CN215308070U - Massage device - Google Patents

Abstract

The present invention relates to a massage device. The massage device includes: a suction port for sucking external air; an air supply part which sucks in external air through the suction inlet and moves the external air to the oxygen generation part; an oxygen generation unit that adsorbs nitrogen from the air supplied from the air supply unit and discharges concentrated oxygen; a flow path pipe for moving the concentrated oxygen from the oxygen generation part to the oxygen discharge port; and an oxygen discharge port for supplying the concentrated oxygen moved through the flow path pipe to a user.

Description

Massage device

Technical Field

The present invention relates to a massage device, and more particularly, to a massage device including an oxygen generator.

Background

Massage (massage) is a medical adjunctive therapy that applies mechanical stimulation of various types to a body part of a subject, such as kneading, pressing, stretching, beating, or moving a part of the body, to regulate the body changes of the subject, thereby contributing to blood circulation and relieving fatigue of the subject.

For economic and time reasons, there is an increasing demand for massage apparatuses or massage devices that provide an artificial massage function. That is, as the demand for relieving stiff muscles and eliminating fatigue or stress by massaging increases, various massage apparatuses have been introduced which are not time-and cost-effective. Any form of appliance, device or apparatus that massages by mechanical means without a separate masseur is referred to as a massage apparatus.

Recently, the increase of fine dusts caused by air pollution has reduced the chance of contacting fresh air not only in cities but also in suburbs. Thus, there are many cases where an air cleaner for purifying air is purchased. However, in the case of using the air purifier in a closed space, although the fine dust can be removed, there is a problem that the oxygen concentration is gradually decreased by the respiration of the user.

If the oxygen concentration is lowered, respiration is accelerated, the pulse rate is increased, and dizziness and vomiting may occur. In addition, if the oxygen concentration is significantly reduced, confusion may occur, and in the more serious case, death may occur. Therefore, ventilation is continuously performed to maintain a certain level of oxygen concentration even if the air purifier is used. However, when ventilation is performed, there is a problem that external fine dust flows into the room again.

In addition, when oxygen is sufficiently supplied into the human body, it is possible to improve mood, relieve fatigue, generate vitality, reduce stress, improve concentration, and maintain pleasant mood. In addition, the pillow also helps sleep, so that the pillow has the effect of refreshing and refreshing in the morning. Therefore, research into oxygen generators is being actively conducted.

As one method for realizing the oxygen generator, there is a membrane method. The principle of the membrane method is to utilize the selective separation characteristics of a hollow fiber membrane, a flat membrane, or the like, which is a polymer membrane. That is, the oxygen generation system uses a separation membrane (membrane) that can selectively separate oxygen in air. According to this method, it is possible to realize a simple apparatus and a low cost, but only low-purity oxygen gas of about 20% to 30% can be generated and a dew condensation phenomenon occurs, so that there is a problem such as mold.

The contents of the utility model

Means for solving the problems

The massage device according to the present invention comprises: an air duct for moving sucked external air to the clean air discharge port, a blowing fan inserted into an inside of a filter mounting part included in the air duct to move the external air to the clean air discharge port, a filter part inserted into an inside of the filter mounting part of the air duct for filtering foreign substances in the external air, a suction port cover covering the filter mounting part and coupled with the fragrance kit, and a discharge port cover coupled with the clean air discharge port.

The massage apparatus according to the present invention further comprises a control part for acquiring identification information of the fragrance kit and controlling the actuator or the air bag to provide a massage to the user based on a massage pattern according to the identification information; the identification information of the fragrance kit corresponds to a fragrance generating substance that generates a predetermined fragrance.

The massage apparatus according to the present invention is characterized in that the filter section includes a High Efficiency Particulate Air (HEPA) 14-grade Air filter.

According to the massage device of the present invention, the filter portion includes: a filter guide frame fixed to the blower fan for fixing the air filter, including at least one hole to enable external air passing through the air filter to flow to the blower fan, the air filter inserted into the inside of the filter guide frame for removing foreign substances from the external air, and a suction port cover guide for pressurizing at least a portion of the air filter to fix the air filter to the filter guide frame, fixed to the filter guide frame, and for engaging the suction port cover.

The massage apparatus according to the present invention further comprises: an air supply part which sucks in external air and moves the external air to an oxygen generation part, the oxygen generation part which adsorbs nitrogen from the external air supplied by the air supply part and discharges concentrated oxygen, and a pressure sensor which measures a gas pressure of an oxygen discharge chamber included in the oxygen generation part; the control section receives information on the gas pressure of the oxygen gas discharge chamber from the pressure sensor, and when the information on the gas pressure is less than or equal to a first threshold value and greater than a third threshold value, the control section outputs a signal indicating that the life of the zeolite contained in the oxygen gas generation section has been exhausted, the first threshold value being greater than the third threshold value.

According to the massage device of the present invention, the control section outputs a signal indicating that the oxygen generation section is malfunctioning when the information on the gas pressure is less than or equal to the third threshold value.

According to the massage device of the present invention, the oxygen generation unit generates gas containing 50% to 60% of oxygen in an amount of 2 liters per minute, and the gas generated by the oxygen generation unit is discharged through the oxygen discharge port.

According to the massage apparatus of the present invention, the discharge port cover is provided at the upper portion of the housing of the arm massage part, and the direction of air is determined by the blades included in the discharge port cover.

The massage apparatus according to the present invention further comprises a dust measuring sensor engaged with the discharge port cover for measuring fine dust in the outside air of the massage apparatus, the control part makes the blower fan not operate when the dust concentration measured by the dust measuring sensor is less than a predetermined first concentration, the control part makes the blower fan rotate at a first speed when the dust concentration measured by the dust measuring sensor is greater than or equal to the first concentration and less than a predetermined second concentration, and the control part makes the blower fan rotate at a second speed when the dust concentration measured by the dust measuring sensor is greater than or equal to the second concentration, the first speed being less than the second speed.

According to the massage apparatus of the present invention, the control part selects information on one massage mode among information on a plurality of massage modes which are pre-stored based on the identification information of the fragrance kit, and the control part controls the actuator or the air bag to provide a massage to the user based on the selected information on the massage mode.

According to the massage device of the present invention, the control part receives the identification information from the fragrance kit, the control part confirms whether the fragrance kit is genuine or not based on the identification information, the control part receives the information on the massage mode from the fragrance kit when the fragrance kit is genuine, and the control part controls the actuator or the air bag to provide the massage to the user based on the information on the massage mode.

According to the massage apparatus of the present invention, the information on the massage pattern includes: at least one of information on audio to be output when the massage is provided to the user, information on images to be output when the massage is provided to the user, information on oxygen to be provided when the massage is provided to the user, information on fragrance to be output when the massage is provided to the user, and information on at least one massage manner of the massage modes.

In addition, a program for realizing the operation method of the massage apparatus as described above may be recorded in a computer-readable recording medium.

Effect of the utility model

The massage device according to an embodiment of the present invention has the following effects: the health of the user is improved by supplying high purity oxygen while providing massage. In addition, the indoor air is purified and provided to the user, so that the respiratory diseases of the user can be improved. In addition, the massage device not only provides massage but also purifies indoor air, so that the utility of the massage device can be improved.

Drawings

Fig. 1 is a diagram for explaining a massage apparatus according to an embodiment of the present invention.

Fig. 2 is a view for explaining a main frame according to an embodiment of the present invention.

Fig. 3 is a diagram illustrating a massage apparatus according to an embodiment of the present invention.

Fig. 4 is a diagram illustrating an external device capable of communicating with the massage device 100 according to an embodiment of the present invention.

Fig. 5 is a diagram illustrating a massage apparatus according to an embodiment of the present invention.

Fig. 6 is a diagram illustrating the air supply part 520 and the oxygen generation part 530 in detail according to an embodiment of the present invention.

Fig. 7 is a diagram schematically illustrating gas flow according to an embodiment of the present invention.

Fig. 8 is a view illustrating a suction port according to an embodiment of the present invention.

Fig. 9 is a diagram illustrating another discharge port according to an embodiment of the present invention.

Fig. 10 is a view illustrating an air supply part according to an embodiment of the present invention.

Fig. 11 illustrates a cross-sectional view of an air supply portion according to an embodiment of the present invention.

Fig. 12 is a diagram for explaining the first damper and the second damper of the air supply portion according to the embodiment of the utility model.

Fig. 13 is a diagram illustrating an oxygen generating part according to an embodiment of the present invention.

Fig. 14 illustrates an oxygen concentration module, an oxygen concentration module holder, and a main support according to an embodiment of the present invention.

Fig. 15 is a block diagram illustrating the structure of the control board 1340 according to an embodiment of the present invention.

FIG. 16 is a view for explaining a pipe of an oxygen generation part according to an embodiment of the present invention

Fig. 17 is a view for explaining a pipe of an oxygen generation part according to an embodiment of the present invention.

Fig. 18 is a block diagram for explaining an oxygen concentration module according to an embodiment of the present invention.

Fig. 19 is a view illustrating an oxygen discharge port according to an embodiment of the present invention.

Fig. 20 is a diagram for explaining an integrated oxygen generation unit including an air supply unit and an oxygen generation unit.

Fig. 21 is a view illustrating an air purifying part according to an embodiment of the present invention.

Fig. 22 is a view illustrating an air purifying part according to an embodiment of the present invention.

Fig. 23 is a view illustrating a clean air discharge port according to an embodiment of the present invention.

Fig. 24 is a flowchart illustrating an operating method of the massage apparatus according to an embodiment of the present invention.

Fig. 25 is a flowchart illustrating an operating method of the massage apparatus according to an embodiment of the present invention.

Detailed Description

Advantages, features and methods of implementation of the disclosed embodiments will become apparent by reference to the drawings and the following embodiments. However, the present invention is not limited to the embodiments disclosed below, and may be implemented in various forms, and the embodiments are provided only for the purpose of making the present invention complete, and fully informing the scope of the present invention to those skilled in the art.

The terms used in the specification are briefly described, and the disclosed embodiments are described in detail.

Terms used in the present specification are general terms that are currently widely used as much as possible in consideration of functions in the present invention, but may be changed according to intentions of those skilled in the art, the appearance of new technology, or the like. In addition, the applicant has arbitrarily selected some terms in a specific case, and in this case, the meanings of the selected terms will be described in detail in the description part of the present invention. Therefore, the terms used in the present invention should be defined based on the meanings of the terms and the overall contents of the present invention, and cannot be defined based on only simple term names.

The singular forms "a", "an" and "the" in this specification include plural forms unless the singular forms are clearly indicated. In addition, the plural also includes the singular, unless it is clearly stated that it is the plural.

Throughout the specification, a portion "including" a certain constituent element means that other constituent elements may be included, but not excluded, unless there is a description to the contrary.

In addition, the term "section" used in the specification refers to a software or hardware constituent element, and the "section" performs some action. However, the "section" is not limited to software or hardware. The "section" may be constituted in such a manner as to exist in an addressable storage medium, or may be constituted in such a manner as to reproduce one or more processors. Thus, as an example, a "section" includes: such as software components, object-oriented software components, class components, and task components, procedures, functions, attributes, programs, subroutines, segments of program code, drivers, firmware, microcode, circuitry, data, databases, data structures, tables, arrays, and variables. The functions provided by the components and the "portions" may be provided by joining the components and the "portions" to a smaller number, or may be provided by further separating the components and the "portions" to a larger number.

According to an embodiment of the utility model, the "section" may be implemented in a processor and a memory. The term "processor" should be broadly interpreted as including general purpose processors, Central Processing Units (CPUs), microprocessors, Digital Signal Processors (DSPs), controllers, microcontrollers, state machines, and the like. In some cases, a "processor" may refer to an Application Specific Integrated Circuit (ASIC), a Programmable Logic Device (PLD), a Field Programmable Gate Array (FPGA), or the like. The term "processor" may refer to a combination of processing devices, e.g., a combination of a DSP (digital signal processor) and a microprocessor, a plurality of microprocessors, one or more microprocessors in conjunction with a DSP core, or any other such configuration.

The term "memory" should be broadly interpreted to include any electronic component capable of storing electronic information. The term memory may refer to various types of processor-readable media, such as Random Access Memory (RAM), read-only memory (ROM), non-volatile random access memory (NVRAM), programmable read-only memory (PROM), erasable programmable read-only memory (EPROM), electrically erasable programmable read-only memory (EEPROM), flash memory, magnetic or optical data storage devices, registers, and the like. A memory may be said to be in electronic communication with a processor if the processor is capable of reading information from the memory and/or recording information to the memory. A memory integrated with the processor is in electronic communication with the processor.

The actuator in this specification refers to a structure capable of providing a driving force. For example, the actuator may include, but is not limited to, a motor, a linear motor, an electric motor, a direct current motor, an alternating current motor, a linear actuator, an electric actuator, and the like.

In this specification, according to an embodiment, a massage apparatus may refer to a massage apparatus including a body massage portion and a leg massage portion. In addition, according to another embodiment, the body massage part 2100 and the leg massage part 2300 may exist as separate independent devices (e.g., a body massage device and a leg massage device) that are separated from each other, and the massage devices may refer to a body massage device or a leg massage device.

Hereinafter, the embodiments will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the embodiments. Also, in the drawings, portions irrelevant to the description will be omitted in order to more clearly describe the present invention.

Fig. 1 is a diagram illustrating a massage device according to an embodiment of the present invention.

The massage apparatus 100 according to an embodiment of the present disclosure includes: a body massage portion 2100 that forms an area for accommodating at least a part of a body of a user and massages the body of the user; and a leg massage part 2300 for massaging the legs of the user.

The body massage portion 2100 is capable of providing a massage to at least a portion of the body of the user. The body massage portion 2100 may include: a massage module 2170 to provide a massage function to at least a portion of a user's body; an audio output module 2160 to provide any form of audio output to a user; a main frame 2110 that constitutes a frame of the body massage portion 2100; and a user input 2180 for receiving an input of an arbitrary form from a user.

The respective structures of the body massaging portion 2100 described above are merely exemplary embodiments, and the body massaging portion 2100 may include various structures in addition to the aforementioned structures.

In addition, the shape and structure of the massage apparatus 100 shown in fig. 1 are merely examples, and various forms of the massage apparatus 100 should also fall within the scope of the present invention without departing from the scope of the claims defined by the claims of the present invention.

The body massage portion 2100 may form a space for accommodating an arbitrary shape of the user. The body massage portion 2100 may have a space with a form corresponding to the shape of the body of the user. For example, as shown in fig. 1, the body massage portion 2100 may be implemented as a seating type that can accommodate the entire body or a part of the body of the user.

The portion of the body massaging portion 2100 that contacts the ground may include any material or any member (e.g., a non-slip pad, etc.) for increasing friction and may include wheels for enhancing mobility of the massaging device 100.

At least a portion of the body massage portion 2100 is slidable. For example, when the body massage portion 2100 starts massaging, at least a part of the body massage portion 2100 may slide forward. In addition, the body massage portion 2100 may be inclined rearward. As a result, the body massage portion 2100 can provide a massage in a state inclined rearward.

According to an embodiment of the present invention, the massage device 100 may include at least one air bag (not shown). The air bag may be located at a shoulder portion, a pelvis portion, an arm massage portion, a leg massage portion 2300, etc. of the user, but is not limited thereto, and may be disposed at a plurality of portions of the massage apparatus 100.

The massage device 100 may include an air supply portion capable of allowing the air cells to be inflated by supplying air to the air cells. The air supply unit may be located inside the body massage unit 2100 or may be located in the leg massage unit 2300. In addition, the air supply may be located outside the massage device 100.

The leg massage part 2300 may provide a leg massage to the user. For example, the leg massage part 2300 may include a lower leg massage part for massaging a lower leg of the user and/or a foot massage part for massaging a foot of the user.

