DRYER ACCESSORY AND DRYER

Description

CROSS REFERENCE TO RELATED APPLICATIONS

This application is the National Phase of PCT International Application No. PCT/KR2022/008849, filed on Jun. 22, 2022, all of which is hereby expressly incorporated by reference into the present application.

TECHNICAL FIELD The present disclosure relates to a dryer accessory and a dryer.

BACKGROUND

Generally, a laundry treating apparatus may include a washing machine, a dryer, a styler, and the like, and the washing machine may have a drying function.

The dryers are categorized into an exhaust-type dryer and a circulation-type dryer, which both heat air with a heater to produce hot air and dry laundry by exposing hot air to the laundry.

In the washing machine, an administration time may be determined simply based on a washing course and a weight of the laundry loaded into a drum, but in the dryer, not only a drying course and the weight of the laundry but also a degree of wetness of the laundry may affect the administration time.

Therefore, humidity of the laundry should be accurately measured, but because the drum rotates, it is difficult to install a temperature sensor and a humidity sensor inside the drum. Therefore, the humidity sensor or the temperature sensor may be installed in a cabinet or a duct to measure the humidity or a temperature. However, this external placement results in a temperature discrepancy between the sensor and the laundry within the drum and inaccurate measurement of the actual degree of wetness of the laundry.

In particular, when a volume of the laundry is great, the accuracy of measurement decreases, and when the volume is too small, the laundry does not reach the humidity sensor, which also results in the decrease in the accuracy.

SUMMARY

Technical Problem

The present disclosure is to provide an accessory that may sense humidity and temperature of laundry without separate battery replacement and charging.

Technical Solutions

Provided is a dryer accessory including a housing including a sensor hole, a sensor module that is located inside the sensor hole of the housing and measures at least one of temperature and humidity, an energy harvesting module that is located inside the housing and generates current based on a movement of the housing, a wireless communication module that transmits the at least one of the temperature and the humidity measured by the sensor module, and a controller that controls the sensor module and the wireless communication module using energy generated by the energy harvesting moduleunit.

The energy harvesting moduleunit may include a pipe extending in one direction, a magnet positioned inside the pipe, and a coil wound on an outer surface of the pipe, and when the magnet moves in the extension direction of the pipe as the housing moves, the current may be generated in the coil.

The magnet may have a cylindrical shape with a diameter smaller than an inner diameter of the pipe.

The energy harvesting moduleunit may include a pipe extending in one direction, a weight positioned inside the pipe, and a piezo disk positioned at an end of the pipe, and when the weight collides with the piezo disk, the current may be generated in the piezo disk.

The controller may include a main board located inside the housing, and the pipe may extend through the main board.

The pipe may extend vertically to the main board, wherein the pipe may include a plurality of pipes arranged along a circumference of the main board.

The controller may include a rectifier that converts AC power generated from the energy harvesting module into DC power, a capacitor that stores energy converted into the DC power, and an analog-to-digital converter that deactivates the sensor module and the wireless communication module until an amount of the energy converted into DC power becomes sufficient to operate the sensor module and the wireless communication module.

The dryer accessory may further include a cylindrical rubber plug positioned between the sensor module and the sensor hole, and a waterproof filter formed at a location of the rubber plug adjacent to the sensor hole, wherein the waterproof filter does not allow liquid to pass therethrough.

The sensor hole and the sensor module may respectively include a pair of sensor holes and a pair of sensor modules disposed at opposite sides of the housing.

The housing may contain an elastic material.

The housing may have a spherical shape.

A dryer for drying laundry includes a cabinet forming an outer appearance of the dryer, a drum rotatably disposed in the cabinet to accommodate the laundry therein, a driver that rotates the drum, a hot air supply that is in communication with the drum and supplies high-temperature air into the drum, a collector in communication with the hot air supply to collect water formed by condensation of moisture discharged from the drum, a wireless communication module that transmits and receives state information of the dryer, and a controller that controls the driver, the hot air supply, and the wireless communication module, the wireless communication module receives at least one of humidity information and temperature information provided by a dryer accessory inserted into the drum, and the controller controls the driver and the hot air supply using the at least one of the humidity information and the temperature information.

The controller may terminate operations of the driver and the hot air supply when the temperature information and the humidity information reach a reference value.

