received components from external impact.

The fan cover 530 is accommodated in the accommodation space inside the case 520 and is disposed in front of the fan assemblies 540 and 545 . That is, the fan cover 530 is disposed between the front panel 510 and the fan assemblies 540 and 545 inside the case 520 .

The fan cover 530 fixes the fan assemblies 540 and 545 inside the case 520 . In addition, the fan cover 530 also serves to guide the flow of air so that the air blown by the fan assemblies 540 and 545 can go straight forward without spreading to the surroundings.

The fan assemblies 540 and 545 are accommodated in the accommodation space inside the case 520 and are disposed between the fan cover 530 and the filter module 550 . That is, the fan assemblies 540 and 545 are disposed behind the fan cover 530 and in front of the filter module 550 . These fan assemblies 540 and 545 serve to suck in air from the rear of the portable device 50 and discharge the air to the front.

The fan assemblies 540 and 545 are accommodated in the accommodation space inside the case 520 and are disposed in the first area S1. Accordingly, the fan assemblies 540 and 545 are disposed at positions facing the rear surface of the upper cover part 531 among the upper cover part 531 and the lower cover part 535 of the fan cover 530 .

In this embodiment, it is illustrated that the portable device 50 is provided with two fan assemblies 540 and 545 . According to this, the portable device 50 is provided with an upper fan assembly 540 and a lower fan assembly 545 .

The upper fan assembly 540 and the lower fan assembly 545 are disposed in a vertical direction. That is, the upper fan assembly 540 and the lower fan assembly 545 are disposed on the same vertical line.

The upper fan assembly 530 and the lower fan assembly 535 may be disposed to face the air discharge units 532 and 533 formed on the fan cover 530 . Accordingly, the air sucked into the upper fan assembly 540 and the lower fan assembly 545 through the rear panel 570 passes through the upper air discharge part 532 and the lower air discharge part 533, respectively, and It may be discharged forward through the panel 510 .

In this embodiment, it is illustrated that the upper fan assembly 540 and the lower fan assembly 545 are formed in the same size and shape. Alternatively, however, the upper fan assembly 540 and the lower fan assembly 545 may have different sizes and shapes.

The upper fan assembly 540 and the lower fan assembly 545 include blowing fans 541 and 546 and motors (not shown), respectively.

The blowing fans 541 and 546 are provided to generate a flow of air. As an example, the blowing fans 541 and 546 may include axial fans. Air sucked into the case 520 through the rear panel 570 may be sucked in the axial direction of the blowing fans 541 and 546 and then discharged in the axial direction of the blowing fans 541 and 546 .

The motor is connected to the blowing fans 541 and 546 to give rotational force to the blowing fans 541 and 546 . Such a motor may include a BLDC motor with adjustable frequency.

The filter module 550 is accommodated in the accommodation space inside the case 520 and is disposed between the fan assemblies 540 and 545 and the rear panel 570 . That is, the filter module 550 is disposed behind the fan assemblies 540 and 545 and in front of the rear panel 570 . The filter module 550 serves to purify air sucked through the rear of the portable device 50 . The air purified while passing through the filter module 550 passes through the fan assemblies 540 and 545 , the fan cover 530 , and the front panel 510 and is discharged to the front of the portable device 50 .

The battery 560 is accommodated in an accommodation space inside the case 520 and is disposed below the fan assemblies 540 and 545 and the filter module 550 . The battery 560 may supply power for driving the portable device 50 . To this end, the battery 560 may be electrically connected to at least one of the fan assemblies 540 and 545, the sub PCB 590, the main PCB 595, and the filter module 550.

The battery 560 is accommodated in the accommodation space inside the case 520 and is disposed in the first area S2. The first region S2 is a region disposed below the first region S1 in which the fan assemblies 540 and 545 and the filter module 550 are disposed. The upper boundary surface of the first region S2 may be defined by the fan assemblies 540 and 545 and the filter module 550, and the lower and side boundary surfaces of the first region S2 may be defined by the bottom part 527 of the case 520. and the side portion 521.

The battery 560 located in the first region S2 is disposed below the fan assemblies 540 and 545 and the filter module 550 . In addition, the battery 560 is disposed between the fan cover 530 and the rear cover 580. That is, the fan assemblies 540 and 545 and the filter module 550 are disposed above the battery 560, the lower cover 535 of the fan cover 530 is disposed in front of the battery 560, and the battery 560 At the rear of the rear cover 580 is disposed.

The rear panel 570, along with the rear cover 580, is disposed at the rear of the case 520 to form the rear exterior of the portable device 50. The rear panel 570 is disposed behind the filter module 560. External air is sucked into the portable device 50 through the rear panel 570 . To this end, a plurality of first intake ports 570a are provided on the rear panel 570 .

Also, the rear cover 580, together with the rear panel 570, is disposed at the rear of the case 520 to form a rear appearance of the portable device 50. The rear cover 580 is disposed behind the battery 560. According to this embodiment, the rear area of the filter module 550 is covered by the rear panel 570 . A rear area of the battery 560 is covered by the rear cover 580 .

Meanwhile, a power button 592 may be provided on the upper portion of the case 520, that is, on the upper surface portion 523 of the case 520. The power button 592 is provided as a control button for turning on/off the power of the portable device 50 .

In addition, an air volume control button 593 may be provided at the top of the case 520 together. The air volume control button 593 is provided as a control button for increasing or decreasing the air volume of the portable device 50 . The air volume control button 593 may be disposed adjacent to the power button 592 so that a user can easily identify and operate it.

The accommodation space inside the case 520 may be divided into a first area S1 and a first area S2. When the accommodating space is divided vertically, the upper region becomes the first region S1 and the lower region becomes the first region S2. It should be noted that the first area S1 and the first area S2 are not physically partitioned areas, but only conceptually partitioned areas.

According to this embodiment, among components accommodated in the accommodating space, the fan assemblies 540 and 545 and the filter module 550 are disposed in the first region S1, and the battery 550 is disposed in the first region S2.