The leg massage part 2300 may be adjusted in length according to the physical characteristics of the user. For example, when a tall user uses the massage apparatus 100, the length of the leg massage unit 2300 needs to be long because the length of the lower leg is long. In addition, when a short user uses the massage apparatus 100, the leg massage section 2300 needs to be shortened because the length of the lower leg is short. Accordingly, the leg massage part 2300 can provide a leg massage in accordance with the height of the user.

The massage module 2170 may be provided inside the body massage portion 2100 to provide any form of mechanical stimulation to a user accommodated in the body massage portion 2100. As shown in fig. 1, the massage module 2170 is movable along the main frame 2110 inside the body massage portion 2100.

For example, the main frame 2110 of the body massage part 2100 may be provided with a Rack gear (Rack gear), and the massage module 2170 provides mechanical stimulation to various parts of the user's body while moving along the Rack gear. The massage module 2170 may include a ball massage unit or a roller massage unit, but is not limited thereto.

The main frame 2110 is a frame for forming an internal structure of the body massage portion 2100, and may be formed of a metal material, a plastic material, or the like. For example, the main frame 2110 may be made of iron, alloy, steel, or the like, but is not limited thereto, and may be made of various hard materials.

According to an embodiment of the present invention, the massage device 100 may include an audio output module 2160. The audio output module 2160 may be disposed in various locations. For example, the audio output module 2160 may include a plurality of output units such as an upper audio output unit disposed at an upper end of the seat portion contacting the user, a front audio output unit attached to a front end of the left and right arm massage portions of the seat portion, and/or a rear audio output unit attached to a rear end of the arm massage portion, etc., but is not limited thereto. In this case, the audio output module 2160 can provide stereo sound of, for example, 5.1 channels, but is not limited thereto.

According to an embodiment of the present invention, the user can control the massage apparatus 100 using the massage apparatus control device 2200. The massage apparatus control device 2200 may be connected to the massage apparatus 100 by wired communication and/or wireless communication.

The massage apparatus control device 2200 may include a Remote controller (Remote controller), a Cellular phone (Cellular phone), a Personal Digital Assistant (PDA), etc., but is not limited thereto, and may include various electronic devices that can be connected with the massage apparatus 100 through wired communication or wireless communication.

Fig. 2 is a view for explaining a main frame according to an embodiment of the present invention.

The main frame 2110 may include an upper frame 2250 provided with a massage module 2170 and a base frame 2210 for supporting the upper frame 2250, according to an embodiment of the present invention.

At least a portion of the upper frame 2250 may be provided with a rack 2251. The rack 2251 is a member for guiding the massage module 2170 to move up and down, and may include a plurality of valleys and a plurality of ridges.

According to an embodiment of the present invention, the rack 2251 may be disposed opposite to each other on both sides of the upper frame 2250, and the massage module 2170 may be moved along the rack 2251.

In fig. 2, the rack 2251 is formed in the up-down direction, but is not limited thereto. The rack 2251 may include a rack in a front-rear direction and a rack in an up-down direction. In the present invention, the front-rear direction refers to a direction from the massage module 2170 toward the user or from the user toward the massage module 2170, and may also be referred to as a Z-axis direction.

The massage module 2170 can include a gear that meshes with the rack 2251. More specifically, the massage module 2170 may include gears that mesh with the rack in the front-rear direction and the rack in the up-down direction, respectively. The gears are rotated by an actuator provided at the massage module 2170 so that the massage module 2170 can move forward, backward, upward or downward.

As the massage module 2170 moves forward, the massage intensity may increase. In addition, as the massage module 2170 moves backward, the massage intensity may be weakened.

The rack 2251 may be made of a metal material or a plastic material. For example, the rack 2251 may be made of iron, steel, alloy, reinforced plastic, melamine resin, phenol resin, or the like, but is not limited thereto.

The upper frame 2250 may be implemented in various shapes. For example, the upper frame 2250 may be divided into an S frame, an L frame, an S & L frame, and a dual S & L frame according to shapes, but is not limited thereto.

The S frame means that at least a portion of the upper frame 2250 includes a frame having a shape curved like "S". An L frame means that at least a portion of the upper frame 2250 includes a frame curved like "L"; the S & L frame means frames each including a shape curved like "S" and a shape curved like "L"; the dual S & L frame refers to a frame including a shape bent like "L" and a shape in which two portions are bent like "S".

The base frame 2210 refers to a portion of the main frame 2110 supporting the upper frame 2250 and interfacing with the ground. The base frame 2210 may include a base upper frame 2211 and a base lower frame 2212.

Base upper frame 2211 may support upper frame 2250 and base lower frame 2212 may interface with the ground. In addition, the base upper frame 2211 may be disposed to be in contact with the base lower frame 2212.

According to an embodiment of the present invention, the base upper frame 2211 can move along the base lower frame 2212. For example, the base upper frame 2211 can be slidably moved forward or backward along the base lower frame 2212. In this case, the upper frame 2250 is connected to the base upper frame 2211 so as to be movable with the movement of the base upper frame 2211.

For example, when the base upper frame 2211 moves forward, the upper frame 2250 can also move forward together, and when the base upper frame 2211 moves backward, the upper frame 2250 can also move backward together. Thereby enabling to allow the sliding movement of the body massaging portion 2100.

Specifically, in order to allow the movement of the base upper frame 2211, a moving wheel may be provided at a lower portion of the base upper frame 2211. In addition, a guide member capable of guiding the moving wheel may be provided on the upper portion of the base lower frame 2212. The moving wheels provided at the base upper frame 2211 move along the guide members provided at the base lower frame 2212, thereby enabling the base upper frame 2211 to move forward or backward.

According to another embodiment of the present invention, the massage apparatus 100 may not provide a sliding function, in which case the base frame 2210 may not be separated into an upper frame and a lower frame.

Fig. 3 is a diagram illustrating a massage apparatus according to an embodiment of the present invention.

The massage device 100 may include at least one of the control part 300, the sensor part 310, the communication part 320, the memory 330, the audio output module 2160, and the input part 350. The control part 300 may include at least one processor and a memory. The at least one processor may execute instructions stored in the memory.

The control section 300 can control the operation of the massage apparatus 100. The control section 300 may include one processor, or may include a plurality of processors. When the control part 300 includes a plurality of processors, at least a part of the plurality of processors may be located at positions physically spaced apart from each other by a distance. In addition, without being limited thereto, the massage apparatus 100 may be implemented in various ways.

According to an embodiment of the present invention, the control part 300 can control the operation of the massage apparatus 100. For example, the massage device 100 may include a plurality of actuators, and the massage device 100 may control the operation of the massage device 100 by controlling the operation of the plurality of actuators. For example, the massage device 100 may include at least one of a drive portion to move the armrest frame support portion, a massage module 2170 movement actuator, at least one actuator included in the massage module, a back angle actuator, a leg angle actuator, a foot massage actuator, a leg length adjustment actuator, and a slide actuator, and the control portion 300 may control the operation of the massage device 100 by controlling these actuators.

The massage module moving actuator is an actuator capable of moving the massage module 2170 up and down, and the massage module 2170 can be moved along the rack by the action of the massage module 2170 moving actuator.

The back angle actuator is an actuator that adjusts the angle of a portion of the massage device 100 that is in contact with the back of the user. The back angle of the massage device 100 can be adjusted by operation of the back angle actuator.

The leg angle actuator is an actuator for adjusting the angle of the leg massage portion 2300 of the massage device 100. The angle between the leg massage part 2300 and the body massage part 2100 can be adjusted by the operation of the leg angle actuator.

The foot massage actuator is an actuator for operating the foot massage module included in the leg massage section 2300. By using the foot massage actuator, the massage apparatus 100 may provide a foot massage to the user.

The massage module 2170 may include at least one actuator, and the control part 300 may operate the at least one actuator to provide various massage operations. For example, the control section 300 may operate at least one actuator included in the massage module 2170 to provide a tapping massage, a kneading massage, and the like, but is not limited thereto, and various massage operations may be provided.

The leg length adjusting actuator is an actuator for adjusting the length of the leg massage part 2300. For example, the control part 300 may adjust the length of the leg massage part 2300 using the leg length adjustment actuator to be able to fit the user, and as a result, the user may enjoy massage that fits the body shape.

The slide actuator enables the massage apparatus 100 to slide. For example, the horizontal base upper frame may be moved forward or backward by the operation of the slide actuator, so that the upper frame connected to the horizontal base upper frame may also be moved forward or backward.

The memory 330 may be included in the control part 300 or located outside the control part 300. The memory 330 may store various information related to the massage device 100. For example, the memory 330 may include massage control information, may include personal authentication information, but is not limited thereto.

The memory 330 may be implemented by a non-volatile storage medium capable of persistently storing some data. For example, the memory 330 may include, but is not limited to, magnetic disk, optical disk, and magneto-optical (magneto-optical) storage devices, as well as flash memory and/or battery backed-up memory based storage devices.

The memory 330 may be a Random Access Memory (RAM) such as a Dynamic Random Access Memory (DRAM) or a Static Random Access Memory (SRAM), and is a volatile memory device in which information stored when the power is turned off is instantaneously erased as a main memory device directly accessed by the processor, but is not limited thereto. Such a memory 330 may be operated by the control section 300.

The massage device 100 may include a sensor portion 310. The sensor part 310 may acquire various information by using at least one sensor. The sensor portion 310 may be configured as a sensor using measurement means such as pressure, electric potential, and optics. For example, the sensor may include, but is not limited to, a pressure sensor, an infrared sensor, an LED sensor, a touch sensor, and the like.

In addition, the sensor part 310 may include a biological information acquisition sensor. The biological information acquisition sensor may acquire fingerprint information, face information, voice information, iris information, weight information, electrocardiogram (electrocardiogram) information, body composition information, and the like, but is not limited thereto and may include a variety of biological information.

According to another embodiment of the present invention, the massage apparatus 100 may sense a contact area and/or a contact position with the user through a sensor. In addition, the massage apparatus 100 may provide personalized massage based on information acquired through the sensors. In addition, the massage device 100 may include a communication portion. The communication unit of the massage apparatus 100 receives a signal from an external device. The control part 300 may acquire a result signal by processing the received signal. The communication section may output the result signal to an external device.

The communication unit 320 communicates with the modules inside the massage apparatus 100, the external massage apparatus, and/or the user terminal via any type of network. The communication part may include a wired/wireless connection module for connecting a network. As the Wireless connection technology, for example, a Wireless Local Area Network (WLAN) (Wi-Fi), a Wireless broadband (Wireless broadband, Wireless), World Interoperability for Microwave Access (Wimax), High Speed Downlink Packet Access (HSDPA), or the like may be used. As wired connection techniques, for example, Digital Subscriber Line (XDSL), Fiber To The Home (FTTH), Power Line Communication (PLC), and the like are used. The network connection unit includes a short-range communication module and is capable of transmitting and receiving data to and from an arbitrary device or terminal located at a short distance. For example, as short range communication (short range communication) technology, Bluetooth (Bluetooth), Radio Frequency Identification (RFID), infrared Data Association (IrDA), Ultra Wideband (UWB), ZigBee (ZigBee), and the like can be used, but the technology is not limited thereto.

In addition, the massage device 100 may also include an input 350 or an output. The massage device 100 may receive input from a user using the input 350. The massage apparatus 100 may output the processing result of the control unit 300 to the output unit.

Specifically, the input section 350 may receive an instruction on operation control of the massage apparatus 100 from the user, and the input section 350 may be implemented in various ways. For example, the input unit 350 may be provided in the body massage unit 2100 and the leg massage unit 2300, but is not limited thereto. Further, the input section 350 may include the user input section 2180 of fig. 1, the massage apparatus control apparatus 2200, or various external devices illustrated in fig. 4.

The massage device 100 may acquire various instructions from the user through the input portion 350. For example, the massage device 100 can receive any instruction regarding selection of a massage module, selection of a massage type, selection of massage intensity, selection of massage time, selection of a massage portion, selection of a position and operation of the body massage portion 2100, selection of On-Off (On-Off) of a power supply of the massage device 100, selection of whether to activate a heating function operation, selection related to sound source playback, and the like, but is not limited thereto.

The massage device 100 can provide an interface for selecting a massage mode. For example, the input 350 or output may include a massage device control apparatus 2200. The medical massage list of various modes relating to physical improvement can be listed by the massage apparatus control device 2200.

The therapeutic massage mode may include at least one of a concentration mode, a meditation mode, a recovery mode, an extension mode, a sleep mode, a vitality mode, a golf mode, a hip shaping mode, an examinee mode, a weightlessness mode, and a growth mode.

According to another embodiment of the present invention, the input part 350 may have a button in a hot key (hot key) form and/or an option button for performing selection, cancellation, input of a direction, etc. according to a preset user setting function, a self-preset function, etc.

The input unit 350 may be implemented by a keyboard, a dome switch, a touch panel (static pressure/static electricity), a jog wheel, a jog switch, or the like, but is not limited thereto. Also, the input section 350 may acquire an instruction according to the utterance of the user based on a voice recognition technique.

According to an embodiment of the present invention, the output portion may include a display for displaying an operating condition of the massage apparatus 100 or a current state of the user, or the like. In this case, the display may include at least one of a Liquid Crystal Display (LCD), a thin film transistor-liquid crystal display (TFT LCD), an organic light-emitting diode (OLED), a flexible display (flexible display), and a three-dimensional display (3D display), but is not limited thereto.

The output section may include an audio output module 2160. The audio output module 2160 can provide any manner of audio output to the user. For example, the audio output module 2160 outputs a sound source and/or binaural beats optimal for the massage mode provided by the massage apparatus 100 to the user, thereby being able to provide brain stimulation to the user. The audio output module 2160 may output an acoustic signal received through a network (not shown) or stored in an internal/external storage medium (not shown). For example, the audio output module 2160 may output a sound source based on the control of the user terminal through the user terminal and a network connection (e.g., bluetooth connection, etc.). In addition, the audio output module 2160 may output any form of acoustic signal that occurs in connection with the operation of the massage apparatus 100.

Those skilled in the art will appreciate that the present invention can be implemented in combination with other program modules and/or by a combination of hardware and software. For example, the utility model may be implemented by a computer-readable medium.

The computer-accessible medium may be any computer-readable medium including volatile and non-volatile media, transitory (transient) and non-transitory (non-transient) media, removable and non-removable media. By way of example, and not limitation, computer-readable media may comprise computer-readable storage media and computer-readable transmission media.

Computer-readable storage media include volatile and non-volatile, transitory and non-transitory, removable and non-removable media for storage of information such as computer-readable instructions, data structures, program modules or other data and which may be embodied by some method or technology. Computer-readable storage media can include, but is not limited to, RAM, ROM, EEPROM, flash memory or other memory technology, CD-ROM, Digital Video Disk (DVD) or other optical disk storage, magnetic cassettes, magnetic tape, magnetic disk storage or other magnetic storage devices, or any other medium which can be accessed by a computer and which can be used to store the desired information.

Fig. 4 is a diagram showing an external device capable of communicating with the massage device 100 according to an embodiment of the present invention.

The massage apparatus 100 may communicate with an external apparatus by wire or wirelessly, transmitting and receiving various data.

The external device may include a portable electronic device 410 such as an AI speaker, a tablet computer, or a smartphone. The portable electronic device 410 may be a portable electronic device dedicated to or used by the massage apparatus 100. Additionally, the external device may include a wearable apparatus 420 such as a smart watch or a smart watch band. The external device may include other massage devices 430 in addition to the massage device 100 that the user is now using. The external device may include a hospital server 440. The external device may include a Personal Health Record (PHR) server. In addition, the external device may include a cloud server 450. The external device may include a medical measurement apparatus such as an electronic scale, a blood glucose meter, or a blood pressure meter.

