CN113456443A - Massage machine and massage system - Google Patents

Abstract

The invention provides a massage system capable of changing the intensity value of massage intensity according to a specified body part. A massage system for controlling a massage intensity based on an intensity value of the massage intensity for a plurality of first body parts, the massage system comprising: an intensity value storage unit that stores intensity values of the respective first body parts; an intensity adjustment value acquisition unit that acquires intensity adjustment values for the plurality of second body parts, based on a user operation; and an intensity value changing unit that changes the intensity value of each first body part in the intensity value storage unit based on the massage intensity adjustment value of each second body part acquired by the intensity adjustment value acquisition unit.

Description

Massage machine and massage system

Technical Field

The invention relates to a massage machine and a massage system.

Background

Jp 2012-250072 a discloses a massage machine including a seat, a backrest, armrests, a footrest, and a base serving as a base for the seat, backrest, armrest, and footrest. A massage unit including a pair of right and left kneading and pressing balls is installed in a liftable manner in the backrest of jp 2012-250072 a. The massage unit includes a kneading mechanism for eccentrically rotating the kneading ball and a knocking mechanism for swinging the kneading ball back and forth.

Disclosure of Invention

The invention aims to provide a massage machine and a massage system which can change the massage intensity value according to a specified body part.

Means for solving the problems

One embodiment of the present invention provides a massage machine or a massage system that changes massage intensity based on an intensity value of the massage intensity for each of a plurality of first body parts, the massage machine or the massage system including: an intensity value storage unit that stores an intensity value of each of the first body parts; an intensity adjustment value acquisition unit that acquires intensity adjustment values for each of a plurality of second body parts; and an intensity value changing unit that changes the intensity value of each of the first body parts in the intensity value storage unit based on the massage intensity adjustment value of each of the second body parts acquired by the intensity adjustment value acquiring unit. The remote controller of the massage machine may include the intensity value storage unit, the intensity adjustment value acquisition unit, and the intensity value change unit.

With this configuration, the intensity value of the massage can be changed for each predetermined body part.

In one embodiment of the present invention, the intensity value changing unit includes: a new intensity value calculation unit that calculates a new intensity value of each of the first body parts reflecting the intensity adjustment value, using the intensity adjustment value of each of the second body parts acquired by the intensity adjustment value acquisition unit; and an updating unit that updates the content of the intensity value storage unit based on the new intensity value of each of the first body parts calculated by the new intensity value calculating unit.

In one embodiment of the present invention, the massage system includes: a massage machine which performs massage; and a portable terminal capable of communicating with the massage machine, the portable terminal including the intensity adjustment value acquisition unit and the intensity value change unit.

In one embodiment of the present invention, the massage is a mechanical massage using a treatment member.

In one embodiment of the present invention, the massage is an air-type massage using an air bag.

In one embodiment of the present invention, the massage includes a mechanical massage using the treatment member and an air massage using the air bag.

Drawings

Fig. 1 is a block diagram showing the overall structure of the massage system.

Fig. 2 is a partially cut-away perspective view showing the external appearance of the massage machine and the mobile terminal.

Fig. 3 is a perspective view schematically showing the structure of the massage unit.

Fig. 4A is a block diagram showing an electrical structure of the massage machine.

Fig. 4B is an air circuit diagram showing an air circuit from the air pump to each airbag.

Fig. 5 is a block diagram showing an electrical configuration of the portable terminal.

Fig. 6A is a schematic diagram showing an example of a remote controller home screen, fig. 6B is a schematic diagram showing an example of a pairing waiting screen, and fig. 6C is a schematic diagram showing an example of a pairing completed screen.

Fig. 7A is a schematic diagram showing an example of a login screen, fig. 7B is a schematic diagram showing an example of a connected device list screen, fig. 7C is a schematic diagram showing an example of a connected screen, and fig. 7D is a schematic diagram showing an example of a connected screen.

Fig. 8A is a schematic diagram showing an example of an application home screen, and fig. 8B is a schematic diagram showing an example of a menu screen.

Fig. 9 is a schematic diagram for explaining a method of setting an initial value of the reference intensity value for each first body part of the mechanical massage.

Fig. 10A is a schematic diagram showing an example of the contents of the first reference intensity value storage unit, and fig. 10B is a schematic diagram showing an example of the contents of the second reference intensity value storage unit.

Fig. 11A is a schematic diagram showing an example of the contents of the first intensity value history storage unit, and fig. 11B is a schematic diagram showing an example of the contents of the second intensity value history storage unit.

Fig. 12 is a schematic diagram showing an example of the contents of the intensity value change table.

Fig. 13A is a schematic diagram showing an example of an item determination screen.

Fig. 13B is a schematic diagram showing an example of the intensity adjustment value setting screen.

Fig. 14A is a schematic diagram showing an example of an optimization setting screen for the intensity value of the mechanical massage.

Fig. 14B is a schematic diagram showing an example of an optimization setting screen displayed when optimization of the intensity value for the mechanical massage is performed.

Fig. 15A is a schematic diagram showing an example of an optimization setting screen for the intensity value of the air massage.

Fig. 15B is a schematic diagram showing an example of an optimization setting screen displayed when optimization of the intensity value for the air massage is performed.

Description of the reference numerals

1, a massage system; 2a chair type massage machine; 3, a portable terminal; 4, a server; 5a communication network; 23 a massage unit; 25 remote controller; 31-36 air bags; kneading and pressing the ball 51; 60 a control unit; 61 a memory; 62 an intensity value storage area; 70 a pressure sensor; 90a control unit; 91 a memory; 92 an intensity adjustment value acquisition unit; 93 an intensity value changing unit; 93A new intensity value calculating section; 93B an update unit; an optimal value calculation unit 94; 95 updating part; 101 a first communication unit; 102 a second communication unit; 103 an operation display unit; 130 application home screen; 151a reference intensity value storage unit; 151A first reference intensity value storage unit; 151B a second reference intensity value storage section; 152 an intensity value history storage unit; 152A first intensity value history storage unit; 152B a second intensity value history storage unit; 153 optimum value operation result storage part; 154 intensity value change table; 155 a massage history storage unit; 160 item decision screen; 161 personalized selection buttons; 162 a massage start button; 170 setting a frame of intensity adjustment value; 180 menu screens; 182 an optimization setting button; 190A, 190B optimization setting screen; 196 an optimize execute button; 197 on-off.

Detailed Description

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

[1] Integral structure of massage system 1

Fig. 1 is a block diagram showing the overall structure of the massage system 1.

The massage system 1 includes a chair-type massage machine (hereinafter, simply referred to as "massage machine 2"), a mobile terminal 3, and a server 4. In the present embodiment, the mobile terminal 3 is a smartphone. The portable terminal 3 is a portable terminal used by a user (a person to be treated) who wants to receive a massage by the massager 2. The massager 2 and the portable terminal 3 can perform wireless communication by Bluetooth (registered trademark), for example. The mobile terminal 3 and the server 4 can communicate with each other via a communication network 5.

The portable terminal 3 is provided with a massage application program for determining a massage item, changing an intensity value of a massage intensity, optimizing the intensity value, and the like. When the massage item is determined, the portable terminal 3 transmits information including the ID (item ID) and the intensity value of the determined massage item to the massage machine 2. When receiving information including the item ID and the intensity value from the portable terminal 3, the massage machine 2 executes a massage item corresponding to the received item ID. At this time, the massager 2 controls the massage intensity based on the received intensity value.

The portable terminal 3 stores information including the item ID, the intensity value, and the like transmitted to the massage machine 2 in a memory as massage history data (a massage history storage unit 155 (see fig. 5) to be described later). Then, the information is transmitted to the server 4 at a predetermined timing. The server 4 stores the massage history received from the mobile terminal 3 in a manner that is differentiated for each user of the mobile terminal 3.

[2] Appearance of the massage machine 2

Fig. 2 is a partially cut-away perspective view showing the external appearance of the massage machine 2 and the mobile terminal 3.

The massager 2 includes a seat 11, a backrest 12, armrests 13, an ottoman 14, and a base serving as a base for these components.

In the following description, the front-back direction, the left-right direction, and the up-down direction refer to the front-back direction, the left-right direction, and the up-down direction, respectively, when the user sits on the massage machine 2 in a normal posture, as viewed from the user.

The base is present below the seat 11, but in fig. 2, the base is not present because it is hidden by the seat 11, the backrest 12, the armrest 13, and the footrest 14.

The seat 11 is disposed on the base. The backrest 12 is disposed at the rear of the seat 11. The armrest portions 13 are disposed on both left and right sides of the seat portion 11. The footrest section 14 is disposed on the front side of the seat section 11. The backrest portion 12 is supported by a backrest rotation actuator 21 (see fig. 4A) so as to be tiltable with respect to the seat portion 11. The ottoman portion 14 is rotatable about a support shaft extending in the left-right direction provided near the upper portion of the seat portion by an ottoman rotation actuator 22 (see fig. 4A). Thereby, the footrest section 14 can be turned between the vertical posture shown in fig. 2 and the horizontal posture rotated by substantially 90 degrees from the vertical posture.

The backrest 12 incorporates a massage unit 23. The massage unit 23 is used to perform various massages (mechanical (japanese: メカ) massages) using a pair of right and left massage pieces (kneading and pressing balls) 51. The backrest 12 is provided with a pair of right and left U-shaped guide rails 28, 29 (see fig. 3) extending in the vertical direction, and the massage unit 23 is movable in the vertical direction along the guide rails 28, 29. The detailed structure of the massage unit 23 will be described later.

The armrest portion 13 is provided with an arm unit 16 having a forearm receiving recess 17 for receiving the forearm of the user. The footrest section 14 includes leg receiving recesses 18 and foot receiving recesses 19 that receive the left and right legs and the feet of the user, respectively.

The backrest 12, the seat 11, the armrest 13, and the footrest 14 of the massage machine 2 are provided with air bags. The air cells are inflated and deflated by the supply and exhaust of air, thereby performing an air massage on the user.

