JP3978036B2 - Massage machine - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
[0002]
The present invention relates to a massage machine, and more particularly to a massage machine suitable for force control of a treatment element.
[Prior art]
[0003]
In a conventional massage machine, the treatment element usually operates in a fixed orbit. However, since the massage operation becomes uniform, for example, in the massage machine disclosed in Japanese Patent Application Laid-Open No. 2000-167020, the treatment element operates in accordance with the operation amount of the operation tool. Massage according to the preference of the user is possible.
[Problems to be solved by the invention]
[0004]
By the way, massage such as manual massage and acupressure is performed while adjusting the pressing force. However, none of the conventional massage machines can control the pressing force of the treatment element on the user, and therefore any input device is suitable for the massage machine that can control the pressing force. It was not even considered.
[0005]
The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a massage machine using an input device suitable for a massage machine capable of controlling a pressing force on a user.
[Means for Solving the Problems]
[0006]
In order to solve the above-described problems, a massage machine according to the present invention includes a closed container-like grip portion that is filled with a fluid and is elastically deformable at least in the radial direction, and an elastic deformation of the grip portion. An input device having a first pressure sensor for detecting an increase and a decrease in pressure of the fluid and outputting a detection signal, a treatment element for massaging a user, and the treatment A second pressure which is disposed in an air cell for massaging the child by expansion and contraction and an air pipe for supplying and discharging air for expanding and contracting the air cell to the air cell, and detects a pressing force of the treatment element on the user sensor and, the basis of the pressing force detected by the second pressure sensor, the pressing force against the treated person of the treatment element in accordance with a detection signal output from the first pressure sensor of the input device air And control means for controlling via the Le, those having a (claim 1). With this configuration, the user can input a massage command in a suitable manner because the user can perceive and input the desired intensity of massage in a pseudo manner. Furthermore, since the grip portion of the input device can be elastically deformed in the radial direction and the deformation is detected by the pressure of the fluid, the grip portion has little directionality, and therefore, an input operation can be easily performed.
[0007]
In this case, the input device includes an operation member in which the grip portion is formed in a shape extending along a predetermined axis and a fixing portion is formed at one end of the grip portion, and the fixing portion of the operation member is connected to the predetermined axis. A base that is pivotably fixed around the rotation member, and a rotation amount detection unit that detects a rotation amount of the operation member and outputs a detection signal; and the control unit is output from the rotation amount detection unit. The operation of the treatment element may be controlled based on the detection signal (claim 2). With this configuration, two types of commands can be input by operating one operation member. In addition, since one of the commands can be input by elastically deforming the grip portion of the operation member in the radial direction, the other command can be easily input while rotating the grip portion.
[0008]
In this case, the massage machine is of a chair type, and the input device further includes a bendable support column that supports the base body, and is attached so as to stand on an armrest portion of the massage machine by the support column. It may be further provided with a bending-deformable column that supports the base body (claim 3). With this configuration, when the user grips the grip part with one hand, the strut bends and the grip part moves back and forth according to the physique of the user, so that the user operates the input device in a suitable state Can do.
[0009]
In the above case, the grip portion of the input device may be formed in a sealed bag shape made of an elastic body, and the fluid may be air. With such a configuration, since the viscosity of the air as the fluid is relatively low, the response speed of the output with respect to the gripping force as the input is relatively improved.
DETAILED DESCRIPTION OF THE INVENTION
[0010]
Embodiments of the present invention will be described below with reference to the drawings.
Embodiment (input device)
FIG. 1 is a longitudinal sectional view showing a configuration of an input device according to an embodiment of the present invention, and FIG. 2 is a view taken in the direction of arrow A in FIG.
[0011]
As shown in FIGS. 1 and 2, the input device 12 according to the present embodiment is configured to include an operation member 201, a base body 202, and a support column 203 as main components.
[0012]
The operation member 201 has a spindle shape, that is, a cylindrical container 204 having a circular cross section and both end portions 204a and 204b formed with a constant diameter and gradually expanding from there to the center. A plug body 223 and a fixed shaft 205 are fitted into both ends 204a and 204b of 204, respectively. The container 204 has such rigidity that it can hold its shape and elasticity that can be easily deformed in the radial direction when gripped by a hand, and is made of a flexible elastic body such as rubber.