Although some examples of the external device have been described in the present invention, it should be understood that the external device may be included as long as it is an apparatus that communicates with the massage device 100 by wire or wirelessly and can transmit and receive information to and from each other.

Fig. 5 is a diagram illustrating a massage apparatus according to an embodiment of the present invention.

The massage device 100 of fig. 5 may further include an oxygen generating device. Various configurations included in the oxygen generator will be described with reference to fig. 5. The massage device 100 includes an intake port 510 for taking in outside air. The suction inlet 510 may be located at the lower end of the massage device 100. When the suction port 510 is located at the lower end of the massage apparatus, there is an effect that it can be used as a handle for moving the massage apparatus 100. Since the conventional massage apparatus 100 has a movable handle at the lower end thereof, the suction port 510 can be provided without largely changing the structure of the conventional massage apparatus 100. Further, the movement handle 511 and the suction port 510 are used as a movement handle, so that the massage apparatus 100 can be stably moved.

However, the position of the suction port 510 is not limited to fig. 5. The suction inlet 510 may be located at the upper end of the massage device 100. Since dust is heavier than air, dust is more prevalent at the lower end. Therefore, by providing the suction port 510 at the upper end of the massage apparatus 100, the concentration of dust in the sucked air can be greatly reduced. In addition, the length of the gas moving tube is reduced by minimizing the distance from the suction port 510 to the oxygen discharge port 540, so that the implementation cost of the oxygen generating device can be reduced. In addition, there is an effect that the gas can be moved only by using a small pressure of the compressor.

In addition, the suction port 510 may be located at an outer surface of the arm massage part. In this regard, description will be made with reference to fig. 21 and 22.

In addition, the massage device 100 may include an air supply part 520, and the air supply part 520 sucks external air through the suction port and moves it to the oxygen generation part. The air supply 520 may include a compressor. The air supply part 520 may suck external air by generating pressure using electric power. In addition, the compressor may supply the sucked air to the oxygen generation part 530.

In addition, the massage device 100 may include an oxygen generating part 530, and the oxygen generating part 530 adsorbs nitrogen from the air supplied from the air supply part and discharges concentrated oxygen. The oxygen generating part 530 may concentrate oxygen by various methods. Typically, air contains 21% oxygen, while concentrated oxygen may contain more than 21% oxygen. The oxygen generating part 530 may increase the concentration of oxygen by removing nitrogen from the air. The oxygen generating part 530 may separate nitrogen from the air and additionally discharge it.

In addition, the massage device 100 may include a flow path tube for moving the concentrated oxygen from the oxygen generation part to the oxygen discharge port. The flow conduit may be a closed conduit. Therefore, the concentrated oxygen can move from the oxygen generation part 530 to the oxygen discharge port 540 without changing the oxygen concentration.

In addition, the massage device 100 may include an oxygen discharge port 540, and the oxygen discharge port 540 may be used to supply the concentrated oxygen moving through the flow path pipe to the user. Oxygen outlet 540 may be positioned near the user's head for inhalation by the user.

The massage apparatus 100 may include a clean air discharge port 3213, and may include a flow path pipe connecting the suction port 510 and the clean air discharge port 3213. The clean air exhaust port 3213 may be provided separately from the oxygen exhaust port 540. In this regard, description will be made with reference to fig. 21 and 22.

Fig. 5 exemplarily shows only the positions of the suction port 510, the air supply unit 520, the oxygen generation unit 530, and the oxygen discharge port 540 included in the massage device 100. That is, the suction port 510, the air supply unit 520, the oxygen generation unit 530, and the oxygen discharge port 540 may be provided at other positions of the massage device 100.

Fig. 21 is a view illustrating an air purifying part according to an embodiment of the present invention. Fig. 22 is a view illustrating an air purifying part according to an embodiment of the present invention.

Referring to fig. 21 and 22, the massage apparatus 100 may include an arm massage portion 3110. The arm massage portion 3110 may include an air cleaning portion 3120. The air cleaning portion 3120 will be described in detail with reference to fig. 22. The outer surface of the arm massage part 3110 may include a suction port 510 for sucking in external air. For example, the left outer surface of the left arm massage portion may include the suction inlet 510. In addition, the right outer surface of the right arm massaging portion may include a suction port 510. Fig. 21 may be a diagram showing the right arm massage part 3110. The suction port 510 may suck external air. The sucked external air may be supplied to the air cleaning portion 3120 or to the oxygen generating device. The air cleaning portion 3120 and the oxygen generating device may share the same suction port 510. However, the air cleaning portion 3120 may not share the suction port 510 with the oxygen generating device. For example, the suction inlet 510 of fig. 5 may be used for the oxygen generating device, and the suction inlet 510 of fig. 21 may be used for the air cleaning portion 3120.

The massage apparatus 100 may include an air duct 3210 for moving the sucked external air to the clean air discharge port 3213. The air duct may include a filter mount 3211. A blower fan 3220 or a filter unit 3230 may be inserted into the filter mounting portion 3211.

The air duct 3210 may include a clean air flow path portion 3212 that moves air. The clean air flow path portion 3212 may constitute a part of a duct that moves air from the filter mounting portion 3211 to the clean air discharge port 3213. The clean air flow path portion 3212 may extend vertically from the filter mounting portion 3211 to the clean air discharge port 3213.

The clean air flow path portion 3212 may have two opposing faces. In order to make the clean air flow path portion 3212 a clean air moving path, two surfaces perpendicular to the two opposing surfaces of the clean air flow path portion 3212 may be required. A part of the casing of the arm massage portion 3110 of the massage apparatus 100 may form a clean air passage pipe together with the clean air passage portion 3212. When the clean air flow path portion 3212 is engaged with the inside of the arm massage portion 3110, a tube having a quadrangular cross section may be formed, and the clean air may move along the clean air flow path portion 3212. Both surfaces of the clean air flow path pipe may be formed by the clean air flow path portion 3212, and the remaining two surfaces of the clean air flow path pipe may be formed by the opposite surfaces inside the housing of the arm massage portion 3110. Both surfaces of the clean air flow path portion 3212 and both surfaces of the housing of the arm massage portion 3110 may be at almost right angles. When both surfaces of the clean air flow path portion 3212 are engaged with both surfaces of the housing of the arm massage portion 3110, the gap can be minimized. The joint portions of both surfaces of the clean air flow path portion 3212 and both surfaces of the housing of the arm massage portion 3110 may use a finishing material made of a flexible material for preventing air from flowing out.

According to various embodiments of the present invention, the oxygen generation suction pipe may be connected to one surface of the housing of the arm massage part 3110 or the clean air flow path part 3212 forming the clean air flow path pipe. The oxygen generation suction tube may function the same as the suction port 510 of fig. 5. The clean air inhaled through the oxygen generation inhalation tube is supplied to the oxygen generation part 530 for generating oxygen. The clean air sucked through the oxygen generation suction pipe passes through the air supply part 520 of fig. 7 and passes through the oxygen generation part 530. Thus, clean air may be used to generate oxygen. Since the air from which a portion of dust or moisture is removed is used, the oxygen generating part 530 may stably generate oxygen and the life of the oxygen generating part 530 may be extended.

The air duct 3210 may include a clean air exhaust 3213. The clean air discharge port 3213 of the air duct 3210 may be a hole through which clean air is discharged. The clean air discharge port 3213 may provide the outside air filtered by the filter part 3230 to a user. The clean air outlet port 3213 may be engaged with the outlet port cover 3260.

The massage device 100 can include a discharge port cover 3260. The discharge port cover 3260 can be engaged with the clean air discharge port 3213. The discharge port cover 3260 will be described in detail with reference to fig. 23.

The massage device 100 may include a blowing fan 3220. The blower fan 3220 may be inserted into the filter mounting portion 3211 included in the air duct 3210. The blower fan 3220 may be fixed to the inside of the filter mounting portion 3211. The blowing fan 3220 may generate an air current to move the external air to the discharge port. The blowing fan 3220 may include at least two fans. Therefore, it is possible to provide sufficient clean air to the user.

In addition, the blowing fan 3220 may change the direction of the air flow. For example, the flow of the outside air of the filter part 3230 to the blower fan 3220 may be in the left-right direction. Here, the left-right direction may refer to a left-right direction when the user sits on the massage apparatus 100. However, after the air passes through the blowing fan 3220, the air flow may be in an upward direction. The upward direction may refer to the opposite direction of the ground.

The blower fan 3220 may be a structure for supplying the air filtered by the filter portion 3230 to the clean air discharge port 3213. The rotation speed of the blowing fan 3220 may be automatically or manually controlled. For example, the control part 300 may determine the operating speed of the blowing fan 3220 based on the input of the user.

In addition, the control part 300 may automatically adjust the speed of the blowing fan 3220. For example, the massage device 100 may further include a dust measurement sensor 3270, the dust measurement sensor 3270 being used to measure fine dust in the outside air of the massage device 100. The control part 300 may deactivate the blowing fan 3220 when the dust concentration measured by the dust measurement sensor 3270 is less than a predetermined first concentration. In addition, the control part 300 may rotate the blowing fan 3220 at the first speed when the dust concentration measured by the dust measurement sensor is greater than or equal to the first concentration and less than a predetermined second concentration. In addition, when the dust concentration measured by the dust measurement sensor 3270 is greater than or equal to the second concentration, the control part 300 may rotate the blowing fan 3220 at the second speed. Wherein the first speed may be less than the second speed.

The control unit 300 may display the measured dust concentration as an image or sound. For example, the massage device 100 may display the measured dust concentration on the display portion in an image manner. In addition, the massage device 100 may include at least three LEDs for displaying dust concentration. Each LED can display low, medium, high dust concentration. The massage device 100 may turn on one of the three LEDs based on the measured dust concentration.

The massage device 100 may include a filter portion 3230. The filter portion 3230 may be inserted into the filter mounting portion 3211 of the air duct 3210. The filter portion 3230 may be fixed inside the filter mounting portion 3211. Or the filter portion 3230 may be fixed to the blowing fan 3220. The filter portion 3230 may be a structure for filtering foreign substances of outside air. The massage apparatus 100 may remove foreign substances contained in the external air sucked into the suction port 510 using the filter part 3230. The filter portion 3230 may include a High Efficiency Particulate Air (HEPA) 14 grade Air filter 3232.

The filter portion 3230 may include a filter guide frame 3231. The filter guide frame 3231 may be fixed to the blower fan. Alternatively, the filter guide frame 3231 may be fixed to the filter mounting portion 3211. The filter guide frame 3231 may fix the air filter 3232. There is no gap between the filter guide frame 3231 and the air filter 3232, and external air must pass through the air filter 3232 in order to flow to the blowing fan 3220. The filter guide frame 3231 may include at least one hole. The at least one hole may be a passage through the air filter 3232 to the blowing fan 3220.

The filter portion 3230 may include an air filter 3232. The air filter 3232 may be inserted into the inside of the filter guide frame 3231. The air filter 3232 may be a structure for removing foreign substances from the external air. The Air filter 3232 may be a High Efficiency Particulate Air (HEPA) 14 grade.

The filter portion 3230 may include a suction port cover guide 3233. The suction port cover guide 3233 may pressurize at least a portion of the air filter 3232 to fix the air filter 3232 to the filter guide frame 3231. The suction port cover guide 3233 may be fixed to the filter guide frame 3231. In addition, the suction port cover guide 3233 may be a structure for engaging the suction port cover 3250.

The massage device 100 may include a suction port cover 3250. The suction port cover 3250 may cover the filter mounting portion 3211. The suction port cover 3250 may have various structures for covering the filter mounting portion 3211. In addition, the suction port cover 3250 may be configured to make the appearance of the massage apparatus 100 more beautiful.

The massage device 100 may include a fragrance kit 3240. The fragrance kit 3240 can be engaged with the intake cap 3250.

The aroma kit 3240 can include an aroma generating substance for generating aroma. The flavor generating substance may include an essential oil, or flavor nanocapsules, etc. Different identification information may be given according to the type of the fragrance generating substance contained in the fragrance kit 3240. That is, the identification information of the fragrance kit 3240 may correspond to a fragrance generating substance that generates a predetermined fragrance.

The fragrance kit 3240 may be classified into one of a plurality of types according to the identification information. A plurality of types may be classified based on one of a massage pattern and a scent of a scent generating substance contained in the scent kit 3240. For example, the massage device 100 may classify the fragrance kit 3240 into a particular type based on the identification information of the fragrance kit 3240. In addition, the massage apparatus 100 may provide a massage to the user by selecting a massage mode corresponding to a specific type.

The control section 300 may acquire identification information of the fragrance kit 3240. The control part 300 may control the actuator or the air bag to provide a massage to the user based on the massage pattern according to the identification information.

The control unit 300 may determine the type of fragrance contained in the filter unit 3230 based on the identification information of the fragrance kit 3240. For example, the control part 300 may include a table in which identification information of the fragrance kit 3240 is associated with the kind of fragrance. The control section 300 may select a kind of fragrance from the table based on the identification information of the fragrance kit 3240. In addition, the control part 300 may output the fragrance provided by the fragrance kit 3240 currently installed in the form of an image or sound. The user can easily know the fragrance that he is smelling.

Fig. 23 is a view illustrating a clean air discharge port according to an embodiment of the present invention.

Referring to fig. 23, the massage device 100 may include a discharge port cover 3260. The discharge port cover 3260 may be located at the clean air discharge port 3213. The discharge port cover 3260 may be a structure that provides air filtered by the filter part 3230 to a user.

The discharge port cover 3260 may be included in the arm massage part 3110. The discharge port cover 3260 is located at an upper portion of the housing of the arm massage part 3110, and the discharge port cover 3260 may face a user. Accordingly, the exhaust port cover 3260 can provide clean air to the user.

Exhaust port cover 3260 can include vanes 3261 for orienting the exhausted air. The orientation of the vanes 3261 can be adjusted by the user.

The massage apparatus 100 may further include an air cleaning flow path portion 3212, and the air cleaning flow path portion 3212 does not pass through the oxygen generating portion and is connected from the suction port 510 to the clean air discharge port 3213. The air cleaning flow path portion 3212 may be a passage through which air filtered by the filter portion 3230 moves to the clean air discharge port 3213. The air filtered by the filter portion 3230 can be discharged to a user through a discharge port cover 3260 provided at the clean air discharge port 3213.

Fig. 6 is a diagram illustrating the air supply part 520 and the oxygen generation part 530 in detail according to an embodiment of the present invention.

The air supply unit 520 and the oxygen generation unit 530, which are not shown in detail in fig. 5, may be confirmed at block 610 of fig. 6. The air supply 520 may include a cover and a housing. The interior of the cover and housing may include a compressor. The oxygen generating part 530 may receive general air and output concentrated oxygen. The concentrated oxygen may be provided to the user. The oxygen generating part 530 may be engaged with the bracket. The oxygen generating part 530 needs to be replaced periodically because its performance is degraded with the lapse of time. The oxygen generating part 530 may have a structure that is easily detached from and installed to the bracket.

Block 620 of fig. 6 shows a top view of the massage device 100. In addition, block 630 of fig. 6 shows a front view of the massage device 100. The air supply unit 520 and the oxygen generation unit 530 may be biased toward the right side of the massage device 100. The right side may represent the direction of the X-axis. The air supply part 520 and the oxygen generation part 530 may be located at a lower end of the massage device 100. The downward direction may be the opposite direction of the Z axis. As described above, since the air supply unit 520 and the oxygen generation unit 530 are located in the massage device 100, it is possible to avoid interference with other structures of the massage device 100.

Fig. 7 is a diagram schematically illustrating gas flow according to an embodiment of the present invention.