The portable device 50 of this embodiment may further include a sub-PCB 590 and a main PCB 595.

The sub PCB 590 includes a sub board 591, a power button 592 and an air volume control button 593 installed on the sub board 591. This sub-PCB 590 may be electrically connected to the main PCB 595.

The sub-PCB 590 may be disposed at the top of the inside of the case 520 . That is, the sub-PCB 590 is disposed above the fan assemblies 540 and 545 and the filter module 550 . The power button 592 and the air volume control button 593 installed in the sub-PCB 590 pass through the upper surface 523 of the case 520 and are exposed to the outside of the case 520 . The user can turn on/off the portable device 50 or adjust the air volume of the portable device 50 by manipulating the buttons exposed in this way.

In addition, the portable device 50 may further include a main PCB 595 that manages all hardware modules of the portable device 50 . The main PCB 595 may function as a controller of the portable device 50 .

The main PCB 595 is disposed below the fan assemblies 540 and 545 in the accommodation space inside the case 520 . That is, the main PCB 595 is accommodated in the first region S2 inside the case 520 and may be disposed between the lower cover 535 of the fan cover 530 and the battery 560 .

As an example, the main PCB 595 may be disposed parallel to the lower cover 535 . The main PCB 595 may be supported by the lower cover 535 and the battery 560 between the lower cover 535 and the battery 560 on both sides in the forward and backward directions.

The main PCB 595 may include a main board 596 and a plurality of devices 597 installed on the main board 591 . The main board 591 may be electrically connected to the fan assemblies 540 and 545 , the battery 560 , the sub PCB 590 , and the sensor module 600 . The main PCB 595 operates the upper fan assembly 530 and the lower fan assembly based on commands input through the power button 592 and air volume control button 593 or data sensed through the sensor module 600. The operation of 535 can be controlled.

Also, the main PCB 595 may be electrically connected to the filter module 550 . For example, when the filter 559 includes an ionizer, the main PCB 595 may be electrically connected to the ionizer and supply power to the ionizer. Alternatively, the filter 529 may be electrically connected to the battery 560 and receive power directly from the battery 560 .

In addition, the portable device 50 of this embodiment may further include a sensor module 600 . The sensor module 600 is disposed in the accommodation space inside the case 520 and is disposed in the first region S2. This sensor module 600 is disposed between the battery 560 and the rear cover 580. That is, the battery 560 is disposed in front of the sensor module 600, and the rear cover 580 is disposed in the rear of the sensor module 600.

The sensor module 600 may include various sensors for detecting air quality around the portable device 50 or in an indoor space where the portable device 50 is disposed. The sensor module 600 may detect air quality and transmit the detected information to the main PCB 595 that manages all hardware modules of the portable device 50 .

[Configuration related to communication and control of portable devices]

4 is a configuration diagram showing the configuration of a portable device according to a third embodiment of the present invention.

Referring to FIG. 4 , a portable device 50 according to an embodiment of the present invention can communicate with an external device such as a mobile terminal 40 . As communication is performed, the portable device 50 may transmit and receive various types of information, data, and commands to and from the mobile terminal 40 .

The sensor module 600 may include various sensors for detecting air quality around the portable device 50 or in an indoor space where the portable device 50 is disposed. For example, sensors may include dust sensors, gas sensors, and the like. The sensor module 600 may detect air quality using sensors and transmit the detected data to the controller 680 or the mobile terminal 40 .

The portable device 50 determines that the air quality is degraded based on the sensing data received from the sensor module 600, and in this case, it is automatically turned on to perform an air purification function. Thereafter, the portable device 50 may determine that the air quality is improved based on the sensing data received from the sensor module 600, and may be automatically turned off to stop the air purification function.

According to this embodiment, on/off of the portable device 50 may mean on/off of an air purifying operation, and a communication operation may be performed regardless of on/off of the portable device 50 .

The user of the mobile terminal 40 can check the air quality based on the sensing data received from the sensor module 600 and turn on or off the portable device 50 based on the checked air quality.

Depending on the embodiment, the portable device 50 may provide various types of information about the operation and state of the portable device 50 to the mobile terminal 40 . For example, the portable device 50 may provide the mobile terminal 40 with various types of information, such as the air volume or operation time of the blowing fan, the state of the filter module 550, and the remaining amount of the battery 560.

The mobile terminal 40 may transmit a control command for remotely controlling on/off of the portable device 50 to the portable device 50 according to a user's input. That is, the portable device 50 may transmit and receive various types of information or commands through communication with the sensor module 600 or the mobile terminal 40 .

The portable device 50 according to this embodiment may include a sensor module 600, a wireless communication unit 650, an output unit 660, a memory unit 670, and a control unit 680.

At least one of the wireless communication unit 650, the sensor module 600, the memory unit 670, and the control unit 680 may be included in the main PCB 595 (see FIG. 3). In addition, at least some of the wireless communication unit 650, the memory unit 670, and the control unit 680 may be implemented as a single integrated chip, or may be implemented as separate chips or circuits.

The wireless communication unit 650 may include a communication module enabling wireless communication between the portable device 50 and the sensor module 600 or between the portable device 50 and the mobile terminal 40 . For example, the wireless communication unit 650 may include a short-distance communication module 651, a mobile communication module 653, and a location information module 655.

The short-distance communication module 651 may perform communication with the sensor module 600 or the mobile terminal 40 . For example, the short-distance communication module 651 includes a communication module supporting a low-power wireless communication method (eg, Bluetooth low energy (BLE)) to minimize power consumption when performing a communication function. In addition, the short-range communication module 651 may include modules supporting various short-range communication methods such as a Bluetooth communication module and an NFC communication module.

The mobile communication module 653 may perform communication with the mobile terminal 40 or a server (not shown). For example, the mobile communication module 653 may include a module supporting a wireless communication scheme such as long term evolution (LTE) and Wi-Fi.