[0013]
The plug body 223 has a cylindrical plug body 206 having a large diameter portion 206c formed in the middle of the inner hole, and the ball 207 is accommodated in the large diameter portion 206c of the inner hole of the plug body 206. And a compression spring 208 is interposed between one end face of the large-diameter portion 206c. As a result, the ball 208 is pressed against the other inclined end surface 206b of the large diameter portion 206c by the urging force of the compression spring 208, thereby forming a check valve. The plug body 206 is press-fitted into the end portion 204a of the container 204 so that the end surface in the direction in which the ball 207 is pressed is on the outside, and is fixed to the end portion 204a by appropriate means (not shown). . An opening 206a into the end face of the inner hole of the plug body 206 constitutes an inlet for the fluid into the grip portion 224, which will be described later.
[0014]
The fixed shaft 205 is formed in a stepped columnar shape, and the large diameter portion 205b is press-fitted into the other end portion 204b of the container 204, and is fixed to the end portion 204b by appropriate means (not shown). A pressure sensor 210 is embedded in the end surface on the large-diameter side of the fixed shaft 205, and a signal line 211 for transmitting the detection output is led out through a through hole 205c formed in the fixed shaft 205. . The container 204, the plug body 223, and the large-diameter portion 205b of the fixed shaft 205 configured as described above constitute the grip portion 224 of the operation member 201, and the small-diameter portion 205a of the fixed shaft 205 is the fixed portion of the operation member 201. Is configured. The grip portion 224 forms a sealed container, and the fluid 209 is injected into the inside from the above-described injection port 206a, and is sealed by a check valve including the above-described ball 207 and compression spring 208. Since the fluid 209 is required to have a high-speed response to the grip deformation of the grip portion 224, it is preferable that the fluid 209 is elastically deformable and has a low viscosity. In this embodiment, the fluid 209 is composed of air pressurized to atmospheric pressure or higher. ing.
[0015]
The base body 202 is formed in a plate shape, and a cylindrical insertion part 202d is formed at the lower end. In addition, a shaft hole 202a is formed in the upper portion of the base body 202 so as to penetrate in the thickness direction, and passes from the center of the shaft hole 202a through the inside of the base body 202 to the lower end of the insertion portion 202d. A hole 202b is formed. Then, the small diameter portion 205a of the fixed shaft 205 of the operation member 201 is rotatably inserted into the shaft hole 202a, and the retaining ring 222 is fitted into the groove 205c formed in the outer peripheral surface of the portion protruding from the shaft hole 202a. Is stopped in the axial direction. A washer 221 is disposed between the large diameter portion 205b of the fixed shaft 205 and the base body 202. Further, a dog 214 is formed in a portion of the fixed shaft 205 protruding from the shaft hole 202a so as to protrude downward at a reference position in the rotation of the operation member 201 shown in FIG. The other end of the return spring 213 made of a coil spring is connected. A pair of limit switches 215 and 216 are arranged on the base body 202 so that the actuators 215a and 216a are positioned on both sides of the dog 214 with a predetermined interval. Further, the through hole 205c of the fixed shaft 205 is formed so as to communicate with the through hole 202b of the base body 202 when the operation member 202 is at the reference position. Further, the through hole 205c of the fixed shaft 205 is formed so as to open over a wide range in the circumferential direction on the outer peripheral surface of the fixed shaft 205, thereby rotating the fixed shaft in both directions within a certain angular range. However, the through-hole 205c communicates with the through-hole 202b of the base body 202.
[0016]
The column 203 is preferably formed of a columnar member that can be bent by elastic deformation or plastic deformation. In this embodiment, the column 203 is formed of a flexible pipe, for example. Then, the insertion portion 202 d of the base body 202 is fitted into the upper end of the column 203 and fixed to the column 203 with a set screw 212. A signal line 211 of the pressure sensor 210 of the operation member 201 is introduced from the through hole 205c of the fixed shaft 205 into the through hole 202c of the base body 202. In addition, a pair of signal lines 217 and 218 for transmitting the detection outputs of the pair of limit switches 215 and 216 reach the through-hole 202b through the through-holes 202c and 202c of the base body 202, and there is a batch with the signal line 211 of the pressure sensor 210. The signal line harness 219 is led out to the outside through the through hole 202c of the base body 202 and the inner hole of the column 203.