The suction port 510 may suck external air. Due to the air pressure difference, external air may be sucked through the suction port 510. The air supply part 520 may provide a motive force that may cause external air to be sucked through the suction port 510. The air supply part 520 may supply external air to the oxygen generation part 530. The oxygen generating part 530 may absorb nitrogen in the received external air. Since nitrogen in the outside air is removed, the oxygen concentration can be relatively increased. The oxygen generating part 530 may generate concentrated oxygen and discharge the oxygen through the flow path pipe. The concentrated oxygen moving through the flow path pipe may be inhaled by the user.

Fig. 8 is a view illustrating a suction port according to an embodiment of the present invention.

The upper side of fig. 8 is a view showing the structure included in the suction port 510, and the lower side of fig. 8 is a view showing the joint of the suction port housing 810 and the suction port cover 830 included in the suction port 510.

Referring to fig. 8, the suction inlet 510 may include a suction inlet housing 810, a first filter 820, and a suction inlet cover 830. The suction inlet housing 810 may engage the housing of the massage device. The suction port housing 810 may serve as a handle for moving the massage device 100.

The first filter 820 may be inserted into the suction port housing 810. The first filter 820 may remove impurities of the external air. The first filter 820 may be surrounded by a cover 821 of an elastic material to be fixed to the suction port housing 810. Cover 821 allows the outer surface of first filter 820 to be in close contact with the inner surface of suction port housing 810. Therefore, the external air can be sucked only through the filter 822. The first filter 820 may include a filter 822 for removing dust. The first filter 820 may remove fine dusts of 0.3 μm or more. In this manner, the first filter 820 has an effect of removing fine dust to purify air at the position of the massage apparatus 100.

The suction port cover 830 may fix the first filter 820 such that the first filter 820 does not fall off the suction port housing. The suction port cover 830 may include at least one suction hole for sucking external air. As shown in fig. 8, the suction hole may be disposed parallel to the ground. But is not limited thereto, the suction hole may be elliptical or circular. At least a portion of the plurality of suction holes may have a size different from that of the other suction holes.

The suction port cover 830 is formed with a handle 832 so that the user can easily open the suction port cover 830. The user can easily replace the first filter 820 by opening the suction port cover 830.

The lower side view of fig. 8 is a view showing the suction port cover 830 being opened. One side of the suction port cover 830 may be engaged with the suction port housing 810. For example, the suction port cover 830 may include a hook-shaped engaging portion 831. The engaging portion 831 may be engaged with the hole of the suction port housing 810. When the suction port cover 830 is opened or closed by the engaging portion 831, the suction port cover 830 may not be separated from the suction port housing 810.

Fig. 9 is a diagram illustrating another discharge port according to an embodiment of the present invention.

The oxygen outlet 540 may include an aperture for injecting concentrated oxygen. When the concentrated oxygen is injected, it is mixed with the outside air, and the concentration of oxygen inhaled by the user is drastically reduced. Therefore, it is necessary to dispose the oxygen discharge port 540 as close to the nose or mouth of the user as possible.

The massage device 100 may automatically adjust the position of the oxygen discharge port 540. For example, the massage device 100 may measure the shoulder position of the user before providing the massage. The massage device 100 may determine the location of the oxygen discharge ports 540 based on the measured shoulder position of the user. Specifically, the massage device 100 may determine the displacement from the user's shoulder to the user's nose or mouth based on a predetermined rule. The massage device 100 may position the oxygen discharge ports 540 near the nose or mouth of the user based on the displacement. Wherein the predetermined rule may be a rule determined based on human scale statistics.

But is not limited thereto, the user may manually adjust the position of the oxygen discharge port 540. Oxygen exhaust port 540 may include an exhaust tube 920. The upper view of fig. 9 shows a state where the discharge tube 920 is not developed, and the lower view of fig. 9 shows a state where the discharge tube 920 is developed. The discharge tube 920 may be inserted into the housing 950 of the massage apparatus 100. The drain 920 may be located on the left or right side of the housing 950 of the massage apparatus 100. The insertion position of the discharge tube 920 in the outer shell 950 may be a position within 30cm from the head of the user.

The discharge pipe 920 may be adjustable in length and may be bent. The discharge pipe 920 may be connected with a flow path pipe. The discharge pipe 920 may be a passage through which the concentrated oxygen moves. The drain pipe 920 may be about 15cm to 30 cm. The discharge tube 920 may be bent or extended to bring the discharge nozzle 910 close to the user's face. The discharge pipe 920 may have a bellows structure.

Oxygen exhaust port 540 may include an exhaust nozzle 910. The discharge nozzle 910 may be connected to a discharge pipe 920. The discharge nozzle 910 may include at least one hole for discharging the concentrated oxygen. The user may position the discharge nozzle 910 within 10cm of the user's nose or mouth.

The oxygen vents 540 may include a vent tube and an oxygen breathing mask. There are cases where a user needs to inhale high-purity oxygen due to diseases caused by diving, diseases caused by viruses, or diseases caused by bacteria. Alternatively, the lung function may be weakened due to health reasons, and the user may not be able to inhale oxygen normally. The oxygen breathing mask may isolate the nose and mouth from the outside air, so that the user better inhales the oxygen generated from the massage apparatus 100. The interior of the oxygen breathing mask may be filled with oxygen supplied from the massage device 100, which the user may inhale. Oxygen breathing masks may use mechanical or electronic means to automatically expel the air exhaled by the user. The interior of the oxygen breathing mask can be maintained with high purity oxygen at all times.

In addition, the massage apparatus 100 may include a discharge port for filling the oxygen cylinder with high pressure instead of the discharge port. The massage apparatus 100 may store the concentrated oxygen at high pressure. In addition, when the discharge port of the massage apparatus 100 is connected to the oxygen cylinder, the massage apparatus 100 may fill the oxygen cylinder with high-pressure concentrated oxygen. The user can carry the portable oxygen cylinder and use the concentrated oxygen when needed.

However, although the above description has been made of the structure for discharging oxygen of various functions, the present invention is not limited thereto, and the oxygen discharge port 540 of various forms or functions may be used in the massage device 100.

Fig. 10 is a view illustrating an air supply part according to an embodiment of the present invention.

The massage device 100 may include an air supply 520. The air supply part 520 may include an air supply part housing 1050, and the air supply part housing 1050 is fixed to a main frame of the massage apparatus. The inner surface of the air supplier case 1050 may use a sound insulating material using a substance such as sponge or paper. The compressor 1030 may be installed in the air supply unit case 1050, and the compressor 1030 may generate loud noise. Accordingly, the air supplier housing 1050 may include a soundproof material to prevent noise of the compressor 1030 from being transmitted to a user. The noise of the compressor 1030 felt by the user can be reduced to below about 37dB due to the air supply unit housing 1050 using the soundproof material.

The air supply 520 may include a first damper 1060. A part of the first damper 1060 may be located between the main frame 2110 of the massage apparatus 100 and the air supply part housing 1050. A portion of the first damper 1060 may be located between the main bracket of the oxygen generating part 530 and the air supply part case 1050. The air supply housing 1050 may include at least one connection bridge 1051. The first damper 1060 may be located at a lower end of the connection bridge 1051.

The first damper 1060 may prevent vibration of the air supply part 520 from being transmitted to the main frame 2110. The first damper 1060 may be made of rubber, polyurethane, or silicone. The resonance of the air supply part 520 can be reduced due to the viscosity of the material itself of the first damper 1060. In addition, since the first damper 1060 does not generate additional noise, it is possible to reduce not only vibration but also noise of the air supply part 520.

As described above, the air supply 520 may include the compressor 1030. The compressor 1030 may induce vibration, which may be transmitted to a user along with the main frame 2110. The vibrations may prevent the user from comfortably receiving the massage. The first damper 1060 prevents vibration of the compressor 1030 from being transmitted to a user along with the main frame 2110.

The air supply 520 may include a compressor 1030 for generating oxygen. The compressor 1030 is installed inside the air supplier housing 1050, and may be a device for sucking external air. The compressor 1030 may suck external air and supply it to the oxygen generation part 530. The compressor 1030 may generate vibration, noise, and heat. Noise can be reduced by the sound insulating material contained in the air supply unit case 1050 and the air supply unit cover 1020. The vibration may be reduced by the first damper 1060 and the second damper 1040. Heat may be reduced by cooling fan 1010.

The air supply 520 may include a second damper 1040. A second damper 1040 may be used to engage the compressor 1030 for oxygen generation with the air supply housing 1050. Both ends of the second damper 1040 may include screw structures. One end of the second damper 1040 may be engaged with a lower end of the compressor 1030. The other end of the second damper 1040 may be engaged with an upper end of the bottom surface of the air supplier housing 1050.

In addition, the second damper 1040 may prevent vibration of the compressor 1030 for generating oxygen from being transmitted to the air supplier housing 1050. More specifically, the second damper 1040 may include a spring to prevent vibration of the compressor 1030 from being transmitted to the air supply case 1050. The spring constant of the second damper 1040 may be determined according to the excitation frequency of the compressor 1030. The second damper may have an elastic coefficient for isolating (isolating) a natural vibration frequency generated from the compressor 1030 for generating oxygen.

More specifically, the internal structure of the compressor 1030 vibrates due to unbalance or shaking of the device when performing a rotational motion and a reciprocating motion, and such a force is called an excitation force. The magnitude of the exciting force of the rotating device is shown below.

F＝m*r*w^2

F: excitation force, r: eccentricity, m: eccentric mass, w: angular velocity of rotation

In addition, the vibration frequency generated due to the rotational motion and the reciprocating motion of the compressor 1030 is referred to as an excitation frequency or a natural vibration frequency. In addition, the degree to which the second damper 1040 transmits the vibration of the device is referred to as a vibration transmissibility. The vibration transmissibility is expressed as follows.

TR＝1/abs(1-r^2)

abs (): absolute value, r: fd/fn, fd: excitation frequency of compressor 1030, fn: the natural vibration number of the damper (═ 1/(2 × pi) × root (k/m)), k: spring coefficient of damper, m: mass of damper

Therefore, in order to block the vibration, it is necessary to reduce the vibration transmission rate. When the damper does not transmit the vibration of the compressor 1030, it is referred to as vibration isolation or damping. In order to reduce the vibration transmissivity, it is necessary that r be larger than root (2). In addition, r is preferably greater than 3. The second damper 1040 may have a spring constant k for reducing an excitation frequency of the compressor 1030.

As described above, the vibration of the compressor 1030 may prevent the user from comfortably receiving the massage. The massage apparatus 100 according to the present invention may be provided with a dual anti-vibration unit. That is, the first and second dampers 1060 and 1040 can prevent vibration of the compressor 1030 from being transmitted to a user along with the main frame 2110. Therefore, the user can comfortably receive the massage.

Fig. 11 is a sectional view illustrating an air supply part according to an embodiment of the present invention.

Referring to fig. 10 and 11 together, the air supply part 520 may include a cooling fan 1010 for cooling a compressor 1030 for generating oxygen. The cooling fan 1010 may be variably controlled according to the temperature of the compressor 1030. For example, the massage device 100 may use a sensor to measure the temperature of the compressor 1030. The massage device 100 may increase the rotation speed of the cooling fan 1010 based on the temperature of the compressor 1030. The rotational speed of the cooling fan 1010 may be proportional to the temperature of the compressor 1030. When the temperature of the compressor 1030 is higher than a predetermined threshold value, the massage apparatus 100 may operate the cooling fan 1010.

Even after the operation of the air supply unit 520 is stopped, the massage apparatus 100 may operate the cooling fan 1010 for 1 to 3 minutes again. Alternatively, even after the operation of the air supply part 520 is stopped, the massage apparatus 100 may operate the cooling fan 1010 until the temperature of the air supply part 520 is lower than the predetermined threshold value. Since the air supply part 520 is a device that generates a large amount of heat, a high temperature can be maintained even after the operation of the air supply part 520 is stopped. The high temperature may not only reduce the lifetime of the air supply part 520 but also reduce the lifetime of peripheral devices. Therefore, the massage device 100 can prevent the air supply part 520 from maintaining an excessively high temperature by operating the cooling fan 1010.

In addition, the air supply 520 may include an air supply cover 1020. The air supplier cover 1020 may cover an opening portion of the air supplier housing 1050. An opening portion of the air supply unit case 1050 may be formed at an upper end of the air supply unit case 1050.

The air supplier cover 1020 may include an air supply hole 1021 and an air discharge hole 1022. The air supply hole 1021 of the air supplier cover 1020 may include a cap such that the cool air based on the cooling fan 1010 is completely supplied to the air supplier case 1050. The cap of the air supply hole 1021 may also change the direction of the cool air based on the cooling fan 1010. For example, the direction of the cool air generated by the cooling fan 1010 may be parallel to the ground. The cap of the air supply hole 1021 may change the direction of the cool air to be directed toward the inside of the air supply part case 1050 perpendicularly to the ground.

The cooling fan 1010 blows air into the air supplier case 1050 through the air supply hole 1021 of the air supplier cover 1020, and the air supplied into the air supplier case 1050 is discharged through the air discharge hole, so that the compressor 1030 for generating oxygen can be cooled.

More specifically, the compressor 1030 for generating oxygen may include a first cylinder chamber 1111 located at a side of the air supply hole 1021 and a second cylinder chamber 1112 located at a side of the air discharge hole 1022. The cooling fan 1010 may blow cold air into the first cylinder chamber 1111 side through the air supply hole 1021. The cool air may cool the compressor 1030. In addition, the cold air may be heated by the compressor 1030. The heated air may be discharged through the air discharge holes 1022. The air supply unit 520 having the configuration of fig. 11 has an effect of cooling the compressor 1030 inexpensively by using only one cooling fan 1010.

The air discharge hole 1022 of the air supplier cover 1020 may include at least one hole. The air pressure may be increased inside the air supplier case 1050 by the cooling fan 1010. Due to the air pressure difference, the air heated by the compressor 1030 may escape from the air supply case 1050 to the outside.

Fig. 12 is a diagram for explaining the first damper and the second damper of the air supply portion according to the embodiment of the utility model.

The first damper 1060 may have a circular ring shape. The screw passes through a hole included in the first damper 1060 so that the air supply part housing 1050 can be engaged with the main frame 2110 or the main bracket 1210 of the oxygen generating part 530. Although described below, main support 1210 is a mechanism for securing the oxygen concentration module.

The first damper 1060 may be located between the main bracket 1210 and the air supply part case 1050. In addition, a first damper 1060 may be located between the main frame 2110 and the air supply part housing 1050.

The first damper 1060 may be located at a lower end of the connection bridge 1051 included in the air supply section case 1050. The air supply section housing 1050 may include four connection bridges 1051. Part of the connection bridge 1051 may be engaged with the main frame 2110. In addition, part of the connection bridge 1051 may be engaged with the main support 1210 of the oxygen generation part 530. The vibration of the air supply part 520 may be prevented from being transmitted to the main frame 2110 or the main bracket 1210 by the first damper 1060.

The second damper 1040 may include a bolt (bolt) shape at both ends. One end of the second damper 1040 may be engaged with a lower end of the compressor 1030. The other end of the second damper 1040 may be engaged with an upper end of the bottom surface of the air supplier housing 1050. The second damper 1040 may have a spring between its ends. The vibration of the compressor 1030 can be prevented from being transmitted to the air supplier housing 1050 by the second damper 1040.

The massage apparatus 100 according to the present invention prevents vibrations by the first damper 1060 and the second damper 1040 in a dual manner, so that a user can comfortably receive a massage.

Fig. 6 and 10 to 12 illustrate an example in which the air supply unit 520 and the oxygen generation unit 530 are disposed separately. But is not limited thereto. The massage device 100 may incorporate the air supply part 520 and the oxygen generation part 530 into one housing. The device in which the air supply part 520 and the oxygen generation part 530 are integrated is referred to as an integrated oxygen generation part. An embodiment in which the air supply unit 520 and the oxygen generation unit 530 are incorporated in one housing will be described with reference to fig. 20.