The location information module 655 is for acquiring location information of the portable device 50, and may include a module for acquiring location information according to various satellite navigation systems such as a global positioning system (GPS). As another example, the controller 680 may obtain location information of the portable device 50 using the mobile communication module 653 as well as the location information module 655 .

The output unit 660 may output information or notification related to the operation of the portable device 50 . For example, the output unit 660 may be implemented as a light source or a display that outputs information or notifications in a visual form, or may be implemented as a speaker that outputs information or notifications in an audio form.

The memory unit 670 may store data such as various types of information or algorithms for the operation of the portable device 50 . In particular, the memory unit 670 may store comparison data (hereinafter, referred to as learning data) for detecting a state of a vehicle from sensing data obtained from the sensor module 600 .

The learning data may include boarding data for detecting a boarding state. The boarding data may include vibration patterns or acceleration patterns when the vehicle is stopped after being turned on, and vibration patterns or acceleration patterns when the vehicle is running.

The learning data may be provided in a pre-stored form when the product is shipped, or may be received and stored from the mobile terminal 40 or the server. Also, the learning data may be regularly or irregularly updated by the mobile terminal 40 or the server.

The controller 680 may include at least one controller that controls overall operations of the portable device 50 .

The controller 680 may control the driving of a blowing fan, more specifically, the motor 132 for rotating the blowing fan, for an air purification operation. When the motor 132 is driven, rotational force is applied to the blowing fan, and air may flow according to rotation of the blowing fan.

In particular, when the motor 132 is implemented as a BLDC motor capable of adjusting the frequency, the controller 680 controls the air volume control button 185 or requests air volume control obtained through communication with the mobile terminal 40, or a sensor module. Based on the detection result received from 600, the air volume can be adjusted by adjusting the rotational speed of the motor 132.

In addition, the portable device 50 of this embodiment may further include a power supply control device 800 . The power supply control device 800 is provided as a means for regulating the connection between the battery and the portable device 50 . The power supply control device 800 may provide a function for reducing battery consumption of the portable device 50 in a power off state, and the specific configuration and operation of the power supply control device 800 will be described later. .

[Configuration of power supply controller]

5 is a configuration diagram schematically showing a configuration of a power supply regulator according to an embodiment of the present invention, and FIG. 6 is a diagram showing a circuit configuration of the power supply regulator shown in FIG. 5 . 7 is a diagram showing a first path in the circuit configuration shown in FIG. 6, and FIG. 8 is a diagram showing a second path in the circuit configuration shown in FIG. 9 is a diagram showing a third path in the illustrated circuit configuration, and FIG. 10 is a diagram illustrating a fourth path in the illustrated circuit configuration.

5 and 6, the power supply control device 800 according to an embodiment of the present invention includes a power switch 810, a control unit 680, a first switching element 820, and a second switching element ( 830), a power supply unit 840, and an external power detection unit 850.

The power switch 810 is provided to generate signals for turning on/off the power of the portable device 50 and regulating the connection between the portable device 50 and the battery 560 . In this embodiment, it is exemplified that the power switch 810 is provided in the form of a push switch that can be operated by a push operation of pressing the power button 592 .

One side of the power switch 810 is connected to a first ground 815, and the other side of the power switch 810 is connected to a first path (a) and a second path (b) to be described later. The power switch 810 may be operated in any one of an on state in which one side and the other side are electrically connected, and an off state in which the one side and the other side are electrically disconnected.

The operation of the power switch 810 may be performed by the power button 592. For example, when the user presses the power button 592, the power switch 810 turns on, and when the user releases the power button 592, the power switch 810 turns off.

The power switch 810 is provided to be operable in the first mode or the second mode. That is, the power switch 810 may be operated in different modes depending on how the user presses the power button 592 .

In this embodiment, it is exemplified that the operation mode of the power switch 810 changes according to the time the user presses the power button 592 .

According to this, when one side and the other side of the power switch 810 are connected for less than the set time, that is, when the on state of the power switch 810 continues for less than the set time, the power switch 810 is operated in the first mode. In addition, when one side and the other side of the power switch 810 are connected for a set time or longer, when the on state of the power switch 810 continues for a set time or longer, the power switch 810 operates in the second mode.

As an example, the set time may be set to 5 seconds, and accordingly, when the user presses the power button 592 for less than 5 seconds, the power switch 810 operates in the first mode, and the user presses the power button 592 ) is pressed for 5 seconds or more, the power switch 810 may be operated in the second mode.

As another example, the operation mode of the power switch 810 may vary according to the number of times the user presses the power button 592 continuously, and the operation of the power switch 810 depends on the force with which the user presses the power button 592. There may be various modifications for distinguishing the operation mode of the power switch 810, such as a different mode.

The portable device 50 of this embodiment may include a main PCB 595 (see FIG. 3 ) that manages all hardware modules of the portable device 50 , and the main PCB 595 controls the controller ( 680).

The control unit 680, which can be implemented through the main PCB 595 as described above, may include at least one controller that controls overall operations of the portable air purifier 50.

A controller included in the controller 680 may be provided with a plurality of pins A, B, C, and D connected to respective paths.

For example, the first pin (1) is connected to the fourth path (d), the second pin (2) is connected to the third path (c), and the third pin (3) is connected to the fifth path (e). and the fourth pin 4 may be connected to the first path (a).

According to this embodiment, each component constituting the power supply control device 800 may be electrically connected by a plurality of paths (a, b, c, d, e).

One side of the power switch 810 and the fourth pin 4 of the control unit 680 may be electrically connected through a first path (a) (see FIG. 7), and one side of the power switch 810 and the first switching The device 820 may be electrically connected through the second path (b) (see FIG. 8). And the battery 560 and the controller 680 can be electrically connected through the third path (c) (see FIG. 9), and between the second path (b) and the second ground 835 is the fourth path (d). ) can be electrically connected through (see FIG. 10). In addition, the power supply unit 840 and the external power detection unit 850, which will be described later, may be connected to the control unit 680 through a fifth path (e).