The dryer may further include at least one of a temperature sensor and a humidity sensor located inside the cabinet, and the controller may deactivate the at least one of the temperature sensor and the humidity sensor when there is the temperature information or the humidity information received from the dryer accessory.

Advantageous Effects

According to the present disclosure, the temperature and the humidity of the laundry may be accurately measured via the dryer accessory.

In addition, according to the present disclosure, the dryer accessory may be used continuously without the separate battery replacement, so that the maintenance thereof may be easy and the damage to the product resulted from the poor waterproof function may be prevented.

Additional scope of applicability of the present disclosure will become apparent from the detailed description below. However, because various changes and modifications within the spirit and scope of the present disclosure will be clearly understood by those skilled in the art, it should be understood that the detailed description and specific embodiments such as preferred embodiments of the present disclosure are given only as examples.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a view showing a dryer according to an embodiment of the present disclosure.

FIG. 2 shows an internal structure of the dryer 10 of the present disclosure.

FIG. 3 is a view showing a method for inserting a dryer accessory of the present disclosure into a dryer.

FIG. 4 is a conceptual diagram showing a wireless communication flow between a dryer, a cloud server, and a user terminal of the present disclosure.

FIG. 5 is an exploded view according to an embodiment of a dryer accessory of the present disclosure.

FIG. 6 is a cross-sectional view according to an embodiment of a dryer accessory of the present disclosure showing a sensor module.

FIG. 7 is a view showing an energy harvesting module according to an embodiment of a dryer accessory of the present disclosure.

FIGS. 8 and 9 are diagrams for illustrating a principle of energy harvesting according to an embodiment of a dryer accessory of the present disclosure.

FIG. 10 is a view showing a controller of a dryer accessory of the present disclosure.

BEST MODE

Hereinafter, embodiments disclosed herein will be described in detail with reference to the attached drawings. In the present document, the same or similar reference numerals are assigned to the same or similar components even in different embodiments, and a description thereof is replaced with the first description. As used herein, singular expressions include plural expressions unless the context clearly dictates otherwise. Additionally, in describing the embodiments disclosed herein, when it is determined that detailed descriptions of related known technologies may obscure the gist of the embodiments disclosed herein, the detailed descriptions will be omitted. In addition, it should be noted that the attached drawings are only for easy understanding of the embodiments disclosed herein and should not be construed as limiting the technical idea disclosed herein.

A dryer 10 of the present disclosure may be equipped as one of a washing machine that may dry laundry, a dryer that dries the laundry, and a styler that may prevent wrinkles and removing odors from the laundry.

A following description is based on the dryer 10 being equipped as the dryer, but this is merely an embodiment and does not exclude the dryer 10 being equipped as the washing machine or the styler.

FIG. 1 shows an outer appearance of the dryer 10 of the present disclosure.

The dryer 10 of the present disclosure may include a cabinet 100 forming the outer appearance thereof, a control panel 120 coupled to the cabinet to input an operation command or display a state, a door 150 pivotably coupled to a front portion of the cabinet 100 to open and close a cabinet inlet through which the laundry is introduced, and a condensate accommodation container 110 where condensate is collected.

The control panel 120 may be coupled to an upper end of the cabinet 100, may include therein a controller P including a microcomputer that controls the dryer, and may include a display 121 that displays the state of the dryer and an input unit that inputs a command to the controller.

The display 121 may be formed as a display screen such as an LCD or an LED, and may also be formed as a touch panel that may receive the command. The display 121 may accurately convey information on the dryer to a user by externally displaying an operating state and an abnormal state of the dryer. In addition, the display 121 may further include a speaker so as to emit an alarm sound to the user.

The input unit may be formed as a rotary knob 122 to allow selection of an arbitrary drying course or option of the dryer. In addition, the input unit may include a power input unit 140 for supplying power to the dryer, and a command input unit 130 for inputting a separate control command.

The power input unit 140 and the command input unit 130 may be formed as physical buttons so that the command may be transmitted even when power is not supplied to the display 121.

In this regard, the command input unit 130 may include a defrosting command input unit that transmits a defrosting command to the controller of the control panel 120 when the dryer 10 is frozen.

The door 150 may be pivotably disposed at the front portion of the cabinet 100, and may be made of a transparent material such that the cabinet inlet defined in the cabinet may be seen through.

The door 150 may have a handle 151 at one side, and may be coupled with a hinge 152 at the other side to open and close the cabinet inlet of the cabinet.