Fig. 20 is a view for explaining an integrated oxygen generating unit including an air supply unit and an oxygen generating unit.

The massage device 100 may include an integrated oxygen generating part 2000. The integrated oxygen generating part 2000 may be coupled with the main frame 2110. The damper may not be included between the main frame 2110 and the integrated oxygen generating part 2000. When the compressor 1030 included in the integrated oxygen generating part 2000 is coupled to the inside of the integrated oxygen generating part 2000, since the dual damper is used, the user does not feel vibration even though the damper is not included between the main frame 2110 and the integrated oxygen generating part 2000. But is not limited thereto. A damper may be used between the integrated oxygen generating part 2000 and the main frame 2110 to further reduce the magnitude of vibration.

The integrated oxygen generation section 2000 may include an integrated housing 2030. An inner surface of the integrated housing 2030 may use a soundproof material using a substance such as sponge or paper. The compressor 1030 integrated inside the housing 2030 may generate loud noise. Accordingly, the integrated housing 2030 may use a soundproof material to prevent noise of the compressor 1030 from being transmitted to a user. The noise of the compressor 1030 felt by the user can be reduced below about 37dB due to the use of the integrated housing 2030 of the soundproof material.

The compressor 1030 and the oxygen generator 530 may be installed inside the integrated housing 2030. Due to the modularized integrated oxygen generating part 2000, there is an effect that maintenance of the massage apparatus 100 becomes convenient.

The integrated oxygen generating part 2000 may internally include a third damper 2021. The third damper 2021 may correspond to the first damper 1060 of fig. 10. The integrated oxygen generating part 2000 may include a compressor holder 2023 inside. The compressor cage 2023 may be a structure for joining the compressor 1030 to the integrated housing 2030. The third damper 2021 may be located between the compressor cage 2023 and the integrated housing 2030. The integrated housing 2030 may include at least two third dampers 2021.

The third damper 2021 may prevent vibration of the compressor 1030 from being transferred to the integrated housing 2030. The third damper 2021 may be made of rubber, polyurethane, or silicone. The integrated oxygen generation section 2000 may include a compressor 1030. The compressor 1030 may induce vibration, which may be transmitted to a user along with the main frame 2110. The vibrations may prevent the user from comfortably receiving the massage. The third damper 2021 may prevent vibration of the compressor 1030 from being transmitted to a user along with the integrated housing 2030 and the main frame 2110.

The integrated oxygen generation part 2000 may include a compressor 1030 for generating oxygen. The compressor 1030 is installed inside the integrated housing 2030, and may be a device for sucking external air. The compressor 1030 may suck external air and supply it to the oxygen generation part 530. The compressor 1030 may generate vibration, noise, and heat. Noise can be reduced by the sound insulating material in the integrated housing 2030 and the integrated cover 2010. The vibration may be reduced by the third damper 2021 and the fourth damper 2022. Heat may be reduced by cooling fan 1010.

The integrated oxygen generating part 2000 may include a fourth damper 2022. The fourth damper 2022 may correspond to the second damper 1040 of fig. 10. Like the second damper 1040, the fourth damper 2022 may have an elastic coefficient for isolating a natural vibration frequency generated from the compressor 1030 for generating oxygen. The fourth damper 2022 may be used to couple the compressor 1030 to the compressor cage 2023. Both ends of the fourth damper 2022 may include a screw structure. One end of the fourth damper 2022 may be joined with the lower end of the compressor 1030. The other end of the fourth damper 2022 may be engaged with an upper end of a bottom surface of the compressor holder 2023.

In addition, the fourth damper 2022 may prevent vibration of the compressor 1030 from being transmitted to the compressor holder 2023 and the integration housing 2030. More specifically, the fourth damper 2022 includes a spring to prevent vibration of the compressor 1030 from being transmitted to the integrated housing 2030.

As described above, the vibration of the compressor 1030 may prevent the user from comfortably receiving the massage. The massage apparatus 100 according to the present invention may have a dual vibration preventing unit. That is, the third damper 2021 and the fourth damper 2022 can prevent the vibration of the compressor 1030 from being transmitted to the user along with the main frame 2110.

In addition, the massage apparatus 100 may include a fifth damper (not shown) between the integrated housing 2030 and the main frame 2110. The massage apparatus 100 may triple-prevent vibration using the third to fifth dampers 2021 to fifth dampers. Therefore, the user can comfortably receive the massage.

The integrated oxygen generation part 2000 may include a cooling fan 2011 for cooling the compressor 1030. The cooling fan 2011 may be at least one. The cooling fan 2011 may be variably controlled according to the temperature of the compressor 1030. For example, the massage device 100 may use a sensor to measure the temperature of the compressor 1030. The massage device 100 may increase the rotation speed of the cooling fan 2011 based on the temperature of the compressor 1030. The rotation speed of the cooling fan 2011 may be proportional to the temperature of the compressor 1030. When the temperature of the compressor 1030 is higher than a predetermined threshold value, the massage apparatus 100 may operate the cooling fan 2011.

Even after the operation of the compressor 1030 is stopped, the massage apparatus 100 may operate the cooling fan 2011 for 1 to 3 minutes again. Alternatively, even after the operation of the compressor 1030 is stopped, the massage apparatus 100 may operate the cooling fan 2011 until the temperature of the compressor 1030 is lower than the predetermined threshold value. Since the compressor 1030 is a device that generates a large amount of heat, a high temperature can be maintained even after the operation of the compressor 1030 is stopped. High temperatures can reduce the life of not only compressor 1030, but also peripheral devices. Therefore, the massage apparatus 100 can prevent the air supply part from maintaining an excessively high temperature by operating the cooling fan 2011.

Additionally, compressor 1030 may include an integrated cover 2010. The integrated cover 2010 may cover the open portion 2032 of the integrated housing 2030. An opening portion 2032 of the integrated housing 2030 may be formed at an upper end of the integrated housing 2030.

The integrated housing 2030 may include at least one air exhaust hole 2031. The cool air may be supplied to the integrated housing 2030 by the cooling fan 2011 installed at the integrated cover 2010. The supplied air may be heated by various devices included in the integrated oxygen generation part 2000. The hot air inside the integrated housing 2030 may escape through the at least one air exhaust hole 2031.

More specifically, the compressor 1030 may include a first cylinder chamber 1111 and a second cylinder chamber 1112. The cooling fan 1010 may blow cool air into the first cylinder chamber 1111 and the second cylinder chamber 1112. The cool air may cool the compressor 1030. In addition, the cold air may be heated by the compressor 1030. The internal air pressure of the integrated housing 2030 is raised by air supplied using the cooling fan 1010. In addition, since the supplied air is heated, the air pressure inside the integrated housing 2030 may be increased. Due to the air pressure difference, air heated by the compressor 1030 may escape from the integrated housing 2030 to the outside. The heated air may be discharged through at least one air discharge hole 2031. The integrated oxygen generation part 2000 having the structure of fig. 20 has an effect of effectively cooling the compressor 1030.

Fig. 13 is a diagram illustrating an oxygen generating part according to an embodiment of the present invention.

The oxygen generating part 530 may include an oxygen concentration module 1310, a main support 1210, and an oxygen concentration module holder 1330.

The oxygen concentration module 1310 may generate concentrated oxygen by concentrating oxygen from outside air. The oxygen concentration module 1310 may use a Pressure Swing Adsorption (PSA) method. The PSA method separates nitrogen and oxygen from air by using the selective adsorption force of an adsorbent (Zeolite). According to the PSA method, high-pressure air is passed through an adsorption column, and nitrogen and oxygen are produced by continuous operations of adsorption, pressure equalization, and desorption. Since the oxygen concentration module 1310 uses the PSA method, high purity oxygen of up to 99% can be generated.

The oxygen concentration module 1310 may use an adsorbent, such as zeolite. The oxygen concentrator module 1310 has high durability and thus may require less maintenance work. For example, the oxygen concentration module 1310 may guarantee 9000Hr performance. Accordingly, a user using the massage apparatus 100 of the present invention can be assured of the performance of the oxygen generation module that is continuously maintained. In addition, the manufacturer of the massage apparatus 100 according to the present invention can reduce additional costs due to the reduction of maintenance work.

Although only the PSA method is described above, the PSA method is not limited thereto. Temperature Swing Adsorption (TSA) may also be used. In addition, other various methods for generating oxygen may be used.

The main support 1210 may be engaged with a main frame 2110 of the massage device 100. Referring to fig. 12, the main support 1210 may include a support portion 1211. The support 1211 may be placed on the main frame 2110. In addition, the support 1211 and the main frame 2110 may be engaged by a screw.

In addition, a first damper 1060 may be placed on the main bracket 1210. The air supply section case 1050 may be placed on the first damper 1060. The main bracket 1210, the first damper 1060, and the air supply part case 1050 may be joined by screws.

Referring again to fig. 13, the oxygen concentration module holder 1330 may be a structure for engaging the main support 1210 and the oxygen concentration module. The oxygen concentration module holder 1330 may be placed on the main support 1210, and the main support 1210 and the oxygen concentration module holder 1330 may be engaged by screws.

The oxygen concentration module holder 1330 may be designed to grasp both sides of the oxygen concentration module 1310. The user may engage the oxygen concentration module 1310 with the oxygen concentration module holder 1330 simply by placing the oxygen concentration module 1310 on the oxygen concentration module holder 1330 and pressing the oxygen concentration module 1310. The structure in which the oxygen concentration module 1310 is fixed to the main support 1210 is explained with reference to fig. 14.

Fig. 14 illustrates an oxygen concentration module 1310, an oxygen concentration module holder 1330, and a main support 1210 according to an embodiment of the present invention.

Oxygen concentration module holder 1330 may include a first male clamp 1331 and a second male clamp 1332. The first male jig 1331 and the second male jig 1332 may be opposite to each other, and may protrude toward the oxygen concentration module 1310.

Both sides of the oxygen concentration module 1310 may include a first recess 1311 and a second recess (not shown). The first male clamp 1331 may be inserted into the first recess 1311 of the oxygen concentration module 1310. In addition, the second male clamp 1332 is inserted into a second recess (not shown) of the oxygen concentration module 1310 so that the oxygen concentration module may be engaged to the oxygen concentration module holder. For example, engagement site 1413 indicates that first male clamp 1331 is inserted into first recess 1311 of oxygen concentration module 1310.

Additionally, the oxygen concentrator module 1310 may be threadably coupled to the main support 1210. Specifically, referring to engagement 1411 and engagement 1412, oxygen concentrator module 1310 may be threadably coupled to main support 1210. One end of main support 1210 having engagement portion 1411 and engagement portion 1412 may be positioned in a leg direction of the user. In addition, the other end of the main support 1210 may be positioned in the direction of the user's head. Here, the leg direction of the user refers to the leg direction of the user when the user is seated on the massage apparatus 100.

As such, the oxygen concentration module 1310 is engaged with the oxygen concentration module holder 1330 or the main support 1210 in a simple manner, and thus a user may easily replace the oxygen concentration module 1310.

Referring again to fig. 13, the oxygen generating part 530 may include a regulator 1350. Regulator 1350 may maintain a constant pressure of the concentrated oxygen generated by the oxygen concentration module. The pressure of the concentrated oxygen generated by the oxygen concentration module 1310 may rise or fall sharply. When the pressure of the concentrated oxygen gas sharply rises or falls, a physical burden may be imposed on devices near the oxygen concentration module 1310, and the life span of the devices near the oxygen concentration module 1310 may be shortened. The regulator 1350 keeps the pressure of the concentrated oxygen gas constant, so that the physical burden of the peripheral devices can be reduced.

The oxygen generating part 530 may include a control board 1340. The oxygen generation part 530 may include a control panel bracket 1341. The control panel bracket 1341 may be a structure for securing the control panel 1340. Hereinafter, the control board 1340 is explained with reference to fig. 15.

Fig. 15 is a block diagram illustrating the structure of the control board 1340 according to an embodiment of the present invention.

The control board 1340 may include an oxygen generation control 1510. The oxygen generation control unit 1510 may be controlled by the control unit 300 of fig. 3. The control board 1340 may include an oxygen generation communication portion 1530. The control board 1340 may transmit and receive signals with the control part 300 of fig. 3 through the oxygen generation communication part 1530.

The control board 1340 may perform various functions related to the oxygen generation part 530 based on the signal of the control part 300. The control board 1340 may control at least one of a voltage supplied to the oxygen generating part 530, an air pressure of outside air supplied to the oxygen generating part 530, an oxygen concentration in the concentrated oxygen, and an air pressure of the concentrated oxygen.

The control board 1340 may control at least one valve to control an inflow amount or a discharge amount of the concentrated oxygen or the external air. The control board 1340 may be controlled based on a signal of the control part 300 of fig. 3. In addition, the control part 300 of fig. 3 may transmit a control signal to the control board 1340 based on a signal of the user input part 2180 or the massage apparatus control device 2200.

In addition, the control board 1340 may include an oxygen generation sensor part 1520. The oxygen generation sensor part 1520 may measure various values related to the oxygen generation part 530. The oxygen generation sensor unit 1520 may measure the oxygen concentration in the concentrated oxygen, the pressure of the concentrated oxygen, and at least one of the pressure of the compressed air flowing from the air supply unit 520 and the input voltage value of the oxygen generation unit 530. The oxygen generation sensor section 1520 may transmit the measurement value to the oxygen generation control section 1510 or the control section 300. The oxygen generation control section 1510 or the control section 300 may perform various operations based on the measured values.

The oxygen generating part 530 may include a pressure sensor for measuring a gas pressure. The pressure sensor may be included in the oxygen generation sensor part 1520. A pressure sensor may be included in the sensor portion 310. Referring to fig. 14, the control board 1340 may include an oxygen generation sensor part 1520. The control board 1340 and the oxygen concentration module 1310 may be connected by a pressure measuring tube 1420. The pressure sensor included in the control board 1340 may measure the pressure of the concentrated oxygen generated by the oxygen concentration module 1310. Alternatively, the pressure sensor may measure the pressure inside the oxygen concentration module 1310. Alternatively, the pressure sensor may measure the pressure inside the oxygen exhaust chamber 1840.

Referring again to fig. 15, the oxygen generation control unit 1510 may acquire the pressure of the concentrated oxygen from the pressure sensor. The oxygen generation control part 1510 may determine whether the oxygen concentration module is normally operated based on the pressure of the concentrated oxygen.

The oxygen generation control part 1510 may determine whether the pressure of the concentrated oxygen is greater than or equal to a predetermined first threshold value and less than a predetermined second threshold value. When the pressure of the concentrated oxygen is greater than or equal to the first threshold value and less than the second threshold value, the oxygen generation control part 1510 may determine that the oxygen generation part 530 normally operates. The oxygen generation controller 1510 may transmit a signal indicating that the oxygen generator 530 is normal to the controller 300.

When the pressure of the concentrated oxygen is less than the first threshold value or greater than or equal to the second threshold value, the oxygen generation control part 1510 may determine that the oxygen generating part 530 abnormally operates. The oxygen generation control unit 1510 may transmit a signal indicating an abnormality of the oxygen generation unit 530 to the control unit 300.

The control part 300 may take necessary measures based on the signal of the oxygen generation control part 1510. For example, the control part 300 may display on the display that the oxygen generation part 530 has a problem. In addition, the control part 300 may disconnect the power of the oxygen generation part 530 to protect the user from the abnormal operation of the oxygen generation part 530.