A right upper arm airbag 31a for massaging a right upper arm and a left upper arm airbag 31b for massaging a left upper arm are provided on both sides of a highly central portion of the backrest portion 12. The airbags 31a and 31b constitute an upper arm airbag 31 for massaging an upper arm.

Further, a right waist airbag 36a for massaging a right waist and a left waist airbag 36b for massaging a left waist are provided on both sides of the lower portion of the backrest 12. The air bags 36a and 36b constitute a waist air bag 36 for massaging the waist.

The seat 11 is provided with a pair of left and right lateral thigh air bags 32a, 32b for massaging side portions of a thigh (japanese patent: ふともも), a pair of left and right rear upper thigh air bags 32c, 32d for massaging a rear upper portion of the thigh, and a rear lower thigh air bag 32e for massaging a rear lower portion of the thigh. These air bags 32a to 32e constitute a thigh air bag 32 for massaging a thigh.

On both side surfaces of the pair of left and right forearm housing recesses 17, forearm main body airbags 33a and 33b for massaging the forearms and hand airbags 33c and 33d for massaging the hands are provided. The air bags 33a to 33d constitute a forearm air bag 33 for massaging the forearm and the hand.

Lateral calf airbags 34a and 34b for massaging the lateral calf (japanese ふくらはぎ) are provided on both side surfaces of the pair of left and right leg-receiving recesses 18. Rear calf airbags 34c and 34d for massaging the rear side of the calf are provided on the bottom surfaces of the pair of right and left leg receiving recesses 18. These air bags 34a to 34d constitute a calf air bag 34 for massaging the calf.

Instep side airbags 35a and 35b for pressing an instep portion downward are provided on both side surfaces of the pair of left and right foot receiving recesses 19. Sole side airbags 35c and 35d for pressing the soles upward are provided on the bottom surfaces of the pair of left and right foot receiving recesses 19. These air bags 35a to 35d constitute a sole air bag 35 for massaging the sole.

A remote controller holder 24 is attached to the arm unit 16. A remote controller (hereinafter, referred to as "remote controller 25") for allowing a user to operate the massage machine 2 is detachably attached to the remote controller holder 24. As shown in fig. 4A, an operation display unit 26 and a plurality of operation keys are provided on an operation surface of the remote controller 25. The operation display unit 26 is constituted by, for example, a touch panel type liquid crystal display. The remote controller 25 includes a communication unit for performing wireless communication with the mobile terminal 3.

[3] Structure of massage unit 23

Fig. 3 is a perspective view schematically showing the structure of the massage unit 23.

The massage unit 23 is attached to the guide rails 28 and 29 so as to be movable up and down. The massage unit 23 includes a main frame 41 having a rectangular frame shape. The main frame 41 is composed of a pair of left and right side walls, and a top wall and a bottom wall that respectively connect upper ends and lower ends of the side walls. A guide shaft 42 extending in the left-right direction and a lifting drive shaft 43 are rotatably attached to the main frame 41.

The guide shaft 42 is disposed at an upper portion of the main frame 41, and the elevating drive shaft 43 is disposed at a lower portion of the main frame 41. Both ends of the guide shaft 42 and the lifting drive shaft 43 protrude outward from both side walls of the main frame 41. Guide rollers 44 guided by the guide rails 28 and 29 are attached to both ends of the guide shaft 42. Pinions 45 that mesh with racks (not shown) provided on the guide rails 28, 29 are attached to both ends of the lifting drive shaft 43.

An elevating motor 46 for rotating the elevating drive shaft 43 is attached to the main frame 41. The elevating motor 46 is coupled to the elevating drive shaft 43 via a gear mechanism 47. The massage unit 23 is moved up and down along the guide rails 28, 29 by the rotation of the up-and-down motor 46.

The massage unit 23 is provided with an elevation position sensor 48, and the elevation position sensor 48 detects an elevation position (vertical position) of the massage unit 23 by detecting a rotation amount of the elevation drive shaft 43. The elevation position sensor 48 is constituted by a rotary encoder for detecting the amount of rotation of the elevation drive shaft 43.

A swing frame 49 is attached to a lengthwise middle portion of the elevating drive shaft 43 so as to be swingable in the front-rear direction. A pair of right and left treatment tools 51 and a treatment tool driving unit 50 including a driving mechanism for the treatment tools 51 are attached to the swing frame 49. The main frame 41 is provided with a treatment member driving unit advancing and retreating mechanism for advancing and retreating the swing frame (treatment member driving unit) in the front-rear direction.

The treatment member driving unit advancing and retreating mechanism will be explained. An advance/retreat shaft 52 disposed below the guide shaft 42 and extending in the left-right direction is rotatably attached to the main frame 41. A forward/backward movement motor 53 for rotating the forward/backward movement shaft 52 is attached to one side portion of the main frame 41. The forward/backward movement motor 53 is connected to the forward/backward movement shaft 52 via a gear mechanism 54. A pair of left and right pinion gears 55 are attached to the longitudinal middle portion of the advancing/retreating shaft 52. Arc-shaped racks 56 that mesh with the pair of left and right pinions 55 are provided on the upper portion of the swing frame 49. When the advancing-retreating shaft 52 is rotated by the advancing-retreating motor 53, the pinion 55 is rotated, and the arc-shaped rack 56 is moved. Thereby, the swing frame 49 swings around the lifting drive shaft 43. Thereby, the treatment instrument drive unit 50 (treatment instrument 51) advances and retreats in the front-rear direction.

A front-rear position sensor 57 is provided in the massage unit 23, and the front-rear position sensor 57 detects the front-rear position of the treatment member driving unit 50 by detecting the amount of rotation of the advancing-retreating shaft 52. The forward/backward position sensor 57 is constituted by an encoder for detecting the amount of rotation of the forward/backward shaft 52. The massage unit 23 is provided with a pressure sensor 70 (see fig. 4A) for detecting the pressing pressure of the treatment implement 51 against the user.

The treatment instrument driving unit 50 includes a kneading mechanism that performs a kneading operation by eccentrically rotating the treatment instrument 51; and a knocking mechanism that performs a knocking operation by swinging the treatment implement 51 in the front-rear direction. The kneading mechanism includes a kneading motor 58 as an actuator (driving source). The striking mechanism includes a striking motor 59 as an actuator (driving source). Such kneading mechanisms and striking mechanisms are well known.

[4] Electric structure of massager 2

Fig. 4A is a block diagram showing an electrical structure of the massage machine 2. Fig. 4B is an air circuit diagram showing an air circuit from the air pump to each airbag.

Referring to fig. 4A, a control unit 60 for controlling the massage machine 2 is built in the massage machine 2. The control unit 60 includes a microcomputer, and includes a CPU, a memory (RAM, ROM, nonvolatile memory) 91, and the like. The memory 61 stores various data in addition to the program of the CPU.

The memory 61 (work memory) has an intensity value storage area 62. The intensity value storage area 62 stores intensity values for a plurality of body parts for the mechanical massage and intensity values for a plurality of body parts for the air massage. The intensity values of the plurality of body parts for the mechanical massage include eight intensity values for the shoulder, the back, the waist and the hip. Shoulder, under shoulder, over back, under back, over waist, under waist and hip are examples of "first body parts" of the present invention.

The strength values for each of the plurality of body parts for the air massage include six strength values for the upper arm, forearm, waist, thigh, calf and sole. The upper arm, forearm, waist, thigh, calf and sole are examples of "first body parts" of the present invention.

The first body part is a detailed part of each part of the body of the person to be treated that can be treated by the massage machine, and the second body part described later is an enlarged part obtained by summarizing the detailed parts of the plurality of first body parts. The second body part includes five of the shoulder and back (including the shoulder and back), the vicinity of the arm, the waist, the vicinity of the pelvis, and the leg.

Hereinafter, for convenience of description, the "intensity values for each of the plurality of body parts for the mechanical massage" and the "intensity values for each of the plurality of body parts for the air massage" will be collectively referred to as "intensity values for each of the first body parts". When the intensity value for the mechanical massage and the intensity value for the air massage are present for the same body part as in the waist of the present embodiment, the above-mentioned "intensity value of each first body part" as a general term is included separately from both. Therefore, the intensity value of each first body part is stored in the intensity value storage area 62.

For convenience of explanation, hereinafter, the "intensity value for each of the plurality of body parts for the mechanical massage" is referred to as "intensity value for each of the first body parts for the mechanical massage", and the "intensity value for each of the plurality of body parts for the air massage" is referred to as "intensity value for each of the first body parts for the air massage". That is, in the present specification, "first body part" in the intensity values for the respective first body parts of the mechanical massage means shoulder, back, waist, and hip, and "first body part" in the intensity values for the respective first body parts of the air massage means upper arm, forearm, waist, thigh, calf, and sole.

The intensity value of each first body part for the mechanical massage is represented by a value corresponding to the amount of protrusion of the treatment tool driving unit 50 from the main frame 41 when the first body part is massaged. Normally, the strength is adjusted to about three levels, but in the present embodiment, the strength can be adjusted in detail by using the projection amount of the driving means. Therefore, the massage machine according to the present embodiment can perform very fine intensity adjustment according to the preference of the user. The value of each intensity value of the mechanical massage is within the range of 1-70. When the intensity value for each first body part of the mechanical massage is changed by the intensity value changing function of the portable terminal 3 described later, the intensity value serving as a reference for calculating the changed intensity value is referred to as a "reference intensity value" for each first body part of the mechanical massage. Initial values of the reference intensity values for the mechanical massage are set on the massager 2 side.

The strength value of each first body part for the air massage is represented by a value corresponding to the air supply time to the air cells when the air cells corresponding to the first body part are inflated. Therefore, the massage machine according to the present embodiment can perform very fine intensity adjustment according to the preference of the user. The value of each intensity value for air massage is in the range of 1-7.

When the intensity value for each first body part of the air massage is changed by the intensity value changing function of the portable terminal 3 described later, the intensity value serving as a reference for calculating the changed intensity value is referred to as a "reference intensity value" for each first body part of the air massage. In the present embodiment, the initial value of each reference intensity value for the air massage is set to a predetermined value (4 in the present embodiment).