Among them, the third path (c) connected to the battery 560 and the fifth path (d) connected to the power supply unit 840 may constitute the power unit P shown in FIG. 5 . In this embodiment, the power supply unit P is defined as a path through which battery power supplied through the battery 560 and external power supplied through the power supply unit 840 are supplied to the control unit 680 .

In addition, a battery voltage sensing unit 845 for sensing the voltage of the battery 560 may be provided in the third path (c). The battery voltage detection unit 845 may be provided in the form of a circuit configured on the third path (c) to detect the voltage of the battery 560 connected to the third path (c). The control unit 680 may check the remaining capacity of the battery 560 using voltage-related information of the battery 560 sensed through the battery voltage detection unit 845 .

Meanwhile, which mode of the first mode and the second mode the power switch 810 operates in can be determined by the controller 680 . In this embodiment, the operating mode of the power switch 810 can be distinguished according to the duration of the on state of the power switch 810, and the control unit 680 detects the duration of the on state of the power switch 810, thereby An operating mode of the switch 810 may be determined.

To this end, the power supply control device 800 of this embodiment may further include a resistor 860. The resistor 860 may be provided between one side of the power switch 810 and the controller 680 . In this embodiment, the resistor 860 is illustrated as being provided on the first path (a).

The control unit 680 determines the connection time between one side and the other side of the power switch 810, that is, the on-state duration of the power switch 810, by measuring the time when no voltage is applied to the resistor 860.

According to this, when the power switch 810 is in an on state, a low signal is input to the fourth pin 4 of the controller 680, and when the power switch 810 is in an off state, a voltage is applied to the resistor 860 Accordingly, a high signal is input to the fourth pin 4 of the controller 680.

The control unit 680 measures the length of time for which the low signal is input to the fourth pin 4, and as a result of the measurement, if the low signal is continuously input to the fourth pin 4 for more than a set time, the power switch 810 It can be determined that it is operating in the second mode. If the measurement result is less than the set time, the controller 680 may determine that the power switch 810 is operating in the first mode.

The first switching element 820 is disposed on the third path (c) to control the shorting of the third path (c). Short circuit of the third path (c) is controlled by the on/off operation of the first switching device 820, and accordingly, whether to supply power from the battery 560 to the control unit 680 can be controlled.

In this embodiment, the first switching element 820 is illustrated as including a MOS-FET switching element. According to this, in the first switching device 820, the gate (G) is electrically connected to one side of the power switch 810 through the second path (b), and the source (S1) is connected to the third path (c). It is electrically connected to the battery 560 through and the drain D is provided in a form electrically connected to the control unit 680 through the third path (c).

More specifically, the first switching device 820 may include a P-channel MOS-FET switching device. The first switching device 820 may be operated to be in an on state when a low signal is input to the gate (G) and to be in an off state when a high signal is input to the gate (G). .

The battery 560 is electrically connected to the controller 680 through the third path (c). The third path (c) is an electrical path connecting the battery 560 and the controller 680, one side of the third path (c) is connected to the battery 560, and the other side of the third path (c) The side is connected to the control unit 680, and the first switching element 820 is disposed on this third path (c).

The second switching element 830 is disposed on a passage electrically connecting the fourth path (d), that is, the second path (b) and the second ground 835 to control shorting of the fourth path (d). do. The shorting of the fourth path (d) is controlled by the on/off operation of the second switching element 830, and accordingly, whether or not the second path (b) is connected to the second ground 835 can be controlled. .

In this embodiment, the second switching element 830 is illustrated as including a BJT switching element. According to this, in the second switching element 830, the base B is electrically connected to the first pin 1 of the control unit 680, and the collector C passes through the fourth path d to the second path. (b), and the emitter (E) is provided in a form electrically connected to the second ground 835 through the fourth path (d).

The second switching element 830 may be operated to be in an on state when a high signal is input to the base (B) and to be in an off state when a low signal is input to the base (B). Also, the state of the contact point 5 to which the second path (b) and the fourth path (d) are connected may change depending on whether the second switching element 830 is in an on state or an off state.

In addition, the power supply control device 800 of this embodiment may further include a connection unit 870. The connection unit 870 is provided to electrically connect the battery 560 and the second path (b). In this embodiment, one side of the connection unit 870 is connected to the portion between the battery 560 and the first switching element 820 of the third path (c), and the other side of the connection unit 870 is connected to the second path (b). It is illustrated as being connected to a portion between the first switching element 820 and the contact point 5 of.

According to this, the state of the contact point 5 between the second path (b) and the fourth path (d) is affected by the connection unit 870 and the second switching element 830. That is, when the second switching element 830 is in an on state, the contact point 5 is connected to the second ground 835 and becomes a low state, and when the second switching element 830 is in an off state, the connection part 870 As the connection between the contact point 5 and the second ground 835 is disconnected while connected to the battery 560 through ), the contact point 5 becomes a high state.

The on/off operation of the second switching device 830 may be controlled by the controller 680. That is, when the power switch 810 is operated in the second mode while the first switching device 820 is on, the controller 680 turns off the second switching device 830, and thus the second path (b) It may be separated from the second ground 835. When the power switch 810 is operated while the first switching device 820 is off, the control unit 680 turns on the second switching device 830, and thus the second path b connects to the second ground. (835) and can be electrically connected. A detailed description of this will be described later.

The power supply unit 840 is provided to receive power from an external power source. In this embodiment, the power supply unit 840 is illustrated as being provided in the form of a connector provided to be connectable to a wire connected to an external power source.

The power supply unit 840 may be electrically connected to the control unit 680 through a fifth path (e). In addition, the power supply unit 840 may also be connected to the third path (c), and may be electrically connected to the battery 560 through the third path (c). Accordingly, the power supply unit 840 may supply power supplied from an external power source to at least one of the battery 560 and the control unit 680 .

That is, the control unit 680 is electrically connected to the power supply unit 840 through the third path (c), and can be operated by receiving power from the power supply unit 840 through the third path (c). And, the battery 560 is electrically connected to the power supply 840 via the first switching device 820 through the third path (c), and from the power supply 840 through the third path (c). It can be charged by receiving power. At this time, charging of the battery 560 is possible while the first switching element 820 is on.