In addition, the control part 300 may receive information on the gas pressure of the oxygen gas discharge chamber from the pressure sensor. In addition, the control part 300 may output a signal indicating that the life of the zeolite included in the oxygen generation part is exhausted when the information on the gas pressure is less than or equal to the first threshold value and greater than the third threshold value. At this time, the first threshold may be greater than the third threshold. The third threshold may be a predetermined value. The user can know the zeolite replacement period based on the output signal and replace the zeolite. Therefore, the massage apparatus 100 can provide optimal oxygen to the user.

In addition, when the information on the gas pressure is less than or equal to the third threshold value, the control part 300 may output a signal indicating that the oxygen generating part 530 is out of order. If the information on the gas pressure is less than the third threshold value, the gas of the oxygen generation unit 530 may flow out, the air supply unit 520 may be abnormal, or a part of the pipe included in the oxygen generation unit 530 may be clogged. The user can quickly recognize that the massage apparatus 100 is abnormal, and can quickly respond to the abnormality.

The duct of the oxygen generation unit 530 will be described below with reference to fig. 16.

Fig. 16 is a view for explaining a pipe of an oxygen generation part according to an embodiment of the present invention.

The control board 1340 and the oxygen concentration module 1310 may be connected by a pressure measuring tube 1420. Since the pressure-measuring tube 1420 has already been described, a repetitive description will be omitted.

The air supply unit 520 and the oxygen generation unit 530 may be connected by a first tube 1630. The compressed air generated from the air supplier 520 may flow to the oxygen generator 530 through the first pipe 1630. The first tube 1630 may have a hardness capable of withstanding the pressure of the compressed air.

The oxygen concentration module 1310 may generate concentrated oxygen based on the external air supplied by the air supply 520. The concentrated oxygen generated by the oxygen concentration module 1310 may be dry. This is because the oxygen concentration module 1310 is not additionally supplied with moisture, and a part of moisture contained in the external air sucked through the first tube 1630 is absorbed by the oxygen concentration module 1310. Since the concentrated oxygen is dried, the inside of the tube included in the massage apparatus 100 may be dried, and mold may not be generated. Therefore, the concentrated oxygen inhaled by the user is hygienic, and there is no odor due to mold.

The concentrated oxygen may move to the regulator 1350 through the second tube 1610. The pressure of the enriched oxygen generated by the oxygen enrichment module 1310 may be variable. The regulator 1350 may change the pressure of the concentrated oxygen to be constant and output.

The regulator 1350 and the output valve may be connected through a third pipe 1620. The concentrated oxygen having a prescribed pressure by means of the regulator 1350 may be moved from the regulator 1350 to an output valve. The output valve may be controlled by the oxygen generation control section 1510. The output valve may or may not discharge the concentrated oxygen to the discharge pipe 1640 based on a signal of the oxygen generation control part 1510. However, the concentrated oxygen gas having a predetermined pressure may flow into the discharge pipe 1640 without passing through the output valve.

The discharge pipe 1640 may be connected to a flow line pipe. The flow pipe is connected to an oxygen outlet 540, and the oxygen outlet 540 may supply concentrated oxygen to a user.

Fig. 17 is a view for explaining a pipe of an oxygen generation part according to an embodiment of the present invention.

The oxygen generation controller 1510 may change the mode of the oxygen generator 530 or stop the operation of the oxygen generator 530 based on the received signal. The oxygen generation control part 1510 may receive a signal from the control part 300.

When a predetermined condition is satisfied, the control part 300 may transmit a control signal to the oxygen generation control part 1510. In addition, the control part 300 of fig. 3 may determine whether to transmit a signal to the oxygen generation control part 1510 based on an input signal of the user input part 2180 or the massage apparatus control device 2200. In addition, the control part 300 may operate the oxygen generating part 530 in one of a plurality of modes based on an input signal of the user input part 2180 or the massage apparatus control device 2200.

The oxygen generation part 530 may include a first valve 1710. The first valve 1710 may be a structure for mixing external air into the concentrated oxygen generated by the oxygen concentration module 1310. The first valve 1710 may be controlled by the oxygen generation control portion 1510.

The discharge pipe 1640 may include a first discharge pipe 1641 and a second discharge pipe 1642. The first exhaust pipe 1641 may be connected to the first valve 1710. When the first valve 1710 is opened, external air may flow into the first exhaust pipe 1641. When the first valve 1710 is closed, the external air does not flow into the first exhaust pipe 1641.

The second discharge pipe 1642 may be a pipe through which concentrated oxygen having a prescribed pressure supplied from the regulator 1350 flows. That is, the third pipe 1620 may be connected to the second discharge pipe 1642.

When the first valve 1710 is opened, the outside air of the first discharge pipe 1641 is mixed with the concentrated oxygen of the second discharge pipe 1642 and is delivered to the user through the flow line pipe. In this case, the flow rate through the flow path pipe can be increased by the outside air, but the oxygen concentration is decreased.

When the first valve 1710 is closed, the concentrated oxygen of the second discharge tube 1642 may be delivered to the user through the flow line tube. Since the outside air is not supplied to the flow path pipe, the flow rate flowing through the flow path pipe is small. However, the oxygen concentration of the gas flowing through the flow path pipe may be high.

The user input 2180 or the massage device control apparatus 2200 may include a button for changing the mode of the oxygen generating device. The button may be a physical button, and may be an icon displayed on the screen in a software manner. The user may change the mode of the oxygen generating device by pressing a button. For example, at least one mode may be altered as follows: first mode- > second mode- > nth mode- > turn OFF (OFF) - > first mode. Wherein OFF (OFF) indicates that the oxygen generation device is finished operating. The control part 300 may transmit a signal to the oxygen generation control part 1510 based on a signal from the user input part 2180 or the massage apparatus control device 2200. The signal may be related to a mode of the oxygen generating device. The oxygen generation device may control the amount of oxygen generation or the concentration of oxygen, etc. based on the received signal.

In addition, the massage device 100 may include a plurality of massage modes. The massage apparatus 100 may store a mode of the oxygen generating apparatus corresponding to the massage mode. The control unit 300 may transmit a signal to the oxygen generation control unit 1510 according to the massage mode received by the user. The signal may be related to a mode of the oxygen generating device. The oxygen generation control unit 1510 may change the mode of the oxygen generation device based on the received signal.

When the signal received from the control part 300 indicates the first mode, the oxygen generation control part 1510 closes the first valve 1710 and operates the oxygen generation part 530 such that only the concentrated oxygen generated by the oxygen concentration module 1310 is supplied to the flow path pipe.

In the first mode, the concentrated oxygen is generated at 1L/min, and the concentration of oxygen in the concentrated oxygen may be 80% to 90%. Referring to fig. 17, when the oxygen generation control part 1510 closes the first valve, external air may not be supplied to the first exhaust pipe 1641. The oxygen generation controller 1510 may discharge the concentrated oxygen from the second discharge pipe 1642 to the flow path pipe. Wherein the concentrated oxygen may be concentrated oxygen whose pressure is changed to be constant by the regulator 1350. The concentrated oxygen may be delivered to the user through a flow line.

When the signal received from the control part 300 indicates the second mode, the oxygen generation control part 1510 opens the first valve 1710 and operates the oxygen generation part 530 to mix the concentrated oxygen generated by the oxygen concentration module 1310 with the external air and supply to the flow path pipe.

In the second mode, the concentrated oxygen is generated at 2L/min, and the concentration of oxygen in the concentrated oxygen may be 45% to 55%. The second mode may be a high flow rate and a low oxygen concentration in the flow path pipe, compared to the first mode. Referring to fig. 17, when the oxygen generation control part 1510 opens the first valve, external air may be supplied to the first exhaust pipe 1641. The oxygen generation controller 1510 may discharge the concentrated oxygen from the second discharge pipe 1642 to the flow path pipe. Wherein the concentrated oxygen may be concentrated oxygen whose pressure is changed to be constant by the regulator 1350. The outside air of the first exhaust pipe 1641 is mixed with the concentrated oxygen of the second exhaust pipe 1642 and is delivered to the user through the flow line pipe.

When the signal received from the control part 300 indicates the third mode, the oxygen generation control part 1510 may increase the power supplied to the oxygen concentration module 1310 or the air supply part 520. For example, the oxygen generation controller 1510 may increase the voltage or current supplied to the oxygen concentration module 1310 or the air supplier 520. In addition, the oxygen generation control part 1510 may close the first valve. Since the first valve is closed, the external air may not flow from the first exhaust pipe 1641 into the flow path pipe.

When the power, voltage, or current supplied to the oxygen concentration module 1310 or the air supplier 520 is increased, the oxygen concentration module 1310 may generate concentrated oxygen of higher purity. For example, in the third mode, the concentrated oxygen is generated at 1L/min, and the concentration of oxygen in the concentrated oxygen may be 90% to 100%.

But not limited thereto, the massage apparatus 100 may not include the first to third modes, and the oxygen may be supplied in one mode. The massage device 100 may generate gas including 50% or more and 60% or less of oxygen in an amount of 1.5 liters or more and 2.5 liters or less per minute using the oxygen generation unit 530. In addition, the massage device 100 can discharge the gas generated from the oxygen generating part through the oxygen discharge port 540. The massage device 100 may stop or start the operation of the oxygen generation part 530 based on the user's selection. The user may selectively inhale more than 50% and less than 60% of oxygen in an amount of about 2L per minute.

Fig. 18 is a block diagram for explaining an oxygen concentration module according to an embodiment of the present invention.

The oxygen concentration module 1310 may include a first oxygen concentration chamber 1810 and a second oxygen concentration chamber 1820. The first and second oxygen concentrating chambers 1810 and 1820 include a substance for absorbing nitrogen, and concentrated oxygen may be generated from the outside air. The substance for absorbing nitrogen may be zeolite. But is not limited thereto.

The first oxygen concentrating chamber 1810 and the second oxygen concentrating chamber 1820 may alternately operate at a predetermined time period. The predetermined period may be 5 minutes to 20 minutes. The first and second oxygen concentrating chambers 1810 and 1820 may absorb nitrogen and generate concentrated oxygen under certain conditions. In addition, the first and second oxygen concentrating chambers 1810 and 1820 may discharge adsorbed nitrogen gas under other specific conditions. The second oxygen concentrating chamber 1820 may vent the absorbed nitrogen gas while the first oxygen concentrating chamber 1810 generates concentrated oxygen. In contrast, when the second oxygen concentrating compartment 1820 generates concentrated oxygen, the first oxygen concentrating compartment 1810 may vent the absorbed nitrogen.

The oxygen concentration module 1310 may include a nitrogen exhaust chamber 1830 for exhausting the concentrated nitrogen. The nitrogen gas exhaust chamber may be a place where nitrogen gas exhausted from the first oxygen concentrating chamber 1810 or the second oxygen concentrating chamber 1820 is collected. The concentrated nitrogen gas of the nitrogen gas exhaust chamber 1830 may be exhausted through the nitrogen gas exhaust pipe. The nitrogen gas discharge pipe may be connected to a space separated from the space where the massage apparatus 100 is located. Therefore, the user can be prevented from sucking the generated nitrogen gas. In addition, the massage device 100 may include a nozzle for blowing concentrated nitrogen gas into the packing container. The user can store food for a long time using concentrated nitrogen gas. The massage apparatus 100 may discharge nitrogen gas from the nozzle based on the control part 300 or the input of the user. The user may fill the sealed bag with food along with the concentrated nitrogen gas.

The oxygen concentration module 1310 may include an oxygen exhaust chamber 1840. The oxygen outlet chamber 1840 may receive concentrated oxygen from at least one of the first oxygen concentrating chamber and the second oxygen concentrating chamber. The concentrated oxygen gas can flow to the flow path pipe under the control of the oxygen generation control unit 1510.

The oxygen concentration module 1310 may include second to seventh valves. The second valve 1851 may be located between the air supply 520 and the first oxygen concentrating chamber 1810. The second valve 1851 may control the flow of gas between the air supply 520 and the first oxygen concentrating chamber 1810. The second valve 1851 may be controlled by the oxygen generation control part 1510.

The third valve 1852 may be located between the air supply 520 and the second oxygen concentrating chamber 1820. The third valve 1852 may control the flow of gas between the air supply 520 and the second oxygen concentrating chamber 1820. The third valve 1852 may be controlled by the oxygen generation control part 1510.

The fourth valve 1853 may be located between the first oxygen concentrating chamber 1810 and the oxygen exhaust chamber 1840. The fourth valve 1853 may control the flow of gas between the first oxygen concentration chamber 1810 and the oxygen exhaust chamber 1840. The fourth valve 1853 may be controlled by the oxygen generation control part 1510.

The fifth valve 1854 may be positioned between the second oxygen concentrating chamber 1820 and the oxygen discharging chamber 1840. The fifth valve 1854 may control the flow of gas between the second oxygen concentrating chamber 1820 and the oxygen discharging chamber 1840. The fifth valve 1854 may be controlled by the oxygen generation control part 1510.

The sixth valve 1855 may be located between the first oxygen concentration chamber 1810 and the nitrogen vent chamber 1830. The sixth valve 1855 may control the flow of gas between the first oxygen concentration chamber 1810 and the nitrogen vent chamber 1830. The sixth valve 1855 may be controlled by the oxygen generation control part 1510.

The seventh valve 1856 may be positioned between the second oxygen concentrating chamber 1820 and the nitrogen vent chamber 1830. The seventh valve 1856 may control the flow of gas between the second oxygen concentrating chamber 1820 and the nitrogen discharging chamber 1830. The seventh valve 1856 may be controlled by the oxygen generation control part 1510.

Hereinafter, operations of the second to seventh valves 1851 to 1856 will be described. First, a process in which the first oxygen concentrating chamber 1810 generates concentrated oxygen and the second oxygen concentrating chamber 1820 discharges nitrogen will be described.

The oxygen generation control part 1510 may open the second valve 1851 to supply the external air from the air supply part 520 to the first oxygen concentrating chamber 1810. The substance contained in the first oxygen concentrating chamber 1810 adsorbs nitrogen from the outside air and generates concentrated oxygen.

The oxygen generation controller 1510 may close the third valve 1852 so that external air is not supplied from the air supplier 520 to the second oxygen concentrating chamber 1820. The second oxygen concentrating chamber 1820 may contain a substance to discharge nitrogen gas. The oxygen generation controller 1510 may control the temperature or pressure of the second oxygen concentrating chamber 1820 to make a condition that the substance of the second oxygen concentrating chamber 1820 can discharge nitrogen gas.

The oxygen generation controller 1510 may open the fourth valve 1853 to supply the concentrated oxygen generated in the first oxygen concentrating chamber to the oxygen discharging chamber 1840. The concentrated oxygen in the oxygen outlet chamber 1840 can be supplied to the user through the discharge pipe 1640 and the flow pipe.

The oxygen generation controller 1510 may close the fifth valve 1854 so as not to supply the gas of the second oxygen concentrating chamber to the oxygen discharging chamber. As described above, the second oxygen concentrating chamber 1820 may contain a gas containing a large amount of nitrogen. Accordingly, the gas including nitrogen may be prevented from flowing into the oxygen exhaust chamber 1840.

The oxygen generation controller 1510 may close the sixth valve 1855 so that the concentrated oxygen generated in the first oxygen concentrating chamber 1810 is not supplied to the nitrogen discharging chamber 1830. Therefore, the concentrated oxygen can be prevented from being unnecessarily discarded.

In addition, the oxygen generation controller 1510 may open the seventh valve 1856 to supply the gas of the second oxygen concentrating chamber 1820 to the nitrogen gas exhaust chamber 1830. The nitrogen exhaust chamber 1830 may collect nitrogen. The massage device 100 may include a nitrogen gas discharge pipe. The nitrogen gas discharge pipe may be connected to a space separated from the space where the massage apparatus 100 is located. That is, the generated concentrated nitrogen gas may be discharged to a space separated from the space where the massage apparatus 100 is used. Therefore, oxygen in the space where the user is located increases. For example, if the massage device 100 is located indoors, the concentrated nitrogen gas may be discharged outdoors.