Hereinafter, the "reference intensity value" for each first body part of the mechanical massage and the "reference intensity value" for each first body part of the air massage are collectively referred to as "reference intensity values for each first body part".

When the massage is performed by the massage machine 2, the control section 60 controls the massage intensity of each first body part using the intensity value of each first body part stored in the intensity value storage area 62.

The controller 60 is connected to the remote controller 25, a drive circuit 71 of the backrest turning actuator 21, and a drive circuit 72 of the ottoman turning actuator 22. The control unit 60 is also connected to a drive circuit 73 of the elevation motor 46, a drive circuit 74 of the advancing and retreating motor 53, a drive circuit 75 of the kneading motor 58, and a drive circuit 76 of the striking motor 59 in the massage unit 23. The control unit 60 is also connected to a pressure sensor 70, a lifting position sensor 48, and a front-rear position sensor 57 in the massage unit 23.

The control unit 60 is also connected to a drive circuit 77 of the air pump 81 and a drive circuit 78 of the plurality of solenoid valves 82a to 82 u. Air is supplied from the air pump 81 to the air bags 31a to 36b using the respective electromagnetic valves 82a to 82 u. Hereinafter, the solenoid valves 82a to 82u are collectively referred to as the solenoid valves 82.

Referring to fig. 4B, the right upper arm airbag 31a is connected to the solenoid valve 82a, and the left upper arm airbag 31B is connected to the solenoid valve 85B. The right thigh lateral airbag 32a is connected to the solenoid valve 82c, and the left thigh lateral airbag 32b is connected to the solenoid valve 82 d. The right upper thigh rear upper bladder 32c is connected to the solenoid valve 82e, and the left upper thigh rear upper bladder 32d is connected to the solenoid valve 82 f. The thigh rear lower air bag 32e is connected to the solenoid valve 82 g.

The solenoid valve 82h is connected to the forearm main body bladder 33a of the right arm, and the solenoid valve 82i is connected to the forearm main body bladder 33b of the left arm. The right-hand air bag 33c is connected to the solenoid valve 82j, and the left-hand air bag 33d is connected to the solenoid valve 82 k. The right waist airbag 36a is connected to the solenoid valve 82t, and the left waist airbag 36b is connected to the solenoid valve 82 u.

The solenoid valve 821 is connected to the right calf transverse air bag 34a, and the solenoid valve 82m is connected to the left calf transverse air bag 34 b. The right calf posterior chamber 34c is connected to the solenoid valve 82n, and the left calf posterior chamber 34d is connected to the solenoid valve 82 o. The right instep side airbag 35a is connected to the solenoid valve 82p, and the left instep side airbag 35b is connected to the solenoid valve 82 q. The right sole side air bag 35c is connected to the solenoid valve 82r, and the left sole side air bag 35d is connected to the solenoid valve 82 s.

In the present embodiment, the electromagnetic valves are provided individually for the airbags arranged in pairs on the left and right sides, but one electromagnetic valve may be provided in common for the two airbags arranged in pairs.

When the electromagnetic valve 82 of a certain air bag is excited, air is supplied from the air pump 81 to the air bag via the electromagnetic valve 82. Thereby, the balloon is inflated. When the solenoid valve 82 of the airbag is demagnetized, the air in the airbag is discharged to the outside through the solenoid valve. Thereby, the airbag is contracted.

The control unit 60 controls the drive circuits 71 and 72 of the actuators 21 and 22 based on an operation of the remote controller 25, an operation of the mobile terminal 3, and the like. The control unit 60 controls the drive circuits 73 to 76 of the motors 46, 53, 58, and 59, the drive circuit 77 of the air pump 81, and the drive circuit 78 of the electromagnetic valve 82 based on the operation of the remote controller 25, the operation of the portable terminal 3, and the like.

Thereby, the massage machine 2 can perform various massages. Further, the massage machine 2 can perform initial value setting processing for setting an initial value of the reference intensity value for each first body part of the mechanical massage. Details of the initial value setting process will be described later.

The operation modes of the massage machine 2 mainly include an application mode in which the massage machine 2 is controlled by operating the portable terminal 3 and a remote controller mode in which the massage machine 2 is controlled by operating the remote controller 25.

The massage mode includes a manual mode, an automatic mode, a human map mode, a health care mode, a history mode, and the like. The manual mode as well as the automatic mode are massage modes that can be executed mainly in the remote controller mode. The body map mode, the health care mode, and the history mode are massage modes that can be executed mainly in the application program mode.

The same function as in the application mode can be executed in the remote controller mode. For example, by connecting the portable terminal 3 and the massage machine 2 in a wired and communicable manner, the application mode can be executed by operating the portable terminal 3 with the remote controller 25. In this case, the remote controller 25 may be provided with the function of the mobile terminal 3.

The manual mode is a mode in which a massage corresponding to the kind of massage selected by the user is performed.

The automatic mode is a mode for allowing the user to select a desired massage item from a plurality of massage items and execute the selected massage item.

The human map mode is a mode in which the user inputs a muscle stiffness portion and a muscle stiffness condition, determines a massage item suitable for the input muscle stiffness portion and the muscle stiffness condition, and executes the determined massage item.

The health care mode is a mode in which a massage item suitable for biological information such as the number of steps, sleep time, and pulse rate (heart rate) of the user is determined, and the determined massage item is executed.

The history mode is a mode in which the user selects a desired massage item from massage items that have been performed on the user in the past, and the selected massage item is executed.

[5] Electrical structure of portable terminal 3

Fig. 5 is a block diagram showing an electrical configuration of the portable terminal 3.

The mobile terminal 3 includes a control unit 90. The control unit 90 includes a microcomputer, and includes a CPU, a memory (RAM, ROM, nonvolatile memory) 91, and the like. The memory 91 stores various data in addition to the program of the CPU. The control unit 90 is connected to a first communication unit 101, a second communication unit 102, an operation display unit 103, and the like. The first communication unit 101 is a communication interface for the control unit 90 to perform wireless communication with the remote controller 25 (the control unit 60 of the massage machine 2). The second communication unit 102 is a communication interface for the control unit 90 to communicate with the server 4 and other mobile terminals via the communication network 5. The operation display unit 103 is constituted by a display having an input function. In the present embodiment, the operation display unit 103 is a touch panel type liquid crystal display (touch panel type display unit). As described above, the portable terminal 3 and the massage machine 2 may be connected to each other in a wired and communicable manner, so that the operation of the portable terminal 3 can be performed by the remote controller 25.

A massage application program for determining a massage item, changing the intensity value of each first body part, optimizing the intensity value of each first body part, or transmitting a massage history to the server 4 based on a body map mode, a health care mode, a history mode, or the like is stored in the memory 91 (nonvolatile memory).

The control unit 90 can realize a project determination function, an intensity value change function, an intensity value optimization function, and the like by executing the massage application program. The item determination function is a function for determining a massage item in a body map mode, a health care mode, a history mode, and the like. The intensity value changing function is a function of changing the intensity value of each first body part. The intensity value optimizing function is a function of optimizing the intensity value of each first body part. Details of these functions will be described later.

[6] Actuation of the massage machine 2

The user activates the massage machine 2 by turning on the power switch of the remote controller 25. Thus, a home screen image (hereinafter, referred to as a "remote controller home screen image") as shown in fig. 6A is displayed on the operation display unit 26 of the remote controller 25. On the home screen of the remote controller, an item selection button 111 for selecting various massage items, a manual button 112 for manually selecting a massage type, a setting button 113 for performing various settings, a bluetooth button 114, and the like are displayed. Bluetooth indicia is displayed on bluetooth button 114. In a state where the massage machine 2 is not connected to the portable terminal 3, the bluetooth label is displayed in white.

When the user taps the bluetooth button 114, the massager 2 enters a connection waiting state (pairing waiting mode) with the portable terminal 3. At this time, the operation display unit 26 displays a pairing waiting screen as shown in fig. 6B. In the pairing waiting screen, characters of "pairing mode", arc arrow pairing marks, a stop button, a bluetooth button, and the like are displayed. In the pairing wait, the circular arc arrow rotates in pairs.

When the massage machine 2 and the mobile terminal 3 are connected, a pairing completion screen as shown in fig. 6C is displayed on the operation display unit 26. In the paired picture, the arc arrow paired marks in the picture waiting for pairing are changed into paired hooks.

When a predetermined time (for example, 2 seconds) has elapsed after the connection completion screen is displayed, the remote control home screen is displayed on the operation display unit 26 (see fig. 6A). However, in this case, the bluetooth label on the bluetooth button 114 is displayed in blue.

[7] Initiation of a massage application

The user starts the massage application by tapping an icon of the massage application displayed on the operation display unit 103 of the portable terminal 3. Thereby, a login screen as shown in fig. 7A is displayed on the operation display unit 103. On the login screen, a login ID input unit 121, a password input unit 122, a login button 123, and the like are displayed.

When the user has already registered, if the user taps the login button 123 after inputting the login ID and the password, the connected device list screen as shown in fig. 7B is displayed on the operation display unit 103. Model selection buttons 124 and 125 indicating the model of the massager that is in the pairing wait mode are displayed on the connected device list screen. The user taps a model selection button corresponding to the model of the massage machine that the user wants to use.

When a predetermined model selection button is tapped, the control unit 90 of the mobile terminal 3 performs processing for connecting the mobile terminal 3 to the massage machine 2 of the model corresponding to the model selection button (hereinafter, referred to as "selected model"). When the selected model is XY-0001, as shown in fig. 7C, a connection screen including a message of "being connected to XY-0001" is displayed on the operation display portion 103. If the massager 2 used is in the pairing wait state, then the portable terminal 3 is connected to the massager 2.