FIG. 1 discloses the front-load type dryer with the door 150 disposed at the front, but a top-load type dryer with the door 150 disposed at the top is not excluded.

FIG. 2 shows an internal structure of the dryer 10 of the present disclosure.

The dryer 10 of the present disclosure may include a drum 200 rotatably disposed inside the cabinet 100 to accommodate the laundry therein, a driver 300 that rotates the drum 200, a hot air supply 400 that is in communication with the drum and supplies high-temperature air (hot air) into the drum, and a base 500 in which the hot air supply 400 is supported or installed.

The drum 200 may include a drum inlet 220 that is in communication with the cabinet inlet of the cabinet 100 and allows the laundry to be introduced and withdrawn therethrough, may be formed in a cylindrical shape that accommodates the laundry therein, and may include a lifter 210 that may raise and lower the laundry in a vertical direction to stir the laundry.

In one example, the dryer 10 of the present disclosure may further include a gasket 230 that prevents the laundry from being withdrawn to a space between the cabinet inlet of the cabinet 100 and the drum inlet 220 of the drum 200.

The hot air supply 400 may include a discharge duct 411 that is in communication with one side of the drum 200 so that moisture in the laundry and air that has passed through the laundry are discharged from the drum 200, a heat pump 420 that cools air that has passed through the discharge duct 411 to remove moisture therefrom and reheat air, and a suction duct 412 that sucks air that has passed through the heat pump back into the drum 200.

The gasket 230 may include a duct connection hole 231 that is in communication with the suction duct 412.

The heat pump 420 may include an evaporator 422 that cools air that has passed through the discharge duct 411, a compressor 421 that compresses and heats a refrigerant that has passed through the evaporator, a condenser 423 that heats air with the refrigerant that has passed through the compressor 421 to generate high-temperature dry hot air, and an expansion valve 424 that expands the refrigerant that has passed through the condenser 423 to reduce a temperature.

In one example, the base 500 may support the heat pump 420 while forming a bottom surface of the dryer 10.

The base 500 may have one end in communication with the discharge duct 411 and the other end in communication with the suction duct 412, and may have the heat pump 420 installed therein and allow air to pass therethrough. Accordingly, water condensed in the evaporator 422 may be collected in the base 500, and a drainage pump 430 for discharging the collected water may be installed in the base 500.

Specifically, a collector 534 where the condensate is collected may be disposed at a lower portion of the base 500, and the drainage pump 430 may drain the condensate in the collector 534. In addition, the drainage pump 430 may be equipped to transfer collected water to the condensate accommodation container 110, and the condensate accommodation container 110 and the drainage pump 430 may be connected to each other via an accommodation pipe 111. Thus, when a certain level of condensate is collected in the base 500, condensate may be transferred to the condensate accommodation container 110, and collected condensate may be removed by extending the condensate accommodation container 110.

In one example, the driver 300 may rotate the drum 200. The driver 300 may include a driving motor 310 that provides power to rotate the drum 200, a driving rotation shaft 320 that rotates by extending through the driving motor 310, a pulley 330 that is coupled to one end of the driving rotation shaft 320, and a belt 340 that is formed as a closed curve connecting the pulley 330 with an outer circumferential surface of the drum 200.

In one example, the driver 300 may further include a blower fan 425 that is coupled to the other end of the driving rotation shaft 320 and provides power to circulate air inside the hot air supply 400 and the drum 200.

The blower fan 425 may be installed in the hot air supply 400 or installed in a location of the base 500 that is in communication with the hot air supply 400 to circulate air in the drum 200 and the hot air supply 400.

Accordingly, when the driving motor 310 operates, the drum 200 may rotate, and at the same time, the blower fan 425 may also circulate air in the drum 200.

The blower fan 425 may cause air inside the drum 200 to pass through the discharge duct 411 in a direction I, then pass through the base 500 and the hot air supply 400, and then flow into the suction duct 412 in a direction II.

In one example, the dryer 10 of the present disclosure may be equipped with a temperature sensor S1 that senses a temperature of air that has passed through the drum 200 or the hot air supply 400. The temperature sensor S1 may be disposed in the hot air supply 400. For example, the temperature sensor S1 may be disposed in the suction duct 412. The temperature sensor S1 disposed in the suction duct 412 may sense a temperature change of air that has passed through the condenser 423. Accordingly, not only a temperature change of air inside the drum 200, but also a dried state of the laundry and an operating state of the heat pump 420 may be comprehensively checked via the temperature sensor S1.