In addition, when it is necessary to stop the oxygen supply according to the user's input or the decision of the control part 300, the oxygen generation control part 1510 may close the fourth valve 1853 and open the sixth valve 1855. Thus, the concentrated oxygen generated in the first oxygen concentrating chamber 1810 may be discarded through the nitrogen vent chamber 1830.

Next, a process in which the second oxygen concentrating chamber 1820 generates concentrated oxygen and the first oxygen concentrating chamber 1810 discharges nitrogen will be described.

The oxygen generation control part 1510 may close the second valve 1851 so that the external air is not supplied from the air supply part 520 to the first oxygen concentrating chamber 1810. The contents of the first oxygen concentrating chamber 1810 may be purged of nitrogen. The oxygen generation control part 1510 may control the temperature or pressure of the first oxygen concentrating chamber 1810 to make a condition that the substance of the first oxygen concentrating chamber 181 can discharge nitrogen gas.

The oxygen generation controller 1510 may open the third valve 1852 to supply external air from the air supplier 520 to the second oxygen concentrating chamber 1820. The second oxygen concentrating chamber 1820 adsorbs nitrogen from the outside air and generates concentrated oxygen.

The oxygen generation control part 1510 may close the fourth valve 1853 not to supply the gas of the first oxygen concentrating chamber to the oxygen discharging chamber. As described above, first oxygen concentrating chamber 1810 may contain a gas containing a substantial amount of nitrogen.

The oxygen generation controller 1510 may open the fifth valve 1854 to supply the concentrated oxygen generated in the second oxygen concentrating chamber to the oxygen exhaust chamber 1840. The concentrated oxygen in the oxygen outlet chamber 1840 can be supplied to the user through the discharge pipe 1640 and the flow pipe.

In addition, the oxygen generation controller 1510 may open the sixth valve 1855 to supply the gas of the first oxygen concentrating chamber 1810 to the nitrogen gas exhaust chamber 1830. The nitrogen exhaust chamber 1830 may collect nitrogen. The massage device 100 may include a nitrogen gas discharge pipe. The nitrogen gas discharge pipe may be connected to a space separated from the space where the massage apparatus 100 is located. That is, the generated concentrated nitrogen gas may be discharged to a space separated from the space where the massage apparatus 100 is used. Therefore, oxygen in the space where the user is located increases. For example, if the massage device 100 is located indoors, the concentrated nitrogen gas may be discharged outdoors.

The oxygen generation controller 1510 may close the seventh valve 1856 so that the concentrated oxygen generated in the second oxygen concentrating chamber 1820 is not supplied to the nitrogen discharging chamber 1830. Therefore, the concentrated oxygen can be prevented from being unnecessarily discarded.

In addition, when it is necessary to stop the supply of oxygen according to the user's input or the decision of the control part 300, the oxygen generation control part 1510 may close the fifth valve 1854 and open the seventh valve 1856. Therefore, the concentrated oxygen generated in the second oxygen concentrating chamber 1820 may be discarded through the nitrogen exhaust chamber 1830.

The nitrogen discarded through the nitrogen exhaust chamber 1830 may be compressed by a compressor. The massage device 100 may be used for nitrogen packaging. The gas collected in the nitrogen exhaust chamber 1830 may include almost no oxygen. Therefore, oxidation of the object to be stored can be prevented. In addition, when nitrogen gas is filled, the object to be stored can be protected by the gas without being broken. The massage device 100 may include a nitrogen gas discharge port, and the packing container may include a nitrogen gas suction port capable of receiving nitrogen gas from the massage device 100. The massage device 100 may discharge compressed nitrogen based on the user's input. The discharged nitrogen gas may fill the packaging container. The packaging container can seal the object and the nitrogen gas.

Fig. 19 is a view illustrating an oxygen discharge port according to an embodiment of the present invention.

Fig. 19 may be a different embodiment than fig. 9. The oxygen discharge port 1910 is formed above the head of the user in the left-right direction. The left-right direction may refer to a left-right direction when the user sits on the massage apparatus 100. The oxygen outlet 1910 may be linear. The oxygen outlet 1910 may face the user, discharging concentrated oxygen downward. In addition, the oxygen outlet 1910 may discharge concentrated oxygen toward the face of the user. That is, the oxygen outlet 1910 may not discharge concentrated oxygen to the hindbrain of the user.

The massage device 100 may include a concentrated oxygen intake 1920 for inhaling concentrated oxygen, the concentrated oxygen intake 1920 being located at the shoulder portion of the user. A part of the concentrated oxygen discharged through the oxygen discharge port 1910 may be inhaled by the user. The remaining concentrated oxygen may be drawn into concentrated oxygen intake 1920 along with ambient air. The air sucked into the concentrated oxygen suction port 1920 may be discharged to a place where there is no user. In addition, the air sucked into the concentrated oxygen suction port 1920 may be used again by the oxygen generation part 530 to generate concentrated oxygen.

The flow of concentrated oxygen may be generated through the oxygen outlet 1910 and the concentrated oxygen inlet 1920. In addition, due to the flow of the concentrated oxygen, an effect of collecting a large amount of oxygen on the face of the user may be generated. Therefore, the user can inhale the concentrated oxygen without using the rod-shaped discharge port shown in fig. 9. In this case, the massage device 100 has a simple design, and thus not only provides the user with an aesthetic satisfaction, but also has an effect of improving the durability of the discharge port.

According to another embodiment, the oxygen discharge ports 1930 may be formed in the direction of the main frame 2110 at the left and right sides of the user. The left and right sides may refer to the left and right sides of the user when seated on the massage device 100. The oxygen vent 1930 may be linear. The oxygen vent 1930 may vent the concentrated oxygen upward toward the user. In addition, the oxygen vent 1930 may vent concentrated oxygen to the user's face. That is, the oxygen outlet 1930 may not discharge concentrated oxygen to the back of the brain of the user.

The massage device 100 may include a concentrated oxygen intake 1940 for inhaling concentrated oxygen, the concentrated oxygen intake 1940 being located at a top of the head of the user. A portion of the concentrated oxygen discharged through the oxygen discharge port 1930 may be inhaled by the user. The remaining concentrated oxygen may be drawn into the concentrated oxygen intake 1940 along with ambient air. The air sucked into the concentrated oxygen suction port 1940 may be discharged to a place where there is no user. In addition, the air sucked into the concentrated oxygen suction port 1940 may be used again by the oxygen generating part 530 to generate concentrated oxygen.

Referring to fig. 9 and 19, the oxygen vents 540, 1910, 1930 may include a second filter to prevent a user from inhaling foreign matter. That is, the concentrated oxygen moving along the flow path pipe may pass through the second filter before being discharged through the oxygen discharge ports 540, 1910, 1930. The second filter filters and discharges dust or harmful substances that may be present in the air supply part 520, the oxygen generation part 530, and the flow path pipe. Thereby, the massage apparatus 100 can not only discharge oxygen but also perform an air purification function.

The second filter may include flavor nanocapsules. The user can feel the fragrance while inhaling the concentrated oxygen. The flavor nanocapsule is prepared by packaging flavor substances in nanocapsules. When an impact is applied to the nanocapsules, the capsules rupture, allowing the flavor in the capsules to escape. In addition, the user may smell a scent. The concentrated oxygen may exert pressure on the second filter and the nanocapsules in the second filter may rupture under force. The user can smell the fragrance while inhaling the oxygen. The flavor nanocapsule may be aromatic. The user can calm the body and mind while smelling the aromatic odor.

The massage device 100 may include a third filter. The flavor nanocapsules may not be included in the second filter but in the third filter. The massage device 100 may use a valve to control the flow of the concentrated oxygen. The massage device 100 may filter fine dusts or harmful substances through the second filter. The second filter and the third filter may be connected in parallel. The flow of the concentrated oxygen through the second filter may be uncontrolled. The massage apparatus 100 may determine whether to open the valve according to a user's input or a predetermined condition of the control part 300. When the massage apparatus 100 opens the valve according to the user's input or a predetermined condition of the control part 300, the concentrated oxygen may flow to the third filter side, and the user may smell a fragrance in the concentrated oxygen passing through the third filter. In addition, when the massage apparatus 100 closes the valve according to the user's input or the predetermined condition of the control part 300, the concentrated oxygen does not flow to the third filter side, and the user can inhale the clean concentrated oxygen passing through the second filter.

The oxygen generation control part 1510 or the control part 300 may acquire the physical state or the massage pattern of the user. The user can input his or her body state or massage mode through the user input section 2180 or the massage apparatus control device 2200. The physical state can be expressed as an index for the degree of fatigue. The massage mode may include at least one of a concentration mode, a meditation mode, a recovery mode, an extension mode, a sleep mode, a vitality mode, a golf mode, a hip shaping mode, an examinee mode, a weightlessness mode, and a growth mode. The massage apparatus 100 may change a massage manner according to a massage mode.

In addition, the massage apparatus 100 may acquire the physical state of the user using a sensor. The physical state of the user may be related to fatigue, stress index. The massage device 100 may use sensors to measure the user's steps, heart rate, blood pressure, blood glucose, or electrocardiogram. The massage device 100 may determine an index related to the fatigue or stress index of the user based on the number of steps, the heart rate, the blood pressure, the blood glucose, or the electrocardiogram of the user. For example, when the number of steps is large, it can be determined that the user's fatigue is high. When the heart rate is high, it may be determined that the stress index is high.

The oxygen generation control part 1510 or the control part 300 may adjust the oxygen concentration included in the concentrated oxygen based on the physical state of the user or the massage mode. For example, the oxygen generation controller 1510 or the controller 300 may store the amount of concentrated oxygen or the concentration value of oxygen in the concentrated oxygen corresponding to the massage mode. The oxygen generation controller 1510 or the controller 300 may provide the user with an amount of oxygen or a concentration of oxygen corresponding to the massage mode the user is receiving. The oxygen generation controller 1510 or the controller 300 may increase the amount of the concentrated oxygen according to an increase in fatigue or an increase in pressure of the user. The oxygen generation controller 1510 or the controller 300 may increase the oxygen concentration in the concentrated oxygen according to the increase in fatigue and the increase in pressure of the user. The fatigue or stress index may be proportional to the amount of concentrated oxygen or the concentration of concentrated oxygen.

The oxygen generation control unit 1510 or the control unit 300 may acquire noise of the air supply unit 520 through a microphone. The oxygen generation controller 1510 or the controller 300 may generate an inverse wave of noise. The oxygen generation controller 1510 or the controller 300 may control the speaker to output an inverse wave to cancel out the noise of the air supplier 520. Accordingly, the user can receive a massage in a comfortable state without feeling noise generated from the air supply part 520.

The oxygen generation control 1510 or the control 300 may sense a situation where oxygen generation is required or not required. The oxygen generation control part 1510 or the control part 300 may control to increase or decrease oxygen generation.

The sensor portion 310 may include a dust measurement sensor. The oxygen generation control part 1510 or the control part 300 may perform a step for measuring the concentration of fine dust or fine particulate matter. When the concentration of the fine dust or the fine particulate matter is equal to or higher than the reference value, the step of operating the oxygen generation part 530 may be performed. The reference value of the concentration of the fine dust or the fine particulate matter notified by the environment section may be stored in the memory 330 in advance or updated in real time by an external device through the communication section 320 according to the environment standard. The reference value of the concentration of the fine dust or the fine particulate matter may be directly input through the user input portion 2180 or the massage apparatus control device 2200. In the dust forecast reference determined by the notification of the environmental department, the upper limit concentration along with the 'ordinary' is from the current 50 mug/m³Down to 35. mu.g/m³The "bad" interval is from 50 μ g/m³To 100. mu.g/m³Strengthening to 36. mu.g/m³To 75. mu.g/m³The "very poor" interval is from 76. mu.g/m³And starting. Therefore, the reference value of the dust particle concentration stored in the control unit can be updated as needed. May include the step of supplying the concentrated oxygen generated from the operating oxygen generating part to the flow path pipe. A step of providing the concentrated oxygen to the user through the flow path pipe may be included. During the process of generating oxygen, massageThe device 100 may pass at least outside air through at least one filter. The air supplied from the massage device 100 is air from which fine dust is removed by a filter, and may be air having a high oxygen concentration.

According to an embodiment of the present invention, the sensor portion 310 may include a fire sensor. The oxygen generation control part 1510 or the control part 300 may perform a step of sensing a fire condition by a fire sensor. The fire sensor may include one or more of a heat sensor, a temperature sensor, a smoke sensor, and a gas sensor, but is not limited thereto. The oxygen generation control part 1510 or the control part 300 sensing the fire condition may include a step of stopping the generation of oxygen in the fire condition. The oxygen generation control unit 1510 or the control unit 300 that stops generating oxygen may perform the step of stopping discharging the concentrated oxygen. Blocking the oxygen supply may reduce the risk of additional explosions in case of fire conditions.

According to an embodiment of the utility model, the massage mode may comprise a headache mode. The headache mode may be set by the user input 2180 or the massage apparatus control device 2200. The oxygen generation controller 1510 or the controller 300 receives the input of the headache mode, and controls the oxygen generator 530 to start discharging oxygen or increase the oxygen discharge amount. Based on the received signal, the oxygen generation part 530 may start operation or adjust the amount of oxygen generation.

In addition, the control part 300 may not include the headache mode alone. The control part 300 may receive a signal indicating a user's headache through the user input part 2180 or the massage apparatus control device 2200. The control part 300 may provide a massage in a massage mode of discharging the maximum amount of oxygen based on the received signal, the massage mode including a concentration mode, a meditation mode, a recovery mode, an extension mode, a sleep mode, a vitality mode, a golf mode, a hip shaping mode, an examinee mode, a weightlessness mode, and a growth mode.

According to an embodiment of the present invention, the control part 300 may perform the step of acquiring the heart rate in the physical state of the user. When the acquired heart rate of the user is faster than the average heart rate of each age group, a step of the oxygen generation control section 1510 generating oxygen may be included. The oxygen generation control portion 1510 or the control portion 300 may adjust the oxygen discharge amount in proportion to the acquired heart rate. The average heart rate for each age group may be stored by memory 330. The average heart rate for adults over 16 to under 65 may be 60 to 100 beats/minute, for adults over 65 may be 55 to 80 beats/minute, and for immature adults under 16 may be 65 to 135 beats/minute.

According to an embodiment of the present invention, the body massage portion 2100 and the leg massage portion 2300 may further include: a skin heat and/or skin color sensing sensor, and a light wave emitting portion for emitting a light wavelength. The user can use the massage device with the naked skin or with clothes. The sensor portion 310 may also include skin heat and/or skin tone sensing sensors. The control part 300 may include a step of sensing skin heat and/or skin color of the user through a skin heat and/or skin color sensing sensor. The control part 300 may perform the step of transmitting a control signal to cause the light wave emitting part to emit a light wavelength suitable for the sensed skin heat and/or skin color. A step of the light wave emitting part emitting a light wavelength suitable for a signal received through the control part 300 may be included. This has the following effects: the skin of the user, which is stimulated by rubbing by the massage module 2170, is quickly sedated by exposing the skin to the light wavelengths.

According to an embodiment of the utility model, the intensity of the massage pattern may be switched by a skin heat and/or skin tone sensing sensor. The control part 300 may perform the step of sensing the skin color and/or heat before or during the current massage through the skin heat and/or skin color sensing sensor. The control part 300 may set the current massage intensity according to the sensed skin color and/or heat. The control part 300 may transmit a set massage intensity signal, and the massage module increases or decreases the massage intensity according to the received massage intensity signal. The user can preset the massage intensity through the input part 350. The memory 330 may store the massage intensity.