When the portable terminal 3 is connected to the massage machine 2, a connected screen as shown in fig. 7D is displayed on the operation display unit 103. When the selected model is XY-0001, a message of 'connection completion with XY-0001' is displayed on the connection completion screen. Then, a home screen of the massage application (hereinafter, referred to as "application home screen") is displayed on the operation display unit 103.

Fig. 8A is a schematic diagram showing an example of an application home screen.

The application home screen has a title area F1, a connection state display area F2, a button display area F3, and the like.

The title area F1 is an area at the upper end of the application home screen. A hamburger button 131 and the like formed of three lines are displayed in the header area F1. The hamburger button 131 is a button for displaying a predetermined menu screen 180 (see fig. 8B).

The connection state display region F2 is disposed below the title region F1. The connected state display area F2 is an area for displaying the connected state with the massage machine 2. When the portable terminal 3 is connected to the massage machine 2, the character string "being connected" is displayed in the connected state display area F2, and when the portable terminal 3 is not connected to the massage machine 2, the character string "not being connected" is displayed in the connected state display area F2.

The button display region F3 is disposed below the connection state display region F2. The button display area F3 displays a human map mode button 132, a health care mode button 133, a plurality of history buttons 134, and the like.

The human map mode button 132 is disposed below the connection state display area F2. The body map mode button 132 is a button for setting the massage mode to the body map mode. A character string of "human map" or the like is displayed on the human map mode button 132. When the human map mode button 132 is tapped, a human map screen (not shown) for allowing the user to input a muscle stiffness portion and a muscle stiffness condition is displayed on the operation display unit 103. The user inputs a muscle stiffness part and a muscle stiffness condition on a human body map picture.

When a muscle stiffness portion and a muscle stiffness condition are input on the human map screen, an item determination screen presenting a massage item appropriate for the input muscle stiffness portion and the muscle stiffness condition is displayed on the operation display unit 103. When the user performs a predetermined operation on the item determination screen, the massage machine 2 executes the presented massage item.

The health care mode button 133 is disposed below the human map mode button 132. The health care mode button 133 is a button for setting the massage mode to the health care mode. The health mode button 133 displays, for example, biological information such as the number of steps, sleep time, and pulse rate of the user, and a message recommending a massage item appropriate for the biological information. In this example, the number of steps of the user on the day and a message recommending a massage item appropriate to the number of steps are displayed. When the health care mode button 133 is pressed, an item determination screen presenting a massage item appropriate for the number of steps, the sleep time, the pulse rate, and the like of the user is displayed on the operation display unit 103. When the user performs a predetermined operation on the item determination screen, the massage machine 2 executes the presented massage item.

The history button 134 is disposed below the health care mode button 133. The history button 134 is a button for setting the massage mode to the history mode. The history button 134 displays the names of the massage items and the massage dates and times that were previously performed on the user. When the history button 134 is tapped, an item determination screen presenting a massage item corresponding to the history button 134 is displayed on the operation display unit 103. When the user performs a predetermined operation on the item determination screen, the massage machine 2 executes the presented massage item.

[8] Setting of application program mode

When the user sets the operation mode of the massage machine 2 to the application mode, the user sets the operation mode to the application mode by operating the remote controller 25 after starting the massage machine 2. When the operation mode is set to the application mode, the control unit 60 performs a process (initial value setting process) for setting an initial value of the reference intensity value for each first body part of the mechanical massage. A method of setting an initial value of the reference intensity value will be described.

First, the control unit 60 performs processing for detecting the shoulder position of the user. Specifically, the controller 60 drives the elevation motor 46 to move the massage unit 23 to the uppermost position. Subsequently, the control unit 60 drives the elevation motor 46 to gradually lower the massage unit 23, and acquires the pressure value detected by the pressure sensor 70. When the pressure value becomes equal to or higher than the predetermined first threshold value, the control unit 60 stops the elevation motor 46. Then, the height position of the massage unit 23 is detected as the shoulder position of the user based on the output of the elevation position sensor 48.

The control section 60 determines the height positions of the shoulder, under the shoulder, on the back, under the back, on the waist, under the waist, and the hip (more precisely, positions in the direction along the moving path of the massage unit 23) based on the shoulder position of the user as body part positions corresponding to these body parts. The positions of the shoulder, back, waist, and hip determined by y1 to y8 in the XY coordinates of fig. 9 are shown. In the XY coordinates of fig. 9, when the massage machine 1 is viewed from the left direction, the Y axis is taken in the direction along the moving path of the massage unit 23, and the X axis is taken in the direction extending forward from the lowermost end position of the massage unit 23. In fig. 9, the Y axis is drawn linearly, but the Y axis is curved when the moving path of the massage unit 23 is curved when viewed from the left-right direction.

Subsequently, the control unit 60 performs processing for setting the initial values of the reference intensity values for the body part positions y1 to y 8.

The control unit 60 first drives the advancing/retreating motor 53 at the shoulder position to advance the treatment instrument driving unit 50 to the rearmost position. Next, the control unit 60 drives the advancing/retreating motor 53 at the shoulder position to gradually move the treatment instrument driving unit 50 forward (toward the back of the user) and acquire the pressure value detected by the pressure sensor 70. When the pressure value reaches the predetermined second threshold value, the control unit 60 stops the advancing/retreating motor 53. Then, a value corresponding to the amount of advance of the treatment member driving unit 50 is stored in the intensity value storage area 62 as an initial value of the reference intensity value for the shoulder position based on the front-rear position sensor 57.

Subsequently, the control unit 60 drives the advancing/retreating motor 53 to retreat the treatment instrument driving unit 50 to the final position, and then drives the elevating motor 46 to move the massage unit 23 to the under-shoulder position and stop. Next, the control unit 60 drives the advancing/retreating motor 53 at the shoulder position, gradually moves the treatment instrument driving unit 50 forward, and acquires the pressure value detected by the pressure sensor 70. When the pressure value reaches the second threshold value, the control unit 60 stops the advancing/retreating motor 53. Then, a value corresponding to the amount of advance of the treatment member driving unit 50 is stored in the intensity value storage area 62 as an initial value for the reference intensity value under the shoulder based on the front-rear position sensor 57.

In the following, by the same operation, initial values of the reference intensity values for the back upper, the back lower, the waist upper, the waist lower, and the hip are obtained and stored in the intensity value storage area 62. Initial values of basic intensity reference values for the eight body part positions y1 to y8 are schematically represented as x1 to x8 in the XY coordinates of fig. 9. x1 to x8 are values corresponding to the amount of advance of the treatment member drive unit 50.

In this way, when the initial values of the reference intensity values for the eight body part positions are stored in the intensity value storage area 62, the control section 60 performs processing for pairing with the mobile terminal 3. Thereby, the operation display unit 26 displays the pairing waiting screen as shown in fig. 6B.

When the massage machine 2 and the mobile terminal 3 are connected, a pairing completion screen as shown in fig. 6C is displayed on the operation display unit 26. When a predetermined time (for example, 2 seconds) has elapsed after the connection completion screen is displayed, the remote control home screen is displayed on the operation display unit 26 (see fig. 6A).

When the massage machine 2 and the portable terminal 3 are in a connected state, the control unit 60 transmits the initial value of the reference intensity value for each first body part of the mechanical massage stored in the intensity value storage area 62 to the portable terminal 3. Upon receiving the initial values of the reference intensity values, the control unit 90 of the portable terminal 3 stores the received initial values of the reference intensity values in a first reference intensity value storage unit 151A (see fig. 5) described later as reference intensity values for the respective first body parts of the mechanical massage. The control unit 90 of the portable terminal 3 stores the initial value of the received reference intensity value in the first region E1 of the intensity value history storage unit 152A (see fig. 5) described later as an intensity value (or history data) for each first body part of the mechanical massage.

When the operation mode of the massage machine 2 is set to the application mode by the remote controller operation by the user, the control unit 60 may first perform processing for pairing with the mobile terminal 3. After the massager 2 and the mobile terminal 3 are connected, the control unit 60 may perform an initial value setting process for setting an initial value of the reference intensity value, and transmit the obtained initial value of the reference intensity value to the mobile terminal 3.

In this case, before the initial value setting process is performed, the control unit 60 may check whether or not the reference intensity values for the respective first body parts of the mechanical massage are stored in the portable terminal 3 by communication with the portable terminal 3. When the portable terminal 3 stores the reference intensity values for the respective first body parts of the mechanical massage, the control unit 60 may not perform the initial value setting process.

[9] Structure for realizing function of changing intensity value and function of optimizing intensity value

Referring to fig. 5, in order to realize the intensity value changing function and the intensity value optimizing function, the memory 91 includes a reference intensity value storage unit 151, an intensity value history storage unit 152, an optimum value calculation result storage unit 153, an intensity value changing table 154, and the like. The memory 91 further includes a massage history storage unit 155. The intensity value history storage unit 152 is an example of the "intensity value storage unit" and the "intensity value history storage unit" of the present invention.

The reference intensity value storage unit 151 includes a first reference intensity value storage unit 151A and a second reference intensity value storage unit 151B. Fig. 10A is a schematic diagram showing an example of the contents of the first reference intensity value storage unit 151A, and fig. 10B is a schematic diagram showing an example of the contents of the second reference intensity value storage unit 151B.

The first reference intensity value storage unit 151A stores reference intensity values for the respective first body parts of the mechanical massage. As described above, the initial value of the reference intensity value for the mechanical massage set by the massage machine 2 is stored in the first reference intensity value storage unit 151A at the time of application mode setting. When the intensity value for the mechanical massage is optimized by the intensity value optimizing function, the optimized intensity value is stored as a reference intensity value in the first reference intensity value storage unit 151A. Thereby, the reference intensity value in the first reference intensity value storage unit 151A is updated.

The second reference intensity value storage unit 151B stores reference intensity values for the respective first body parts of the air massage. The initial value of the reference intensity value stored in the second reference intensity value storage unit 151B is 4 in the present embodiment. When the intensity value for the air massage is optimized by the intensity value optimizing function, the optimized intensity value is stored as the reference intensity value in the second reference intensity value storage unit 151B. Thereby, the reference intensity value in the second reference intensity value storage unit 151B is updated.