A humidity sensor S2, as a device for measuring residual moisture of the laundry, may accurately identify the dried state of the laundry only when it comes into direct contact with the laundry. Because the drum rotates, when an electronic component is installed on an inner wall of the drum, there are problems such as wiring, so that the humidity sensor may be disposed on an inner surface of a lower portion of the gasket 230 of the drum inlet.

However, also in this case, only humidity of laundry located at a front side may be measured, and when there are many pieces of laundry, it is difficult to determine a dryness level of a clumped portion.

The temperature sensor is an important factor in determining the humidity, and it is difficult for the temperature sensor S1 located in the suction duct or the discharge duct to accurately measure the humidity because of a difference from a temperature of the laundry itself.

Therefore, the present disclosure uses a separate dryer accessory 600 equipped with a sensor module 621 that may measure the humidity, for more accurate humidity measurement. The sensor module 621 may additionally be equipped with a temperature sensor to measure the temperature as well as the humidity.

FIG. 3 is a view showing a method for inserting a dryer accessory of the present disclosure into a dryer. The dryer accessory 600 of the present disclosure is inserted into the dryer drum and is located inside the drum together with the laundry. Because the dryer accessory 600 is located inside the drum and is able to be in direct contact with the laundry, the accurate temperature and humidity sensing becomes available.

A ball dryer accessory 600 inserted into the dryer drum may not necessarily have a ball shape, but may have a spherical shape to rotate with the rotation of the drum and minimize friction with the laundry.

The dryer accessory 600 prevents the pieces of laundry from tangling with each other when rotating in the drum and has an excellent dust removal effect by tapping the laundry. clothes. The dryer accessory 600 creates a space between the pieces of laundry to improve a drying effect and shorten a drying time, resulting in an energy saving effect.

Furthermore, the dryer accessory 600 of the present disclosure may assist the function of the dryer by including a humidity sensor in addition to the physical action described above. In addition to the humidity sensor, a temperature sensor may also be disposed, and the dryer accessory 600 may collect accurate humidity information and temperature information by being in direct contact with the laundry.

FIG. 4 is a conceptual diagram showing a wireless communication flow between a dryer, a cloud server, and a user terminal of the present disclosure.

The temperature information and the humidity information collected from the dryer accessory may be transmitted to the dryer via a wireless communication unit to adjust an administration time of the dryer. When the dryer is equipped with an IOT function, the wireless communication unit of the dryer may transmit the temperature information and the humidity information to a cloud server 20 and retransmit them to a user's terminal 30.

FIG. 5 is an exploded view according to an embodiment of a dryer accessory 600 of the present disclosure, and FIG. 6 is a cross-sectional view according to an embodiment of a dryer accessory 600 of the present disclosure showing a sensor module 621.

The dryer accessory 600 of the present disclosure includes a housing 610 having a space for mounting an electronic component therein. The internal space of the housing 610 may define a groove corresponding to a shape of the electronic component, so that an electronic module 630 may be fixed without moving inside the housing 610.

The electronic component of the present embodiment is formed to have a cylindrical shape as shown in FIG. 5, and the internal space in the cylindrical shape may also be included inside the housing 610.

The housing 610 may have a spherical shape so as to roll freely inside the drum, and may use a soft and elastic material such as silicone or rubber. A heavy material may be used rather than a light material so as to move a lot by a centrifugal force when the drum rotates.

The dryer accessory of the present disclosure does not require battery replacement or charging, so that a pair of hemispherical housings 611 and 612 may be joined to each other to implement the single spherical housing 610.

The housing has a sensor hole 613 defined therein such that air is supplied to the humidity sensor and the temperature sensor. For more accurate sensing, a pair of sensor holes of the present disclosure may be defined at opposite sides of the housing, and the sensor module 621 may be disposed at each side.

The sensor hole 613 may be covered with a waterproof material such that air is supplied to the sensor module 621, but moisture is prevented from penetrating the sensor hole 613 and damaging the electronic module 630. Gore-Tex 627 may be used as the waterproof material, and a cylindrical rubber plug 625 with the Gore-Tex 627 attached to one side may be disposed between the sensor hole 613 and the sensor module 621.

The sensor module 621 may include not only the humidity sensor but also the temperature sensor, and may measure humidity and temperature of air introduced via the Gore-Tex and transmit them to the controller.