According to an embodiment of the present invention, the user name may be designated through the input part 350 and/or the display. The control unit 300 may generate a use list of the user from the designated name. The user's usage list may be stored in memory 330. The control part 300 may control to sense the body structure of the user according to the stored user name. The memory 330 may store the sensed body structure according to the user name. The memory 330 may store the massage pattern use details and the oxygen use details according to the user name. The user may query the user's list of oxygen usage details and the user's body structure via the display. The control portion 300 may sense the body structure of the user seated on the massage apparatus 100. The control part 300 may recognize the user based on the body structure. The control unit 300 may acquire the massage pattern use details and the oxygen use details based on the identified user. The control part 300 may provide the user with a massage based on the massage pattern usage particulars and the oxygen usage particulars.

The massage device 100 may include a sensor for sensing whether the user is seated on the massage device 100. When it is determined that the user is seated in the massage apparatus 100, the massage apparatus 100 may measure the body structure of the user. The user can measure the body structure by just sitting on the massage device without additional input. In addition, the massage apparatus 100 may automatically recognize the user based on the body structure of the user. In addition, the massage apparatus 100 may automatically select a massage mode according to the recognized user. The selected massage pattern may be a massage pattern mainly used by the user in the past based on the massage pattern usage details. In addition, the massage apparatus 100 may determine whether to automatically supply oxygen or the oxygen supply amount based on the identified user. The massage apparatus 100 may determine whether to automatically supply oxygen or the oxygen supply amount based on the oxygen use details. All the processes are automatically performed without additional selection, and the user can receive a massage based on his favorite past pattern, so that the user's satisfaction is high.

Fig. 24 is a flowchart illustrating an operating method of the massage apparatus according to an embodiment of the present invention.

The control unit 300 may execute step 3410 of acquiring identification information of the fragrance kit. For example, the massage device 100 may include a photographing part. The photographing part may photograph a bar code (bar code) or a QR code on the fragrance kit. The control part 300 may acquire identification information of the fragrance kit based on the barcode or QR code image photographed by the photographing part.

According to various embodiments of the present invention, the massage device 100 may include a communication portion 320. In addition, the fragrance kit 3240 may include a processor, memory, or communication section. The massage device 100 may communicate with the fragrance kit in a wired or wireless manner. The control part 300 may request the identification information from the fragrance kit using the communication part 320. In addition, the fragrance kit 3240 may transmit identification information to the massage apparatus 100 in response to a request of the control part 300. The control part 300 may receive identification information of the fragrance kit.

According to various embodiments of the present invention, the massage device 100 may receive identification information of the fragrance kit 3240 from the user.

The control part 300 controls the actuator or the air bag to provide a massage to the user based on the massage pattern according to the identification information of the fragrance kit.

More specifically, the control part 300 may perform step 3420 of selecting information on one massage mode among information on a plurality of massage modes stored in advance based on the identification information of the fragrance kit 3240. For example, the plurality of pre-stored massage modes may include at least one of a cardiac image mode, a concentration mode, a health mode, a relaxation training mode, a breathing relaxation mode, an early-safety mode, and a late-safety mode.

The psychographic mode of the massage apparatus 100 uses a method of treating psychology by focusing the user on a certain specific image in the heart. Through the psychogram mode, the user can relax, relieve stress, maintain positive mood, and can relieve psychological symptoms.

The portrait mode of the massage apparatus 100 may provide audio or images while providing a massage to the user. The information on the massage pattern includes: at least one of information on audio to be output when the massage is provided to the user, information on images to be output when the massage is provided to the user, information on oxygen to be provided when the massage is provided to the user, information on fragrance to be output when the massage is provided to the user, and information on at least one massage manner of the massage modes.

The massage pattern may correspond to a massage pattern list. The massage pattern list may be different according to the massage pattern. The different massage pattern lists may be predetermined according to the massage patterns. The list of massage modes may include a plurality of massage modes. The massage pattern list may be a list in which massage patterns to be performed by the massage apparatus 100 are arranged in chronological order. The massage device may be executed starting from the topmost massage pattern of the list of massage patterns. The massage apparatus may provide a massage to the user by sequentially performing a plurality of massage modes included in the massage mode list.

The massage pattern may be defined by information on the massage pattern. The information on the massage manner may indicate a combination of at least one of information on a massage type, a massage time, a massage intensity, a massage position, a temperature of the massage device, and a massage posture. The information included in the massage mode will be described in detail below.

The massage position may refer to a body part of the user that the massage apparatus 100 massages. The massage device 100 is controlled in such a manner as to move actuators located at the respective portions to provide a massage to the body part of the user. The massage device can massage at least one portion simultaneously. For example, the massage device 100 may massage at least one of the arm, the leg, the foot, and the back, etc., simultaneously.

The massage category may include at least one of tapping, kneading, volar tapping, compound massage, acupressure, trembling, and jiggling. The massage apparatus 100 may be controlled to move the massage module or the air bag based on the information on the kind of massage. The massage apparatus 100 may provide the user with a massage of tapping, kneading, palmar tapping, compound massage, acupressure, trembling, or trembling tapping, etc., based on the information on the kind of massage.

The massage time indicates a time when the massage apparatus 100 provides a massage pattern to the user. The massage apparatus 100 may determine the time to provide the massage pattern to the user based on the information on the massage time.

The massage intensity indicates the intensity of pressing, kneading, and beating of the user by the massage apparatus 100. The massage apparatus 100 adjusts the intensity of pressing, kneading, and beating the user by controlling the actuator. The intensity of pressing, kneading, beating the user may vary depending on the body part.

The information on the massage pattern as described above may be stored in the massage apparatus 100 in advance. The massage apparatus 100 may select information on the massage mode corresponding to the identification information of the fragrance kit. In addition, when information on a massage pattern corresponding to the identification information of the fragrance kit is not stored, the massage apparatus 100 may request the information on the massage pattern to the external server. In addition, the massage apparatus 100 may receive information on the massage pattern from the server.

When the fragrance kit 3240 is installed in the massage apparatus 100, the massage apparatus 100 may add an additional massage pattern to the massage pattern list. The additional massage mode may be a massage mode corresponding to the fragrance kit 3240. The massage pattern list may include a plurality of massage patterns that the massage apparatus 100 may provide. The user may receive a massage by selecting an additional massage mode from the massage mode list. When the fragrance kit 3240 is detached from the massage apparatus 100, the massage apparatus 100 may delete the additional massage pattern from the massage pattern list. Therefore, the user may not be able to select an additional massage pattern from the massage pattern list.

When the fragrance kit 3240 is installed, the massage apparatus 100 can activate an additional massage mode. The massage device 100 may cause the display to show that the user may select an additional massage mode. In addition, the control part 300 may perform a step 3430 of controlling the actuator or the air bag to provide a massage to the user based on the information on the selected massage mode. In addition, the massage device 100 may provide a fragrance to the user based on a fragrance generating substance included in the fragrance kit. In addition, the massage device 100 can play the image and the audio corresponding to the identification information of the aromatic suite. In addition, the massage device 100 may determine whether to provide oxygen to the user based on the identification information of the fragrance kit.

Fig. 25 is a flowchart illustrating an operating method of the massage apparatus according to an embodiment of the present invention.

In the above, the embodiment in which the massage apparatus 100 stores information about the massage pattern in advance has been described. But is not limited thereto. According to another embodiment of the present invention, the control part 300 may perform the step 3510 of receiving the identification information from the fragrance kit 3240. Step 3510 may correspond to step 3410. Since step 3410 has already been explained, a repetitive explanation will be omitted.

The control part 300 may perform step 3520 of confirming whether the fragrance kit 3240 is genuine based on the identification information. The identification information may be encrypted, and the control part 300 may generate the confirmation code by decrypting the identification information based on a predetermined algorithm. When the confirmation code matches the predetermined code, the control section 300 may determine that the fragrance kit 3240 is genuine. Alternatively, the control unit 300 may transmit the confirmation code to an external server. The control part 300 may receive information indicating whether the fragrance kit 3240 is genuine from the server.

Also, the control part 300 may generate a confirmation code by decrypting the identification information based on a predetermined algorithm, and the confirmation code may include information on the expiration date of the fragrance kit 3240. When the fragrance kit 3240 is within the valid period, the control part 300 may determine to provide a massage based on the fragrance kit 3240. In addition, the control part 300 may output an alarm when the fragrance kit 3240 exceeds the expiration date. The user can easily know that the expiration date of the fragrance kit 3240 has passed and can receive an optimal massage by replacing the fragrance kit 3240. Even if the expiration date of the fragrance kit 3240 has passed, the user can decide to use the fragrance kit 3240. The control part 300 may determine to provide a massage based on the fragrance kit 3240 exceeding the valid period based on the input of the user.

In addition, the massage device 100 may determine the replacement time of the fragrance kit 3240 based on at least one of the time the fragrance kit 3240 is installed in the massage device 100 and the number of times the user is provided with a cardiac massage based on the fragrance kit 3240. For example, when the fragrance kit 3240 is installed in the massage apparatus 100 for more than a threshold time, the massage apparatus 100 can output a signal indicating the time until the fragrance kit 3240 is replaced. The critical time may be a predetermined time. The user can replace the fragrance kit 3240 at the appropriate time by confirming the output signal.

When the fragrance kit 3240 is operated by an unauthorized company, it may provide a harmful scent to the user, provide an adverse massage to the user, or provide a massage that reduces the life of the massage apparatus 100. According to the present invention, it is possible to secure the fragrance generating material coated on the fragrance kit 3240 by confirming whether the fragrance kit 3240 is genuine. In addition, the information about the massage pattern stored in the fragrance kit 3240 can secure that a safe massage pattern can be provided.

When the fragrance kit 3240 is genuine, the control part 300 may perform step 3530 of receiving information on a massage pattern from the fragrance kit 3240. As described above, the fragrance kit 3240 can include at least one of a processor, memory, and communication. The control part 300 may request information on the massage mode to the fragrance kit 3240. In addition, the control part 300 may receive information about a massage mode stored in the memory of the fragrance kit 3240.

When the fragrance kit 3240 is installed in the massage apparatus 100, the massage apparatus 100 may add an additional massage pattern to the massage pattern list. The additional massage mode may be a massage mode corresponding to the fragrance kit 3240. The massage pattern list may include a plurality of massage patterns that the massage apparatus 100 may provide. Accordingly, the user can receive a massage by selecting an additional massage mode from the massage mode list. When the fragrance kit 3240 is detached from the massage apparatus 100, the massage apparatus 100 may delete the additional massage pattern from the massage pattern list. Therefore, the user may not be able to select an additional massage pattern from the massage pattern list.

When the fragrance kit 3240 is installed, the massage apparatus 100 can activate an additional massage mode. The massage device 100 may cause the display to show that the user may select an additional massage mode. For which an additional massage mode can be selected. Step 3540 of controlling the actuators or air bags to provide a massage to the user based on the information about the massage pattern may be performed. In addition, the massage device 100 may provide fragrance to the user based on a fragrance generating substance included in the fragrance kit 3240. In addition, the massage device 100 can play images and audio corresponding to the fragrance kit 3240. In addition, the massage device 100 may determine whether to provide oxygen to the user based on at least one of the identification information of the fragrance kit and the input of the user.

The above description has been focused on various embodiments. Those skilled in the art to which the utility model pertains will appreciate that the present invention may be embodied in modified forms without departing from the essential characteristics thereof. Therefore, the disclosed embodiments should be considered in an illustrative and not a restrictive sense. The scope of the utility model is shown in the claims, not in the above description, and all differences within the equivalent scope should be construed as being included in the present invention.

Further, the embodiments of the present invention described above may be written as programs that can be executed by a computer and can be implemented in a general-purpose digital computer that runs the programs using a computer-readable recording medium. The computer-readable recording medium includes storage media such as magnetic storage media (e.g., ROM, floppy disks, hard disks, etc.) and optical reading media (e.g., CD-ROMs, DVDs, etc.).

Claims (12)

1. A massage device is characterized in that a massage device is provided,

the method comprises the following steps:

an air duct for moving the sucked external air to the clean air discharge port,

a blowing fan inserted into an inside of a filter mounting part included in the air duct to move the external air to the clean air discharge port,

a filter part inserted into the filter mounting part of the air duct for filtering foreign matters in the external air,

a suction port cover covering the filter mounting part and coupled with the fragrance kit, an

A discharge port cover engaged with the clean air discharge port.

2. The massaging device of claim 1,

further comprising a control part for acquiring identification information of the fragrance kit and controlling an actuator or an air bag to provide a massage to a user based on a massage pattern according to the identification information;

the identification information of the fragrance kit corresponds to a fragrance generating substance generating a predetermined fragrance.

3. The massaging device of claim 1,

the filter section comprises an efficient particulate air 14 stage air filter.

4. The massaging device of claim 1,

the filter part includes:

a filter guide frame fixed to the blowing fan for fixing an air filter, including at least one hole to allow external air passing through the air filter to flow toward the blowing fan,

the air filter inserted into the inside of the filter guide frame for removing foreign substances from the outside air, and

a suction port cover guide pressurizing at least a portion of the air filter to fix the air filter to the filter guide frame, fixed to the filter guide frame, and adapted to engage the suction port cover.

5. The massaging device of claim 2,

further comprising:

an air supply part which sucks the external air and moves the external air to the oxygen generation part,

an oxygen generating part adsorbing nitrogen from the outside air supplied from the air supplying part and discharging concentrated oxygen, an

A pressure sensor for measuring a gas pressure of an oxygen gas discharge chamber included in the oxygen gas generation unit;

the control portion receives information on the gas pressure of the oxygen gas discharge chamber from the pressure sensor,

the control section outputs a signal indicating that the life of zeolite contained in the oxygen generation section has been exhausted when the information on the gas pressure is less than or equal to a first threshold value and greater than a third threshold value,

the first threshold is greater than the third threshold.

6. The massaging device of claim 5,

the control portion outputs a signal indicating that the oxygen generating portion is malfunctioning when the information on the gas pressure is less than or equal to a third threshold value.

7. The massaging device of claim 5,

the oxygen generation unit generates a gas containing 50% or more and 60% or less of oxygen in an amount of 2 liters per minute,

the gas generated by the oxygen generating part is discharged through an oxygen discharge port.

8. The massaging device of claim 1,

the discharge port cover is positioned at the upper part of the shell of the arm massage part, and the direction of air is determined by the blades contained in the discharge port cover.

9. The massaging device of claim 2,

further comprising a dust measuring sensor engaged with the discharge port cover for measuring fine dust in the outside air of the massage apparatus,

the control part may make the blower fan not operate when the dust concentration measured by the dust measuring sensor is less than a predetermined first concentration,

the control part rotates the blowing fan at a first speed when the dust concentration measured by the dust measurement sensor is greater than or equal to the first concentration and less than a predetermined second concentration,

the control part rotates the blowing fan at a second speed when the dust concentration measured by the dust measurement sensor is greater than or equal to the second concentration,

the first speed is less than the second speed.

10. The massaging device of claim 2,

the control part selects information on one massage pattern among information on a plurality of pre-stored massage patterns based on the identification information of the fragrance kit,

the control portion controls the actuator or the air bag to provide a massage to the user based on the selected information on the massage mode.

11. The massaging device of claim 2,

the control part receives identification information from the fragrance kit,

the control unit confirms whether the fragrance kit is genuine based on the identification information,

the control part receives information on a massage mode from the fragrance kit when the fragrance kit is genuine,

the control portion controls the actuator or the airbag to provide a massage to a user based on the information on the massage mode.

12. The massaging device of claim 10 or 11,

the information on the massage pattern includes: at least one of information on audio to be output when the massage is provided to the user, information on images to be output when the massage is provided to the user, information on oxygen to be provided when the massage is provided to the user, information on scent to be output when the massage is provided to the user, and information on at least one massage mode of the massage modes.

Images