The intensity value history storage unit 152 includes a first intensity value history storage unit 152A and a second intensity value history storage unit 152B. Fig. 11A is a schematic diagram showing an example of the contents of the first intensity value history storage unit 152A, and fig. 11B is a schematic diagram showing an example of the contents of the second intensity value history storage unit 152B.

When the intensity value of each first body part for the mechanical massage is changed by the intensity value changing function or optimized by the intensity value optimizing function, the changed intensity value or the optimized intensity optimal value is stored as the latest history data in the first intensity value history storage unit 152A. However, as described above, at the time of setting the application mode, the initial value of the reference intensity value for the mechanical massage is stored as the first history data in the first intensity value history storage unit 152A. The first intensity value history storage unit 152A stores history data of the last five times of the mechanical massage.

The first intensity value history storage unit 152A has first to fifth areas E1 to E5. The first area E1, the second area E2, the third area E3, the fourth area E4, and the fifth area E5 store the current intensity value, the one-time previous intensity value, the two-time previous intensity value, the three-time previous intensity value, and the four-time previous intensity value, respectively, as history data. Hereinafter, the first region E1 of the first intensity value history storage unit 152A may be referred to as a "first intensity value storage unit 150A". The first intensity value storage unit 150A is an example of the "intensity value storage unit" of the present invention.

When the intensity value for each first body part of the air massage is changed by the intensity value changing function or optimized by the intensity value optimizing function, the changed intensity value or the optimized intensity optimized value is stored as history data in the second intensity value history storage unit 152B. However, the initial value (4 in the present embodiment) of the reference intensity value for the air massage is stored as the first history data in the second intensity value history storage unit 152B. The second intensity value history storage unit 152B stores history data of the last five times of the air massage.

The second intensity value history storage unit 152B has first to fifth areas E1 to E5. The first area E1, the second area E2, the third area E3, the fourth area E4, and the fifth area E5 store the current intensity value, the one-time previous intensity value, the two-time previous intensity value, the three-time previous intensity value, and the four-time previous intensity value, respectively, as history data.

Hereinafter, the first region E1 of the second intensity value history storage unit 152B may be referred to as "second intensity value storage unit 150B". The second intensity value storage unit 150B is an example of the "intensity value storage unit" of the present invention. Hereinafter, the first intensity value storage unit 150A and the second intensity value storage unit 150B are collectively referred to as "intensity value storage unit 150".

The optimum value calculation result storage unit 153 stores the calculation result of the optimum value. As described later, each time the history data of each first body part in the intensity value history storage unit 152 is updated, the optimum value of the intensity value of each first body part is calculated based on the updated history data of each first body part. Then, the calculated optimum value of the intensity value of each first body part is stored in the optimum value calculation result storage section 153.

Fig. 12 is a schematic diagram showing an example of the contents of the intensity value change table 154.

The intensity value change table 154 is a table used when the intensity value of each first body part is changed by the intensity value change function. In the intensity value change table 154, "the added value to the reference intensity value" corresponding to the intensity adjustment value is stored for each of the plurality of second body parts, the types of mechanical massage and air massage, and the first body part, which are more common than the first body part. Among the second plurality of body parts are five of the shoulder and back (including the shoulder and back), near the arms, the waist, near the pelvis, and the legs.

As described later, the intensity adjustment value can be set by the user for each second body part. In the present embodiment, as shown in the upper column of the intensity value change table 154, there are five intensity adjustment values of "-2", "-1", "normal (═ 0)", "1", and "2". The "added value to the reference intensity value" is a value obtained by adding the reference intensity values stored in the reference intensity value storage unit 151 in order to calculate the intensity value of each first body part after the change.

The massage history storage unit 155 stores, as massage history data, the ID and the intensity reference value of the massage item to be executed by the massage machine 2 in the application mode.

Returning to fig. 5, the control unit 90 includes an intensity adjustment value acquisition unit 92 and an intensity value change unit 93 to achieve the intensity value change function.

The intensity adjustment value acquisition unit 92 acquires the intensity adjustment value of each second body part based on the user operation.

The intensity value changing section 93 changes the intensity value of each first body part in the intensity value storage section 150 based on the massage intensity adjustment value of each second body part acquired by the intensity adjustment value acquiring section 92. As described above, the intensity value storage unit 150 corresponds to the first region E1 of the first intensity value history storage unit 152A and the first region E1 of the second intensity value history storage unit 152B.

The intensity value changing unit 93 includes a new intensity value calculating unit 93A and an updating unit 93B.

The new intensity value calculation unit 93A calculates a new intensity value of each first body part reflecting the intensity adjustment value, using the intensity adjustment value of each second body part acquired by the intensity adjustment value acquisition unit 92. Specifically, the new intensity value calculation unit 93A calculates a new intensity value for each body part using the intensity adjustment value for each second body part acquired by the intensity adjustment value acquisition unit 92 and the reference intensity value for each first body part stored in the reference intensity value storage unit 151.

In the present embodiment, the new intensity value calculation unit 93A calculates a new intensity value for each first body part based on the intensity adjustment value for each second body part acquired by the intensity adjustment value acquisition unit 92, the reference intensity value for each first body part stored in the reference intensity value storage unit 151, and the contents of the intensity value change table 154.

The updating unit 93B updates the content of the intensity value storage unit 150 based on the new intensity value of each first body part calculated by the new intensity value calculating unit 93A. In the present embodiment, the update unit 93B updates the content of the intensity value history storage unit 152 including the intensity value storage unit 150 based on the new intensity value of each first body part.

The control unit 90 includes the intensity adjustment value acquisition unit 92, the new intensity value calculation unit 93, the update unit 93B, the optimum value calculation unit 94, and the update unit 95 in order to achieve the intensity value optimization function.

The optimum value calculating unit 94 calculates the optimum value of the intensity of each first body part based on the history data of the last two times or more stored in the intensity value history storage unit 152. Specifically, the optimum value calculating unit 94 calculates the optimum value of the intensity of each first body part based on the average value of the history data of the last five times stored in the intensity value history storage unit 152. However, when the history data stored in the intensity value history storage unit 152 is less than five times, the optimum value calculation unit 94 calculates the optimum value of the intensity of each first body part based on the average value of the history data of the number of times stored in the intensity value history storage unit 152. In the present embodiment, the optimum value calculation unit 94 calculates the optimum value of the intensity of each body part and stores the optimum value in the optimum value calculation result storage unit 153 each time the content of the intensity value history storage unit 152 is updated by the update unit 93B or the update unit 95.

When "predetermined condition" is satisfied, the updating unit 95 updates the content of the intensity value storage unit 150 based on the intensity optimum value calculated by the optimum value calculating unit 96. In the present embodiment, when the "predetermined condition" is satisfied, the updating unit 95 updates the content of the intensity value history storage unit 152 including the intensity value storage unit 150 and the content of the reference intensity value storage unit 151 based on the intensity optimum value stored in the optimum value calculation result storage unit 153. The "predetermined conditions" will be described later.

[10] Detailed description of the function of changing the intensity value

When a massage item is determined in the human map mode, the health care mode, or the history mode, an item determination screen 160 such as that shown in fig. 13A is displayed on the operation display unit 103.

The item determination screen 160 displays the names, the massage times, and the contents of the massage items determined by the control unit 90, and also displays a personalized selection button 161, a massage start button 162, and the like. In the example of fig. 13A, the whole body fatigue recovery item is displayed as the name of the massage item.

The massage start button 162 displayed on the item determination screen 160 is operable, but the massage start button 177 displayed on the intensity adjustment value setting screen 170 of fig. 13B described later is not operable. Therefore, in the item determination screen 160, the massage start button 162 is displayed in a first color (for example, blue) indicating operability, and in the intensity adjustment value setting screen 170, the massage start button 177 is displayed in a second color (for example, gray) indicating non-operability.

When the user taps the massage start button 162, the control unit 90 of the portable terminal 3 transmits information including the ID of the massage item displayed on the item determination screen 160 (hereinafter referred to as "item ID") and the intensity value of each first body part stored in the intensity value storage unit 150 to the massage machine 2. When receiving the item ID and the intensity value of each first body part from the portable terminal 3, the control unit 60 of the massage machine 2 stores the intensity value of each first body part in the intensity value storage area 62. Then, the control unit 60 executes the massage item corresponding to the received item ID. At this time, the control section 60 controls the massage intensity based on the intensity value of each first body part in the intensity value storage area 62 (the intensity value of each first body part received this time).

The control unit 90 of the portable terminal 3 stores information including the item ID, the intensity value of each first body part, the transmission date and time (massage date and time) and the like transmitted to the massage machine 2 in the massage history storage unit 155 as massage history information. The massage history information stored in the massage history storage unit 155 is used as a massage item selection candidate for the history pattern. The massage history information stored in the massage history storage unit 155 is transmitted to the server 4 at a predetermined timing.

The personalized selection button 161 is provided for performing a strength value change function. When the user wants to change the intensity value of the massage intensity, the user taps the personalized selection button 161. When the personalized selection button 161 is tapped, an intensity adjustment value setting screen 170 as shown in fig. 13B is displayed on the operation display unit 103.

The intensity adjustment value setting screen 170 includes a title area F1, an adjustment value setting area F2, a button display area F3, and the like.

The header area F1 is an area at the upper end of the intensity adjustment value setting screen 170. The title name of "personalized selection" and the like are displayed in the title area F1.

The adjustment value setting area F2 is disposed below the header area F1. In the adjustment value setting area F2, first to fifth adjustment value setting sections 171 to 175 for setting the intensity adjustment value for the second body part by the user are displayed in a vertical arrangement. Details thereof will be described later.

The button display region F3 is disposed below the adjustment value setting region F2. In the button display region F3, an intensity value changing button 176 and a massage start button 177 are displayed. However, in the intensity adjustment value setting screen 170, the massage start button 177 is not operable, and therefore, the display is performed in a second color (gray in this example).