The dryer accessory 600 requires power to operate the sensor module 621 and operate the wireless communication unit for transmitting data collected from the sensor module 621 to the dryer. When the dryer accessory 600 includes a battery for the power, the housing 610 should be opened to charge or replace the battery. In this case, when a waterproof performance is deteriorated or a damage occurs, it may cause a defect in the dryer accessory 600, so that the dryer accessory 600 of the present disclosure may be supplied with the power using an energy harvesting technology.

The electronic module 630 mounted inside the housing 610 may be equipped with a controller 650 for control and an energy harvesting module 640 for generating the power. In the present embodiment, the electronic module 630 is formed in a cylindrical shape and the sensor modules 621 are respectively disposed on top and bottom surfaces of the cylinder, but there is no limitation on the shape of the electronic module 630 and thus a hexahedral shape or other shapes may be applied.

FIG. 7 is a view showing an electronic module 630 according to an embodiment of a dryer accessory 600 of the present disclosure. The electronic module 630 may include the energy harvesting module 640, the controller 650, and the sensor module 621.

The electronic module 630 may have a frame to fix each component, and may include a top surface and a bottom surface 633 where the sensor modules 621 are respectively located, and a side surface 631 constituting a side surface circumference of the cylinder.

The side surface may be omitted as shown in FIG. 7, but the cylindrical side surface 631 as shown in FIG. 5 may be further included for rigidity. A material and a volume of the frame may be designed differently to adjust a weight of the dryer accessory 600.

The energy harvesting is a technology that harvests small energy that is usually wasted or unused and converts the energy into usable electrical energy, and is composed of a converter that converts the wasted energy into the electrical energy and a collector that accumulates the electrical energy.

There are following types of energy harvesting technologies.

Body energy harvesting is a method that uses body heat, static electricity, kinetic energy, and the like generated via a body movement. Photon energy harvesting is a method that uses sunlight, and thermal energy harvesting is a method that uses a large amount of waste heat generated in industrial sites. Because this method requires a great temperature difference, it is good for use in places where high-temperature heat is generated, such as the industrial sites.

Electromagnetic energy harvesting is a method that uses electromagnetic energy such as radio waves or mobile phone waves.

Vibration energy harvesting is a method that generates electricity by applying a vibration or a pressure to a piezoelectric element, and uses a polarization effect of the piezoelectric element. The piezoelectric element may generate electrical energy by utilizing a phenomenon of the electricity being generated on a surface of crystal such as quartz or tourmaline. The electricity is generated even with a small pressure, so that the piezoelectric element may be used as a pressure sensor. Further, when a great impact is applied, a large amount of electricity is generated, which may be used with the energy harvesting technology.

Potential energy harvesting is a method that utilizes a potential energy difference occurring in a water discharge outlet of a hydroelectric power plant and a cooling water discharge channel of a thermal power plant, and requires a large facility.

As the drum rotates, a location of the dryer accessory may change, and potential energy thereof may change. However, to obtain electric energy of a level to be actually used, the change in the potential energy should be as great as that of a waterfall, making it difficult to apply the potential energy harvesting.

To implement the energy harvesting by utilizing a small change in the location, current may be generated using the principle of electromagnetic induction. When a magnet 645 is disposed inside the dryer accessory 600 while the dryer accessory 600 moves inside the drum, a magnetic field may be formed as the magnet 645 moves. Further, when a coil 643 is disposed in a movement path of the magnet 645, the current may be generated in the coil 643 and utilized as energy.

FIG. 8 is a view for illustrating a principle of electromagnetic energy harvesting according to an embodiment of a dryer accessory of the present disclosure.

As shown in FIG. 8, a pipe extending in one direction, a magnet 645 located inside the pipe 641, and a coil 643 wound on an outer surface of the pipe 641 may be included. When the magnet 645 moves inside the pipe based on the movement of the dryer accessory 600, the current flows in the coil 643. A cylindrical magnet 645 having a diameter corresponding to a diameter of the pipe may be used such that polarity of the magnet 645 does not change.

Because the dryer accessory 600 rotates while changing a vertical orientation thereof, the magnet 645 may continuously generate the current while moving along the pipe.