Between the power supply unit 840 and the control unit 680, an external power detection unit 850 may be provided. The external power detection unit 850 is disposed on the fifth path (e) and is electrically connected to the power supply unit 840 and the control unit 680. The external power detection unit 850 detects whether external power is connected to the power supply unit 840, and the control unit 680 determines whether the power supply unit 840 is connected to the external power supply unit 840 according to the detection result of the external power detection unit 850. You can check whether the power is connected or not.

When power supply to the power supply unit 840 is detected by the external power detection unit 850 while the first switching element 820 is in an ON state, even if the power switch 810 is operated in the second mode, the control unit 680 controls the 1 Do not turn off the switching element 820. In addition, when power supply to the power supply 840 is detected by the external power detection unit 850 while the first switching element 820 is turned off, the control unit 680 turns on the first switching element 820 that was turned off. perform the control operation. A detailed description thereof will be described later.

In addition, a first switching device 820 is disposed between the power supply unit 840 and the battery 560, and the power supplied through the power supply unit 840 passes through the first switching unit 820 to the battery 560. can be supplied. A converter 880 may be provided between the power supply unit 840 and the first switching device 820 . Power input to the power supply unit 840 in AC form may be converted into DC form by the converter 880 and then supplied to the battery 560 and the control unit 680 .

In this embodiment, the battery 560 is illustrated as supplying power of 5V voltage, and accordingly, the converter 880 may convert the power input to the power supply unit 840 in the form of alternating current into DC power of 5V voltage. can be provided.

In addition, a noise filter 890 may be installed on the third path (c) and the fifth path (e). The noise filter 890 serves to remove noise of power supplied from the power supply 840 or the battery 560 and may be formed of a combination of a resistor and a capacitor.

[Operations and effects of the power supply regulator]

11 is a flowchart showing a control operation related to entering a sleep mode of a power supply regulator according to an embodiment of the present invention, and FIG. 12 is a control operation of a power supply regulator in a power off mode according to an embodiment of the present invention. 13 is a diagram showing the operating state of the circuit during power off mode operation of the power supply regulator according to an embodiment of the present invention. 14 is a configuration diagram showing a control operation state when the power supply regulator enters the sleep mode according to an embodiment of the present invention, and FIG. 15 is a sleep mode of the power supply regulator according to an embodiment of the present invention. It is a diagram showing the operating state of the circuit during the entry operation. 16 is a flowchart showing a control operation related to the sleep mode release of the power supply controller according to an embodiment of the present invention, and FIGS. 17 and 18 are the sleep mode release of the power supply controller according to an embodiment of the present invention. It is a configuration diagram showing the control operation status during operation. In addition, FIGS. 19 and 20 are diagrams showing circuit operation states during the sleep mode release operation of the power supply controller according to an embodiment of the present invention, and FIGS. 21 and 22 are power supply according to an embodiment of the present invention. It is a configuration diagram showing another example of the control operation state during the sleep mode release operation of the controller.

Referring first to FIG. 4 , the portable device 50 of the present invention may include a first function unit F1 and a second function unit F2.

Among them, the first function unit F1 corresponds to a configuration that receives power from the power supply control device 800 and performs the first function. In this embodiment, the portable device 50 is illustrated as a portable air purifier, and accordingly, the first functional unit F1 may include elements related to performing an air purifying function.

For example, the first functional unit F1 includes an upper fan assembly 540 and a lower fan assembly 545 that perform a function of sucking in air from the rear of the portable device 50 and discharging it to the front, air quality It may be made including a sensor module 600 that performs functions such as sensing.

Also, an output unit 660 that outputs information or notification related to the operation of the portable device 50 may also be included in the first function unit F1. In this case, the output unit 660 may be implemented as a light source or a display that outputs information or notifications in a visual form, or may be implemented as a speaker or the like that outputs information or notifications in an audio form.

Also, the second functional unit F2 corresponds to a configuration provided for communication between an external device and the portable device 50 . In this embodiment, the second functional unit (F2) may include a wireless communication unit 650 provided for communication between the portable air purifier and an external device.

The first function unit F1 may be controlled on/off by the control unit 680. That is, the first function unit F1 may be controlled on/off by the control unit 680 separately from the second function unit F2 in a state in which power is supplied to the control unit 680 .

In contrast, the second functional unit F2 is not directly controlled on/off by the control unit 680. In this embodiment, the second function unit F2 is illustrated as being in an off state when power supply to the entire portable device 50 is stopped.

That is, while power on/off control of the portable device 50 is performed by the controller 680, power supply to the second function unit F2 is not interrupted, and the entire portable device 50 including the controller 680 is not interrupted. The supply of power to the second functional unit F2 may be stopped only when the supply of power to the is stopped.

Hereinafter, on/off of the first function unit F1 is controlled by the control unit 680, and the power supply to the first function unit F1 is stopped in a power off mode, and the control unit 680 and the second function A state in which power supply to the entire portable device 50 including the unit F2 is stopped is defined as a sleep mode.

11 to 13, when the user presses the power button 592 (S110), the power switch 810 is turned on (S120), and the controller 680 turns on the power switch 810. It is determined whether or not the state has continued for a minimum time (for example, 0.05 seconds) (S130).

If the user presses the power button 592 for a shorter period of time than the minimum time, the controller 680 determines that the operation is not intended by the user and ignores the signal input through the power switch 810 (S131). .

If the user presses the power button 592 for longer than the minimum time, the controller 680 first determines whether the portable device 50 is in operation, that is, whether the first function unit F1 of the portable device 50 is in operation. Do (S140).

If the first function unit F1 of the portable device 50 is not in operation, that is, if the portable device 50 is in a power-off mode, the controller 680 determines whether external power is connected to the power supply unit 840. It is determined whether or not (S141).