The first to fifth adjustment value setting sections 171 to 175 will be explained. The first adjustment value setting unit 171 is a setting unit for setting an intensity adjustment value for the shoulder and back. The second adjustment value setting unit 172 is a setting unit for setting an intensity adjustment value for the vicinity of the arm. The third adjustment value setting unit 173 is a setting unit for setting an intensity adjustment value for the waist. The fourth adjustment value setting unit 174 is a setting unit for setting an intensity adjustment value for the vicinity of the pelvis. The fifth adjustment value setting unit 175 is a setting unit for setting an intensity adjustment value for a leg.

In each of the adjustment value setting units 171 to 175, the user can set an intensity adjustment value of "-2", "-1", "normal (═ 0)", "1", or "2" for the corresponding second body part. Specifically, the user moves the circular pointer left and right by sliding or tapping, thereby setting the intensity adjustment value. Then, when the setting operation of the intensity adjustment value is completed, the user taps the intensity value change button 176. Thereby, the intensity value change instruction is input.

When the intensity value change instruction is input, the control unit 90 (intensity adjustment value acquisition unit 92) acquires the intensity adjustment value of each second body part. Then, the control unit 90 (new intensity value calculation unit 93A) calculates new intensity values of the respective first body parts reflecting the intensity adjustment values, using the intensity adjustment values of the respective second body parts acquired by the intensity adjustment value acquisition unit 92. Specifically, the new intensity value calculation unit 93A calculates a new intensity value for each first body part based on the intensity adjustment value for each second body part, the reference intensity value for each body part stored in the reference intensity value storage unit 151, and the content of the intensity value change table 154.

More specifically, the new intensity value calculation unit 93A first acquires the "added value to the reference intensity value" of each first body part from the intensity value change table 154 based on the intensity adjustment value of each second body part and the content of the intensity value change table 154. Next, the new intensity value calculation unit 93A calculates a new intensity value for each first body part by adding the "added value to the reference intensity value" for each first body part acquired from the intensity value change table 154 to the reference intensity value for the corresponding first body part.

According to the intensity value change table 154 in fig. 12, for example, when the intensity adjustment value for the waist is 2, the "added value to the reference intensity value" for the upper, lower, and lower portions of the waist in the mechanical massage is 16, and the "added value to the reference intensity value" for the lower, and upper portions of the waist in the air massage is 2. Therefore, the new intensity value calculation unit 93A calculates a new intensity value by adding 16 to the corresponding reference intensity value stored in the reference intensity value storage unit 151 for the upper, lower, and upper waists in the mechanical massage. For the waist in the air massage, the new intensity value calculation unit 93A adds 2 to the corresponding reference intensity value stored in the reference intensity value storage unit 151, thereby calculating a new intensity value.

Next, the control unit 90 (updating unit 93B) updates the content of the intensity value history storage unit 152 based on the new intensity value of each first body part calculated by the new intensity value calculating unit 93A. Specifically, the updating unit 93B transfers the history data of the first region E1, the second region E2, the third region E3, and the fourth region E4 in the intensity value history storage unit 152(152A, 152B) to the second region E2, the third region E3, the fourth region E4, and the fifth region E5, respectively, and then stores the new intensity value of each first body part in the first region E1.

Thus, the content of the intensity value storage unit 150 is updated simultaneously with the updating of the content of the intensity value history storage unit 152 including the intensity value storage unit 150.

When the content of the intensity value history storage unit 152 is updated by the updating unit 93B, the control unit 90 (optimum value calculating unit 94) calculates the optimum value of the intensity of each first body part based on the updated content of the intensity value history storage unit 152, and stores the optimum value in the optimum value calculation result storage unit 153. Thereby, the content of the optimum value calculation result storage unit 153 is updated. In the present embodiment, the optimum intensity value for each first body part is a value obtained by rounding the average value of the historical data of the last five times for the corresponding first body part.

When the content immediately after the update of the first intensity value history storage unit 152A is, for example, the content shown in fig. 11A, the average values (rounded values) of the history data of the last five times for each first body part of the shoulder, the shoulder lower, the back upper, the back lower, the waist upper, the waist lower, and the hip are 49, 44, 28, 33, and 33, respectively. In addition, when the content immediately after the update of the second intensity value history storage unit 152B is, for example, the content shown in fig. 11B, the average values (rounded values) of the history data of the last five times for each first body part of the upper arm, forearm, thigh, calf, and sole are 4, 3, 5, and 5.

When the intensity value change button 176 is tapped on the intensity adjustment value setting screen 170, the display screen changes from the intensity adjustment value setting screen 170 (fig. 13B) to the item determination screen 160 (fig. 13A). Subsequently, when the user taps the massage start button 163 on the item determination screen 160, the control unit 90 of the portable terminal 3 transmits the ID of the massage item displayed on the item determination screen 160 and the intensity value of each first body part stored in the intensity value storage unit 150 (the first region E1 of the intensity value history storage unit 152) to the massage machine 2.

When receiving the item ID and the intensity value of each first body part from the portable terminal 3, the control unit 60 of the massage machine 2 stores the intensity value of each first body part in the intensity value storage area 62. Then, the control unit 60 executes the massage item corresponding to the received item ID. At this time, the control section 60 controls the intensity value of the massage based on the intensity value of each first body part in the intensity value storage area 62 (the intensity value of each first body part received this time). Therefore, the intensity value of the massage is controlled based on the intensity value of each first body part after the intensity value is changed.

The method for setting the intensity adjustment value may be the following method (hereinafter, referred to as "another method"). In another method, as in the above-described method, when the personalized selection button 161 is tapped on the item determination screen 160, the intensity adjustment value setting screen 170 is displayed on the operation display unit 103. However, in another method, the intensity value setting units 171 to 175 can be operated only by tapping the intensity value change button 176 on the intensity adjustment value setting screen 170. The operation of each adjustment value setting unit 171 to 175 may be changed by an erroneous operation. Thus, the operator can check the adjustment value setting unit by operating the adjustment value setting unit, and the operator can be prevented from performing an erroneous operation.

When the intensity value change button 176 is tapped, the operable/inoperable state of the intensity value change button 176 is changed from operable to inoperable, and the operable/inoperable state of the massage start button 177 is changed from inoperable to operable.

In the case of the other method, the user sets the intensity adjustment value for each second body part by the adjustment value setting units 171 to 175 after tapping the intensity value change button 176. Then, when the setting of the intensity adjustment value by pressing the second body part is completed, the user taps the massage start button 177.

When the massage start button 177 is pushed, the control unit 90 (intensity adjustment value acquisition unit 92) acquires the intensity adjustment value of each second body part. Then, the control unit 90 (new intensity value calculation unit 93A) calculates a new intensity value for each first body part based on the intensity adjustment value for each second body part, the reference intensity value for each body part stored in the reference intensity value storage unit 151, and the content of the intensity value change table 154.

Next, the control unit 90 (updating unit 93B) updates the content of the intensity value history storage unit 152 based on the new intensity value of each first body part calculated by the new intensity value calculating unit 93A. When the content of the intensity value history storage unit 152 is updated by the updating unit 93B, the control unit 90 (optimum value calculating unit 94) calculates the optimum value of the intensity of each first body part based on the updated content of the intensity value history storage unit 152, and stores the optimum value in the optimum value calculation result storage unit 153.

Further, the control unit 90 transmits the ID of the massage item displayed on the item determination screen 160 immediately before being displayed on the intensity adjustment value setting screen 170 and the intensity value of each first body part stored in the intensity value storage unit 150 to the massage machine 2.

[11] Detailed description of the function of intensity value optimization

The optimization mode for optimizing the intensity value includes an automatic mode and a manual mode. The automatic mode is a mode in which the intensity value and the reference intensity value are changed by automatically optimizing each time the intensity value is changed by the intensity value changing function. The manual mode is a mode in which the intensity value and the reference intensity value are changed by the user clicking an optimization execution button 196 (see fig. 14A and 15A) described later to optimize the manual mode.

As described above, in the present embodiment, regardless of the optimization mode, the optimum value is calculated every time the content of the intensity value history storage unit 152 is updated, and is stored in the optimum value calculation result storage unit 153. The method of setting the optimization mode will be described later.

[11.1] optimization method in Manual mode

First, a method of optimizing the intensity value for the mechanical massage in the manual mode will be described.

For example, when the user taps the hamburger button 131 on the application home screen 130 shown in fig. 8A, a menu screen 180 as shown in fig. 8B is displayed in a pull-down menu mode. A plurality of menu selection buttons 181 to 187 including an optimization setting button 182 are displayed on a menu screen 180.

When the optimization setting button 182 is tapped by the user, an optimization setting screen 190A for the mechanical massage as shown in fig. 14A is displayed on the operation display unit 103. The optimization setting screen 190A has a title area F1, a mechanical/air selection area F2, an intensity value line display area F3, an execution button display area F4, and an optimization mode setting area F5.

The header area F1 is disposed at the upper end of the optimization setting screen 190A. The title name of "optimization setting" and the like are displayed in the title area F1.

The mechanical/air selection area F2 is disposed below the title area F1. In the machine/air selection area F2, a machine selection button 191 for displaying an optimization setting screen 190A for a mechanical massage and an air selection button 192 for displaying an optimization setting screen 190B (see fig. 15A) for an air massage are arranged in a horizontal direction.

Since the screen of fig. 14A is the optimization setting screen 190A for the mechanical massage, the mechanical selection button 191 is in a selected state. In the screen of fig. 14A, the colors of characters and the like on the mechanical selection button 191 and the air selection button 192 are displayed in different colors so that it can be recognized that the mechanical selection button 191 is selected and the air selection button 192 is not selected. Specifically, the characters or the like on the mechanical selection button 191 are displayed in a third color (for example, blue) indicating that the button is selected, and the characters or the like on the air selection button 192 are displayed in a fourth color (for example, gray) indicating that the button is not selected.

The user can switch the optimization setting screen 190A for the mechanical massage to the optimization setting screen 190B for the air massage by tapping the air selection button 192 on the optimization setting screen 190A (see fig. 15A).