A single electromagnetic energy harvesting module 640 may be composed of the pipe, the magnet, and the coil 643, a plurality of electromagnetic energy harvesting modules 640 may be disposed as shown in FIG. 7, and the plurality of electromagnetic energy harvesting modules 640 may be arranged as far apart as possible so as not to affect neighboring units.

In the present embodiment, it is shown that there are four electromagnetic energy harvesting modules 640, but the number of electromagnetic energy harvesting modules 640 may be equal to or greater than or equal to or smaller than four. Both ends of the pipe may be fixed by top and bottom surfaces 633 of a disk shape, and a main board as a controller may be located in the middle of the pipes.

In addition to the energy harvesting technology using the electromagnetic energy, the vibration energy harvesting technology may be used. The dryer accessory moves inside the drum, but it is not easy for a great impact to be directly applied by the laundry inside the drum.

Instead, a weight may be placed inside the housing, and a pressure may be applied to a piezo disk by utilizing a force of moving and colliding of the weight based on the movement and the rotation of the housing.

FIG. 9 is a view for illustrating an energy harvesting operation using a piezo disk according to an embodiment of a dryer accessory of the present disclosure.

The present disclosure may use the magnet used in the electromagnetic energy harvesting technology described above as the weight because it moves along the pipe. When the electromagnetic energy harvesting technology is not utilized, an energy harvesting module may be composed of the pipe with the coil omitted, the piezo disk, and the weight having a predetermined weight instead of the magnet.

When the magnet or the weight moves along the pipe 641 and collides with the piezo disk 647 located at an end of the pipe 641, electricity is generated in the piezo disk 647.

Energy collected as such may be utilized to control the sensor module 621 and the wireless communication module of the dryer accessory 600.

FIG. 10 is a view showing a controller of a dryer accessory of the present disclosure. (a) is a view showing a main board 651 located in the middle of the pipes. Holes 652 through which the respective pipes extend may be defined along a circumference of the disk-shaped main board 651 to maximize the spacing between the pipes.

An main chip 653 that controls the dryer accessory may be mounted in a middle space.

A flexible board 623 may be used to connect the sensor modules 621 located on the top and bottom surface frames with the main board 651. In addition to a signal of the sensor module 621, power collected from the piezo disk may also be transmitted to the flexible board 623.

The flexible board 623 is connected to a cable connector 654 of the main board 651, and the sensor modules 621 are located at both sides, so that the connectors 654 may be located at both sides of the main board 651.

(b) is a block diagram showing a configuration of an electronic module of a dryer accessory 600 of the present disclosure. The power collected from the electromagnetic energy harvesting module 640 and the piezo energy harvesting module 640 is energy collected in an analog manner, so that the current has an alternating current (AC) waveform. A rectifier 657 may be included to convert the waveform of the current into a direct current (DC) waveform. Because a voltage of the current that has passed through the rectifier 657 is different from a voltage used in the sensor module 621 or the wireless communication module 6532, a converter 655 for converting the voltage may be further included. The power that has passed through the converter 655 may be supplied to a micro controller unit (MCU), but because an amount of the power collected using the energy harvesting technology is small, the power should be collected in a certain amount to operate the sensor module 621 and the wireless communication module.

Therefore, the generated energy maybe accumulated using a capacitor 656, preferably a super capacitor. An analog-to-digital converter (ADC) 6535 of the MCU 6531 may activate the wireless communication module 6532 to operate only when the amount of power is equal to or greater than the certain amount.

In addition to the MCU_6531, a clock 6553 and a wireless communication module 6532 may be implemented together in a main chip 653. Because it is sufficient for the wireless communication module to be connected to the wireless communication unit of the dryer, a short-range wireless communication technology such as Bluetooth may be used.

In particular, the dryer accessory 600 may use Bluetooth low energy (BLE) 6532 that operates at low power because it uses the power collected via the energy harvesting technology.

The greatest feature of the Bluetooth low energy (BLE) is that a duty cycle is about several milliseconds (ms) and it is in a sleep mode most of the time, so that power consumption is very low. The Bluetooth low energy (BLE) uses a bandwidth of 2 MHz and supports a transmission speed of 1 Mbps, but an average transmission speed is equal to or lower than 200 kbps because of the short duty cycle.

The above detailed description should not be construed as limiting in all respects but should be considered as illustrative. The scope of the present disclosure should be determined by a reasonable interpretation of the appended claims, and all changes within the equivalent scope of the present disclosure are included in the scope of the present disclosure.