When external power is connected to the power supply unit 840, the control unit 680 performs power on/off control for the first function unit F1 so that power is supplied to the first function unit F1. It does (S142). This is because, if external power is connected to the power supply unit 840, it can be said that a sufficient amount of power to operate the first function unit F1 is being supplied to the portable device 50. As a result, the power-off mode of the portable device 50 is released, and the portable device 50 can perform the first function, that is, a function related to air purification.

If external power is not connected to the power supply unit 840, the control unit 680 checks the remaining amount of the battery 560 (S143), and the remaining amount of the battery 560 operates the first function unit F1. If it is determined that it is not sufficient to do so, the control unit 680 ignores the signal transmitted from the power switch 810 (S144).

If it is determined that the remaining amount of the battery 560 is sufficient to operate the first function unit F1, the controller 680 controls the first function unit F1 to supply power to the first function unit F1. Performs power on/off control for (S145). As a result, the power-off mode of the portable device 50 is released, and the portable device 50 can perform the first function, that is, a function related to air purification.

If the first functional unit F1 of the portable device 50 is in an operating state, that is, if the portable device 50 is released from the power-off mode, the controller 680 sets the power switch 810 to an on state. It is determined whether or not the time (eg, 5 seconds) has continued (S150).

When the power switch 810 is turned on, that is, when the user presses the power button 592, one side of the power switch 810 connected to the first path (a) is connected to the first ground 815, and accordingly A low signal, that is, a 0V voltage signal is input to the fourth pin 4 of the controller 680.

On the other hand, when the power switch 810 is turned off, that is, the power button 592 is not pressed, a high signal, that is, 5V, is generated as the voltage is applied to the resistor 860 provided on the first path (a). A voltage signal is input to the fourth pin 4 of the controller 680.

The controller 680 determines whether a low signal is continuously input to the fourth pin 4 for a set time or more. The control unit 680 determines that the power switch 810 is operated in the second mode when a low signal is continuously input to the fourth pin 4 for longer than a set time, and the fourth pin When input to (4), it is determined that the power switch 810 is operated in the first mode.

When it is detected that the power switch 810 is operated in the first mode, the control unit 680 performs power on/off control for the first function unit F1, and accordingly, for the first function unit F1. The power supply is stopped (S151). As a result, the portable device 50 enters a power-off mode. At this time, the first function unit F1 is turned off, the second function unit F2 is kept on, and the first switching element 820 is also kept on, and thus power to the control unit 680 is maintained. Supply remains the same.

Unlike this, when it is detected that the power switch 810 is operated in the second mode, the control unit 680 determines whether external power is connected to the power supply unit 840 (S160). If external power is connected to the power supply unit 840, the control unit 680 ignores the signal transmitted from the power switch 810 (S161). Accordingly, the portable device 50 maintains the operating state of the first functional unit F1 as it is.

The operation of the second mode of the power switch 810 is for changing the states of the power supply controller 800 and the portable device 50 to a sleep mode. When the portable device 50 enters the sleep mode, the first switching device 820 is turned off, and thus the connection between the power supply 840 and the battery 560 is disconnected.

In this way, when the first switching device 820 is turned off in a state in which external power is supplied through the power supply unit 840, the operation of the control unit 680 by the external power and the first function unit F1 by its control Although the operation of the battery 560 can be continued, it becomes a very inefficient state in which only the charging of the battery 560 cannot be performed.

Considering this point, when the power switch 810 is operated in the second mode while the external power is connected to the power supply unit 840, the controller 680 ignores the second mode signal, and the portable device ( 50) controls the first function unit F1 to maintain the operating state as it is.

If no external power is connected to the power supply unit 840, as shown in FIGS. 11, 14, and 15, the control unit 680 operates the first switching device 820 and the second switching device 830. is turned off (S170), and the operation of the power supply controller 800 is controlled so that the states of the power supply controller 800 and the portable device 50 are changed to a sleep mode (S180). When such control is performed, the states of the power supply controller 800 and the portable device 50 are changed to the sleep mode, and the first function unit F1 and the second function unit F2 and the entire control unit 680 are changed. The supply of power to the furnace is stopped, and accordingly, the entire portable device 50 including the first function unit F1 and the second function unit F2 and the control unit 680 is turned off.

The operation of the power supply controller 800 related to entering the sleep mode is as follows.

When the low signal transmitted through the power switch 810 is continuously received by the fourth pin 4 of the control unit 680 for more than a set time, the control unit 680 operates the power switch 810 in the second mode through this recognized as being

In this way, when the controller 680 recognizes the operation of the second mode of the power switch 810, the power of the controller 680 is turned off. When power of the control unit 680 is turned off, a low signal is transmitted through the first pin 1 of the control unit 680, and accordingly, the second switching element 830 is turned off.

When the second switching element 830 is turned off, the electrical connection between the second path (b) and the second ground 835 is disconnected. At this time, since the second path (b) is connected to the battery 560 by the connection part 870 and the second path (b) is not connected to any ground, the contact 5 on the second path (b) ) becomes high.

As the contact 5 on the second path (b) becomes high in this way, a high signal is input to the gate (G), and accordingly, the first switching element 820 is turned off. As the first switching element 820 is turned off, electricity between the battery 560 and the entire configuration of the portable device 50 including the first functional unit F1, the second functional unit F2, and the control unit 680 The hostile connection is broken.

Accordingly, power of the entire portable device 50 including the first function unit F1 and the second function unit F2 and the control unit 680 is turned off, and the state of the portable device 50 is changed to a sleep mode.

In this sleep mode state, the electrical connection between components such as the first functional unit F1 and the second functional unit F2 constituting the portable device 50 and the battery 560 is completely cut off, so that the battery 560 There is almost no amount of current leaking from the portable device 50.

Therefore, when the state of the portable device 50 is changed to the sleep mode as described above, the remaining amount of the battery 560 can be effectively maintained for a long time, even if the power of the portable device 50 is turned on again after a long time has passed. It is possible to maintain the state of the portable device 50 in a state in which it can be operated immediately.