The intensity value line display region F3 is disposed below the machine/air selection region F2. When the optimal setting screen image 190A is viewed from the front, a schematic view of the upper half of the human body when the upper half of the human body seated in the massage machine 2 is viewed from the left direction (hereinafter, referred to as a "body diagram 193") is displayed in the region of the left half of the intensity value line display region F3, and when the optimal setting screen image 190A is viewed from the front, a first intensity value line (reference intensity value line) 194 indicating the current reference intensity value for each first body part subjected to the mechanical massage and a second intensity value line 195 indicating the intensity value of each first body part when the optimization is performed are displayed in the region of the right half of the intensity value line display region F3.

The first intensity value line 194 is generated by drawing solid dots on the current reference intensity value of each first body part at the body part position in the body map 193 and at the position corresponding to the reference intensity value, and connecting these dots by straight lines. That is, the first intensity value line 194 is composed of eight solid dots indicating the current reference intensity value of each first body part, and seven line segments connecting two adjacent dots. The first intensity value line 194 is displayed in a fifth color (e.g., light blue).

The second intensity value line 195 is generated by drawing hollow dots at the body part position of the body diagram 193 and at a position corresponding to the intensity optimum value, and connecting the hollow dots by straight lines, the intensity optimum value for each first body part for mechanical massage stored in the optimum value calculation result storage unit 153. That is, the second intensity value line 195 is composed of eight hollow dots representing the intensity optimum value of each first body part, and seven line segments connecting two adjacent dots. The second intensity value line 195 is displayed in a sixth color (e.g., blue) that is distinguishable from the first intensity value line 194.

In the intensity value line display area F3, explanatory text is displayed indicating that the first intensity value line 194 (light blue line in this example) represents the current reference intensity value of each first body part, and the second intensity value line 195 (blue line in this example) represents the intensity value of each first body part when the optimization is performed.

The execution button display region F4 is disposed below the intensity value line display region F3. The execution button display area F4 displays a message indicating optimization based on the intensity value change history, and an optimization execution button 196.

The optimization execution button 196 displayed on the optimization setting screen 190A of fig. 14A is operable, but the optimization execution button 196 displayed on the optimization setting screen 190A of fig. 14B after optimization is executed is not operable. Therefore, in the optimization setting screen 190A of fig. 14A, the optimization execution button 196 is displayed in the first color (e.g., blue) indicating operability, and in the optimization setting screen 190A of fig. 14B, the optimization execution button 196 is displayed in the second color (e.g., gray) indicating non-operability.

The optimization mode setting area F5 is an area disposed below the execution button display area F4, and is an area near the lower end of the optimization setting screen 190A. A switch 197 for switching the optimization mode between the automatic mode and the manual mode is displayed in the optimization mode setting area F5. The switch 197 is composed of a bar and a circle, and in the off state, the circle is displayed on the left end side of the bar and has an eighth color (for example, gray), and in the on state, the circle is displayed on the right end side of the bar and has a ninth color (for example, blue) different from the eighth color.

When the switch 197 is turned off, the optimization mode is set to the manual mode, and when the switch 197 is turned on, the optimization mode is set to the automatic mode. The switch 197 is turned off in an initial state (default). In the example of fig. 14A, the switch 197 is off, and therefore the optimization mode is the manual mode.

The user determines whether to optimize based on the first line 194 and the second line 195 of intensity values. When it is determined that the optimization is not to be performed, the user taps a return button or the like to return the display screen to, for example, the application home screen 130.

On the other hand, when it is determined that the optimization is to be performed, the user taps the optimization execution button 196. Thereby, the optimized execution instruction is input. When the optimization execution command is input, the control unit 90 (updating unit 95) updates the content of the reference intensity value storage unit 151 and the content of the first intensity value history storage unit 152A based on the intensity optimum value for each first body part of the mechanical massage stored in the optimum value calculation result storage unit 153.

Specifically, the updating unit 95 writes the intensity optimum value for each first body part of the mechanical massage stored in the optimum value calculation result storage unit 153 into the reference intensity value storage unit 151. The updating unit 95 also transmits the history data of the first region E1, the second region E2, the third region E3, and the fourth region E4 in the first intensity value history storage unit 152A to the second region E2, the third region E3, the fourth region E4, and the fifth region E5, respectively, and then stores the optimal intensity value for each first body part for the mechanical massage in the first region E1. Thus, the content of the first intensity value history storage unit 152A is updated, and the content of the first intensity value storage unit 150A is updated.

When the content of the first intensity value history storage unit 152A is updated, the optimum value calculation unit 94 calculates an optimum intensity value based on the content of the updated first intensity value history storage unit 152A, and stores the optimum intensity value in the optimum value calculation result storage unit 153.

When the optimization execution button 196 is pressed, the display screen changes from the optimization setting screen 190A shown in fig. 14A to the optimization setting screen 190A shown in fig. 14B. In the optimization setting screen 190A in fig. 14B, the color of the first intensity value line 194 is changed from the fifth color (light blue in this example) to a seventh color (for example, gray) different from both the fifth color and the sixth color (blue in this example). In addition, the hollow portion of the dot of the second intensity value line 195 is filled with a fifth color (light blue in this example). In addition, in the intensity value line display area F3, "optimization completion" is displayed. "is received. Also, the color of the optimization execution button 196 is changed from a first color (blue in this example) indicating operable to a second color (gray in this example) indicating inoperable.

Next, a method of optimizing the intensity value for the air massage in the manual mode will be described.

For example, when the user taps the air selection button 192 on the optimization setting screen 190A shown in fig. 14A or 14B, the display screen changes from the optimization setting screen 190A for the mechanical massage to the optimization setting screen 190B for the air massage as shown in fig. 15A.

The optimization setting screen 190B has a title area F1, a mechanical/air selection area F2, an intensity value bar display area F3, an execution button display area F4, and an optimization mode setting area F5. The optimization setting screen 190B is substantially the same as the optimization setting screen 190A, but the display content in the intensity value bar display region F3 is different from the display content in the intensity value line display region F3.

The title name of "optimization setting" and the like are displayed in the title area F1.

In the mechanical/air selection region F2, the mechanical selection button 191 and the air selection button 192 are arranged in a lateral direction. Since the screen in fig. 15A is the optimization setting screen 190B for the air massage, the air selection button 192 is in a selected state. Thus, text or the like on the air selection button 192 is displayed in a third color (e.g., blue) indicating that the button is selected, and text or the like on the mechanical selection button 191 is displayed in a fourth color (e.g., gray) indicating that the button is not selected.

The user can switch the optimization setting screen 190B for the air massage to the optimization setting screen 190A for the mechanical massage by tapping the machine selection button 191 on the optimization setting screen 190B (see fig. 14A).

In the intensity value bar display area F3, a first intensity value bar 201 indicating the current reference intensity value and a second intensity value bar 202 indicating the optimized intensity value are displayed for each first body part for the air massage. The current reference intensity value is the reference intensity value of the corresponding first body part in the second reference intensity value storage unit 151B. The intensity value at the time of optimization is the intensity optimum value of the corresponding first body part in the optimum value calculation result storage section 153.

When the optimization setting screen 190B is viewed from the front, in the area of the left half of the intensity value bar display area F3, the bar display portions for the upper arm, forearm, and waist, which are divided by the region, are arranged at intervals in the vertical direction. In the right half of the intensity value bar display region F3, bar display portions for the thigh, the calf, and the sole, which are divided by region, are arranged at intervals in the vertical direction.

A first intensity value bar 201 indicating a current reference intensity value for the corresponding body part and a second intensity value bar 202 indicating an optimized intensity value for the corresponding body part are displayed on the respective bar display sections for each part. The first intensity value bar 201 is a straight line extending in the lateral direction and having a length corresponding to the current reference intensity value (1-7). Therefore, the greater the current reference intensity value, the longer the length of the first intensity value bar 201. In the present embodiment, the first intensity value bar 201 is displayed in a fifth color (light blue in this example).

The second intensity value bar 202 is a line extending in the transverse direction and having a length corresponding to the optimized intensity values (1-7), and is shown below the first intensity value bar 201. Thus, the greater the optimized intensity value, the longer the length of the second intensity value bar 202. In this embodiment, the second intensity value bar 202 is displayed in a sixth color (blue in this example).

In the intensity value bar display area F3, explanatory text indicating that the first intensity value bar 201 (light blue bar in this example) represents the current reference intensity value of each first body part, and the second intensity value bar 202 (blue bar in this example) represents the intensity value of each first body part when optimization is performed is displayed.

In the execution button display area F4, a message indicating optimization based on the intensity value change history and an optimization execution button 196 are displayed. The optimization execution button 196 is displayed in a first color (blue in this example) indicating the operable state.

A switch 197 for switching the optimization mode between the automatic mode and the manual mode is displayed in the optimization mode setting area F5. In the example of fig. 15, the switch 197 is off, and therefore the optimization mode is the manual mode.

The user determines whether to optimize based on the first intensity value bar 201 and the second intensity value bar 202 for each body part. When it is determined that the optimization is not to be performed, the user taps a return button or the like to return the display screen to, for example, the application home screen 130.

On the other hand, when it is determined that the optimization is to be performed, the user taps the optimization execution button 196. Thereby, the optimized execution instruction is input. When the optimization execution command is input, the control unit 60 (updating unit 95) updates the contents of the reference intensity value storage unit 151 and the contents of the second intensity value history storage unit 152B based on the intensity optimum values for the respective first body parts of the air massage stored in the optimum value calculation result storage unit 153.

Specifically, the updating unit 95 writes the intensity optimum value for each first body part of the air massage stored in the optimum value calculation result storage unit 153 into the reference intensity value storage unit 151. The updating unit 95 also transmits the history data of the first region E1, the second region E2, the third region E3, and the fourth region E4 in the second intensity value history storage unit 152B to the second region E2, the third region E3, the fourth region E4, and the fifth region E5, respectively, and then stores the optimal intensity value for each first body part for the air massage in the first region E1. Thus, the content of the second intensity value history storage unit 152B is updated, and the content of the second intensity value storage unit 150B is updated.

When the content of the second intensity value history storage unit 152B is updated, the optimum value calculation unit 94 calculates an optimum value of intensity based on the updated content of the second intensity value history storage unit 152B, and stores the optimum value in the optimum value calculation result storage unit 153.

When the optimization execution button 196 is pressed, the display screen changes from the optimization setting screen 190B shown in fig. 15A to the optimization setting screen 190B shown in fig. 15B. In the optimization setting screen 190B of fig. 15B, the color of the first intensity value line 194 is changed from the fifth color (light blue in this example) to the seventh color (gray in this example). In addition, in the intensity value bar display area F3, "optimization completion" is displayed. "is received. Also, the color of the optimization execution button 196 is changed from a first color (blue in this example) indicating operable to a second color (gray in this example) indicating inoperable.

In the present embodiment, when the optimization mode is set to the manual mode, the "predetermined condition" is "operation of the optimization execution button 196 (input of the optimization execution command)".

[11.2] description of automatic mode

For example, when the user turns on the switch 197 on the optimization setting screens 190A and 190B in fig. 14A, 14B, 15A, and 15B, the optimization mode is set to the automatic mode. When the optimization mode is set to the automatic mode, the optimization execution button 19 is inoperable in fig. 14A and 15A. Therefore, in fig. 14A and 15A, the optimization execution button 19 is displayed in a second color (gray in this example).

As described above, when the intensity value change button 176 on the intensity adjustment value setting screen 170 (see fig. 13B) is pressed, the new intensity value calculation unit 93A calculates a new intensity value for each first body part. Then, the control unit 90 (updating unit 93B) updates the content of the intensity value history storage unit 152 (intensity value storage unit 150) based on the new intensity value of each first body part. Then, the control unit 90 (optimum value calculating unit 94) calculates the optimum value of the intensity of each first body part based on the content of the updated intensity value history storage unit 152, and stores the optimum value in the optimum value calculation result storage unit 153.

When the optimization mode is set to the automatic mode, the control unit 90 (updating unit 95) updates the content of the reference intensity value storage unit 151 based on the intensity optimum value of each first body part stored in the optimum value calculation result storage unit 153 at that point in time each time the intensity value change button 176 on the intensity adjustment value setting screen 170 is pressed.

In the present embodiment, when the optimization mode is set to the automatic mode, the "predetermined condition" is "operation of the intensity value change button 176 (input of an intensity value change instruction)".

In the above-described another method, since the intensity value is changed by operating the massage start button 177, it is considered that the command input by operating the massage start button 177 substantially includes a command (intensity value change command) for changing the intensity value. Therefore, when the above-described another method is adopted and the optimization mode is set to the automatic mode, the "predetermined condition" is "operation of the massage start button 177 (input of the intensity value change instruction) on the intensity adjustment value setting screen 170".

The "predetermined condition" in the manual mode and the "predetermined condition" in the automatic mode are summarized, and the "predetermined condition" is that "an optimization execution command is input in the manual mode" or "an intensity value change command is input in the automatic mode".

In the present embodiment, the intensity value for each first body part of the mechanical massage can be changed for each second body part (in the present embodiment, around the shoulder, the back, the arms, the waist, and the pelvis). In addition, the intensity value for each first body part for the air massage can be changed for each second body part (in the present embodiment, the vicinity of the arm, the waist, the vicinity of the pelvis, and the leg).

In addition, in the present embodiment, the intensity value for each first body part of the mechanical massage can be optimized based on the history of changes in the intensity value for each first body part of the mechanical massage. Thus, the intensity value for each first body part of the mechanical massage can be easily set according to the preference of the user.

In addition, in the present embodiment, the intensity value for each first body part of the air massage can be optimized based on the history of changes in the intensity value for each first body part of the air massage. Thus, the intensity value for each first body part for the air massage can be easily set according to the preference of the user.

[12] Modification example

While the embodiments of the present invention have been described above, the present invention may be implemented in other embodiments. For example, in the above-described embodiment, when the new intensity value of each first body part is calculated by the new intensity value calculation unit 93A, the control unit 90 (the update unit 93B) updates the content of the intensity value history storage unit 152 based on the new intensity value of each first body part. At this time, the control unit 90 may further transmit the new intensity value of each first body part to the massage machine 2, and the control unit 60 may store (overwrite) the new intensity value of each first body part in the intensity value storage area 62.

The control unit 90 (updating unit 95) may further perform the following operation when updating the contents of the intensity value history storage unit 152 and the reference intensity value storage unit 151 based on the intensity optimum value of each first body part. That is, the updating unit 95 may transmit the intensity optimum value of each first body part to the massage machine 2, and the control unit 60 may store (overwrite) the intensity optimum value of each first body part in the intensity value storage area 62.

In the intensity adjustment value setting screen 170 (see fig. 13B), the intensity adjustment value is set for the second body part, but the intensity adjustment value may be set for the first body part. Further, the intensity adjustment value may be set for a plurality of body parts different from the second body part and the first body part.

In the above-described embodiment, the new intensity value calculation unit 93A calculates the new intensity value using the intensity adjustment value and the reference intensity value, but the current intensity value (the intensity value stored in the intensity value storage unit 150) may be used instead of the reference intensity value. In this case, the reference intensity value storage unit 151 is not necessary.

In the above-described embodiment, the control unit 90 has the intensity value changing function and the intensity value optimizing function, but may not have the intensity value optimizing function.

In the above-described embodiment, the sole- side air bags 35c and 35d for pressing the sole upward are provided on the bottom surfaces of the pair of left and right foot accommodating recesses 19 (see fig. 2), but a sole roller that is driven to rotate for massaging the sole may be provided instead of the sole- side air bags 35c and 35 d.

In the above-described embodiment, the mobile terminal 3 is a smartphone, but the mobile terminal 3 may be a computer such as a tablet computer.

In the above-described embodiment, the massage machine 2 is a chair-type massage machine, but the massage machine 2 may be a massage machine other than a chair-type massage machine.

Although the embodiments of the present invention have been described in detail, these are merely specific examples used for clarifying the technical content of the present invention, and the present invention should not be construed as being limited to these specific examples, and the scope of the present invention is limited only by the claims attached hereto.

This application corresponds to Japanese patent application No. 2020-.

Claims (16)

1. A massage machine which controls a massage intensity based on an intensity value of the massage intensity for a plurality of first body parts,

the massage machine comprises:

an intensity value storage unit that stores an intensity value of each of the first body parts;

an intensity adjustment value acquisition unit that acquires intensity adjustment values for each of a plurality of second body parts; and

an intensity value changing unit that changes the intensity value of each of the first body parts in the intensity value storage unit based on the massage intensity adjustment value of each of the second body parts acquired by the intensity adjustment value acquiring unit.

2. The massager of claim 1 wherein,

the intensity value changing unit includes:

a new intensity value calculation unit that calculates a new intensity value of each of the first body parts reflecting the intensity adjustment value, using the intensity adjustment value of each of the second body parts acquired by the intensity adjustment value acquisition unit; and

an updating unit that updates the content of the intensity value storage unit based on the new intensity value of each of the first body parts calculated by the new intensity value calculating unit.

3. The massager of claim 1 wherein,

the first body part is a detailed part of each part of the body of the person to be treated that can be treated by the massage machine,

the second body part is an enlarged range part obtained by summarizing the detailed parts of the plurality of first body parts.

4. The massager of claim 1 wherein,

the massage machine comprises a remote controller which can communicate with the massage machine,

the remote controller includes the intensity adjustment value acquisition unit and the intensity value change unit.

5. The massager of claim 2 wherein,

the massage machine comprises a remote controller which can communicate with the massage machine,

the remote controller includes the intensity adjustment value acquisition unit and the intensity value change unit.

6. The massager of any one of claims 1 to 5 wherein,

the massage is a mechanical massage using a treatment member.

7. The massager of any one of claims 1 to 5 wherein,

the massage is an air type massage using an air bag.

8. The massager of any one of claims 1 to 5 wherein,

the massage includes a mechanical massage using a treatment member and an air massage using an air bag.

9. A massage system which controls massage intensity based on an intensity value of the massage intensity for a plurality of first body parts, wherein,

the massage system includes:

an intensity value storage unit that stores an intensity value of each of the first body parts;

an intensity adjustment value acquisition unit that acquires intensity adjustment values for each of a plurality of second body parts; and

an intensity value changing unit that changes the intensity value of each of the first body parts in the intensity value storage unit based on the massage intensity adjustment value of each of the second body parts acquired by the intensity adjustment value acquiring unit.

10. The massage system of claim 9,

the intensity value changing unit includes:

a new intensity value calculation unit that calculates a new intensity value of each of the first body parts reflecting the intensity adjustment value, using the intensity adjustment value of each of the second body parts acquired by the intensity adjustment value acquisition unit; and

an updating unit that updates the content of the intensity value storage unit based on the new intensity value of each of the first body parts calculated by the new intensity value calculating unit.

11. The massage system of claim 9,

the first body part is a detailed part of each part of the body of the person to be treated that can be treated by the massage machine,

the second body part is an enlarged range part obtained by summarizing the detailed parts of the plurality of first body parts.

12. The massage system of claim 9,

the massage system includes:

a massage machine which performs massage; and

a portable terminal capable of communicating with the massage machine,

the portable terminal includes the intensity adjustment value acquisition unit and the intensity value change unit.

13. The massage system of claim 10,

the massage system includes:

a massage machine which performs massage; and

a portable terminal capable of communicating with the massage machine,

the portable terminal includes the intensity adjustment value acquisition unit and the intensity value change unit.

14. The massage system of any one of claims 9-13,

the massage is a mechanical massage using a treatment member.

15. The massage system of any one of claims 9-13,

the massage is an air type massage using an air bag.

16. The massage system of any one of claims 9-13,

the massage includes a mechanical massage using a treatment member and an air massage using an air bag.

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