That is, if the portable device 50 is set to the sleep mode when not in use for a long period of time, the portable device 50 can be in a usable state as soon as the power is turned on even after a long time has elapsed.

In addition, if the portable device 50 is set in the sleep mode when the product is shipped, even if the product is purchased after a long time, the portable device 50 can be in a usable state immediately when the user turns on the power.

In particular, according to the power supply controller 800 of this embodiment, the power is turned on/off without removing the battery 560 from the portable device 50 or adding a separate switch for setting the sleep mode. The sleep mode can be set only by manipulating the power switch 810 for manipulation.

This power supply control device 800 can be applied to a portable device 50 having a built-in battery 560, and various problems caused by the arrangement of several switches in the portable device 50, that is, a separate switch It is possible to solve the problem of securing space required for addition, the risk of erroneous operation due to the narrowing of the distance between switches, and the difficulty of maintaining a simple appearance of the portable device 50 due to exposure of several switches.

As described above, when the portable device 50 is in the sleep mode and the sleep mode is to be released, as shown in FIGS. 16, 17 and 19, the power button 592 is pressed (S210). ), and turn on the power switch 810 (S220).

When the power switch 810 is turned on, a connection is made between the second path (b) and the first ground 815, and accordingly, the gate (G) of the first switching element 820 connected to the second path (b) A low signal is input to

As a result, the first switching element 820 is turned on, and an electrical connection is made between the battery 560 and the control unit 680 through the third path (c) (S230), whereby power is supplied to the control unit 680. will lose That is, when the power switch 810 is turned on, the first switching element 820 is turned on, and power from the battery 560 is supplied to the control unit 680, and the control unit 680 is driven with the power supplied from the battery 560. It can be.

In this way, the control unit 680, which has been driven while the power is turned off, determines whether external power is connected to the power supply unit 840 (S240).

If external power is not connected to the power supply unit 840, the control unit 680 checks the remaining amount of the battery 560 (S250), and the remaining amount of the battery 560 is determined by the first function unit F1 and the second function unit F1. If it is determined that it is not sufficient to operate the second function unit F2, the controller 680 returns the power supply controller 800 and the portable device 50 to the sleep mode again.

Returning to the sleep mode may be started by turning off the power of the control unit 680 again, and a process after the power of the control unit 680 is turned off may be performed in the same manner as when entering the sleep mode.

If it is determined that the remaining amount of the battery 560 is sufficient to operate the first function unit F1 and the second function unit F2, as shown in FIGS. 18 and 20 , the controller 680 first A high signal is transmitted through the pin 1, and accordingly, the second switching device 830 is turned on (S260).

As such, when the second switching element 830 is turned on and maintained, the first switching element 820 is in an on state even when the power switch 810 is turned off by releasing the user's hand from the power button 592. may be maintained (S270).

Specifically, when the second switching element 830 maintains an on state, the second path (b) is connected to the second ground 835. Accordingly, the contact 5 on the second path (b) maintains a low state. Also, the first switching device 820 maintains an on state as the low signal input to the gate G is maintained.

In this state, even if the power switch 810 is turned off by releasing the user's hand from the power button 592, the on state of the first switching element 820 can be maintained. ) operation alone, the sleep mode is released, and power from the battery 560 can be supplied to all functional units F1 and F2 constituting the portable device 50 (S280).

The circuit configuration of the power supply regulator 800 performing the sleep mode release operation as described above has the following significance.

According to the circuit configuration of the power supply control device 800 as described above, even when the power of the control unit 680 is turned off and the electrical connection between the control unit 680 and the battery 560 is completely disconnected, the power button 592 Driving of the control unit 680 may be resumed only by manipulation.

In the conventional case, in order to return to a state in which the battery can be discharged, charging must be performed through connection terminals exposed to the outside. In this way, power necessary for driving the control unit, which is also disconnected electrically from the battery, can be supplied to the control unit in a state in which the power is turned off.

Otherwise, a separate switch for separately regulating only the connection between the battery and the device must be provided in the portable device separately from the power switch. In this structure, the connection between the battery and the controller is made only through the operation of such a separate switch, and through this, power necessary for driving the controller can be supplied to the controller.

In contrast, according to the circuit configuration of the power supply control device 800 of this embodiment, the operation of the control unit 680 can be resumed only by manipulating the power button 592, and through this, the functional units F1 and F2 operate again. The state of the portable device 50 may be returned to a state in which power may be supplied from the battery 560 or in a state in which the battery 560 may be charged, or in an operable state.

The portable device 50 of this embodiment having such a power supply control device 800 does not need to be supplied with external power to return to an operable state from a sleep mode, and needs to separately provide a connection terminal for charging. In addition, there is no need to provide a separate switch to separately regulate only whether or not the battery is connected to the device.

That is, the portable device 50 of the present embodiment can easily and quickly enter a sleep mode or return to an operable state only by manipulating the power button 592 provided for power on/off control.

The portable device 50 of this embodiment can provide a power cut-off function capable of reducing battery consumption in the power-off state of the portable device 50 having a built-in battery 560, and without a separate power supply. It is possible to provide further improved usability by enabling the switching from the cut-off state to the power-supply state.

In addition, the portable device 50 of this embodiment, without adding a separate connection terminal for charging or a separate switch for separately controlling only whether the battery and the device are connected, is in a power-off state (sleep mode) and a power-supply state (operating state). possible state) can be easily and quickly made, it is possible to prevent problems such as an increase in product size due to an increase in switches and an increase in the risk of erroneous operation of switches, and a simple and beautiful appearance to enhance user satisfaction. can provide.

In addition, the portable device 50 of the present embodiment can arbitrarily block battery discharge and maintain the battery level of the portable device at a certain level or higher even after a considerable amount of time has elapsed after product shipment, further improving consumer satisfaction. There are advantages to doing so.

Meanwhile, as shown in FIG. 21 , when external power is connected to the power supply unit 840 while the power supply controller 800 and the portable device 50 are in the sleep mode, the external power is supplied to the control unit 680. It is supplied and driving of the control unit 680 can be started.

In this way, the control unit 680, which has been driven while the power is off, detects that external power is connected to the power supply unit 840, and turns on the first switching element 820.

At this time, the on/off control of the first switching element 820 may be performed by the on/off control of the second switching element 830 of the control unit 680, and a detailed description of this has been described above, so here to omit

As shown in FIG. 22 , when the first switching device 820 is maintained in an on state, the battery 560 may be charged by an external power source connected to the power supply unit 840 . At this time, the controller 680 may detect the voltage of the battery 560, and through this, control the amount of charge of the battery 560 to an appropriate level.

The present invention has been described with reference to the embodiments shown in the drawings, but this is only exemplary, and those skilled in the art can make various modifications and equivalent other embodiments. will understand Therefore, the true technical protection scope of the present invention should be determined by the claims below.

40: mobile terminal
50: portable device
510: front panel
520: case
530: fan cover
540: upper fan assembly
545: lower fan assembly
550: filter module
560: battery
570: rear panel
580: rear cover
590: Sub PCB
592: power button
593: wind direction control button
595: Main PCB
596: main board
597: element
600: sensor module
650: wireless communication unit
651: short-distance communication module
653: mobile communication module
655: location information module
660: output unit
670: memory unit
680: control unit
800: power supply regulator
810: power switch
815: first ground
820: first switching element
830: second switching element
835: second ground
840: power supply
845: battery voltage detection unit
850: external power detection unit
860: resistor
870: connection part
880: Converter
890: noise filter

Claims (21)

A power switch provided to be operable in the first mode or the second mode;
a controller electrically connected to one side of the power switch through a first path;
a first switching element electrically connected to one side of the power switch through a second path; and
A battery electrically connected to the control unit through a third path; includes,
The first switching element is disposed on the third path to control shorting of the third path;
When the power switch is operated in the first mode while the first switching element is on, the controller recognizes that the power switch is operated in the first mode through the first path and controls the device on/off. ,
When the power switch is operated in the second mode while the first switching element is on, the control unit recognizes that the power switch is operated in the second mode through the first path and turns off the first switching element. power supply regulator.
According to claim 1,
In the first switching element, a gate is electrically connected to one side of the power switch through the second path, a source is electrically connected to the battery through the third path, and a drain is electrically connected to the control unit through the third path. Power supply control device comprising a MOS-FET switching element electrically connected to.
According to claim 1,
When one side and the other side of the power switch are connected for less than a set time, the power switch operates in the first mode,
When one side and the other side of the power switch are connected for more than a set time, the power switch operates in the second mode.
According to claim 3,
A resistor disposed between the controller and one side of the power switch and connected to the controller through the first path;
The control unit determines a connection time between one side and the other side of the power switch by measuring a time when no voltage is applied to the resistor.
According to claim 1,
The power supply control device further comprising a power supply unit receiving power from an external power source and supplying the received power to at least one of the battery and the control unit.
According to claim 5,
Power supply control device further comprising an external power detection unit for detecting whether or not power is supplied to the power supply unit.
According to claim 6,
Wherein the control unit does not turn off the first switching element even if the power switch is operated in the second mode when the supply of power to the power supply unit is detected by the external power detection unit.
According to claim 6,
The control unit turns on the first switching element when the external power detection unit detects power supply to the power supply unit while the first switching element is off.
According to claim 8,
The power supply unit is electrically connected to the control unit through the third path,
The control unit operates by receiving power from the power supply unit through the third path.
According to claim 5,
The power supply unit is electrically connected to the battery via the first switching element through the third path,
The battery is charged by receiving power from the power supply unit through the third path.
According to claim 5,
A power supply control device further comprising a converter for converting the power supplied through the power supply unit into a direct current form.
A power switch provided to be operable in the first mode or the second mode;
a controller electrically connected to one side of the power switch through a first path;
a first switching element electrically connected to one side of the power switch through a second path; and
A battery electrically connected to the control unit through a third path; includes,
The first switching element is disposed on the third path to control shorting of the third path;
When the power switch is operated while the first switching element is on, the control unit recognizes that the power switch is operated through the first path and turns off the first switching element;
When the power switch is operated while the first switching element is off, the first switching element is turned on through the second path and the power of the battery is supplied to the control unit through a third path.
According to claim 12,
The first switching device includes a MOS-FET switching device having a gate electrically connected to one side of the power switch through the second path.
According to claim 13,
The other side of the power switch is connected to a first ground,
When the power switch is operated while the first switching element is off, the gate is connected to the other side of the power switch and the first switching element is turned on.
According to claim 14,
Further comprising a connection portion electrically connecting the battery and the second path, and a second switching element for controlling a fourth path connecting the second path and a second ground,
When the power switch is operated in the second mode while the first switching element is on, the controller turns off the second switching element so that the second path is separated from the second ground;
When the power switch is operated while the first switching element is off, the control unit turns on the second switching element so that the second path is connected to the second ground.
According to claim 15,
When the second switching element is turned off, the voltage of the battery is applied to the gate through the connection part and the second path, so that the first switching element is maintained in an off state,
When the second switching element is turned on, the gate is connected to the second ground through the second path and the fourth path, so that the first switching element remains turned on.
The power supply control device according to any one of claims 1 to 16; and
A portable device comprising a first function unit that receives power from the power supply regulator, performs a first function, and is controlled on/off by the control unit.
According to claim 17,
Further comprising a second functional unit provided for communication between an external device and the portable device;
When the power switch is operated in the first mode while the first switching element is on, the controller controls on/off of only the first function unit except for the second function unit.
According to claim 18,
The second functional unit includes at least one of a Bluetooth communication module, an NFC communication module, an LTE communication module, a Wi-Fi communication module, and a GPS.
According to claim 18,
The portable device includes a case and a filter module mounted inside the case,
The first function unit includes a fan assembly that generates a flow of air from outside the case passing through the filter module.
According to claim 20,
The first functional unit further includes a sensor module,
The sensor module is a portable device comprising a sensor for detecting air quality.

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