[0017]
Next, the operation of the input device configured as described above will be described.
[0018]
In FIGS. 1 and 2, when the operator grips the grip portion 224 of the operation member 201 with one hand and applies force, the operator receives a reaction force due to the elasticity from the grip portion 224. Then, when the grip portion 224 is gripped with a certain strength against this reaction force, the diameter of the grip portion of the grip portion 224 decreases according to the grip force, and the pressure of the fluid 209 increases. Then, the pressure sensor 210 detects this increase in pressure, and outputs this detection signal to the outside through the signal line 211. Next, when the operator weakens the gripping force, the diameter of the gripped portion of the grip portion 224 increases by the elasticity, and the pressure of the fluid 209 decreases, and the pressure sensor 210 detects this pressure drop. Output to the outside. Thereby, the operator can input grip strength. In other words, a certain command can be input while feeling the reaction force from the input device 12. In addition, since the grip portion 204 of the operation member 201 is composed of a flexible body 204 and a fluid 209 made of pressurized air, a high-speed response of output to a grip force input is possible. .
[0019]
Next, when the operator rotates the operation member 201 in the clockwise direction (solid line direction in FIG. 1) while holding the grip 224, the operation member 201 rotates around the central axis 301 in the clockwise direction. . Then, the dog 214 of the fixed shaft 205 contacts the actuator 215a of the limit switch 215 and swings it to a predetermined position. Then, the limit switch 215 outputs a signal (hereinafter referred to as a switching signal) indicating the change of the electrical contact from open to closed or the change from closed to open through the signal line 217. On the other hand, when the operating member 201 is turned counterclockwise (dotted line direction in FIG. 1), the operating member 201 is rotated counterclockwise, and the dog 214 comes into contact with the actuator 216a of the limit switch 216 to reach a predetermined position. Rock. Then, the limit switch 216 outputs a switching signal to the outside through the signal line 218. Thus, the operator can input another command by turning the operation member 201. In addition, the other command can be easily input while grasping the grip portion 224.
[0020]
When the operator releases his / her hand while turning the operation member 201, the operation member 201 is rotated by the return spring 213 and returned to the reference position.
(Massage machine)
3 is a perspective view showing the overall configuration of the massage machine according to the present embodiment, and FIG. 4 is a piping and block diagram showing the configuration of the control system of the massage machine of FIG.
[0021]
As shown in FIG. 3, the massage device 1 according to the present embodiment is a chair-type massage device, and includes a backrest portion 2, a seat portion 3, and a pair of left and right armrest portions 4 and 4. Yes. A massage driving unit 6 and an elevating mechanism 5 are disposed inside the backrest unit 2. The elevating mechanism 5 includes a ball screw 9 extending along the center line of the backrest 2 and an elevating motor 10 that rotates the ball screw 9 in both forward and reverse directions, and a screwing portion 7 a of the elevating mechanism 5 is attached to the ball screw 9. It is screwed. Accordingly, when the lifting motor 10 rotates, the massage driving unit 6 moves in the vertical direction (Z-axis direction) according to the rotation. An input device 12 is disposed on one armrest portion 4.
[0022]
Referring also to FIG. 4, the massage driving unit 6 includes a base 7 on which a screw 7 a with the ball screw 9 is formed, a support member 13 disposed on the front surface of the base 7, and a left-right direction (Y-axis direction). An oscillating plate 15 attached to a support member 13 so as to be rotatable around a rotating shaft 14 extending in a straight line, a treatment element 8 projecting from the front surface of the oscillating plate 15, an oscillating plate 15 and a base 7. And an air cell 17 which is disposed between and expands and contracts when compressed air is supplied and discharged. As a result, when the air cell 17 expands and contracts, the swing plate 15 swings in the substantially front-rear direction (substantially X-axis direction) about the rotation shaft 14, thereby the treatment element 8 advances and retracts in the substantially front-rear direction.
[0023]
The air cell 17 is connected to the air pump 18 via a switching valve 19 and throttles A and B connected in series to the switching valve 19 and connected in parallel to each other. The switching valve 19 switches between air supply and exhaust to the air cell 17. The apertures of the apertures A and B are fixed, and the aperture of the aperture B is set to be larger than that of the aperture A. In the present embodiment, the opening of the diaphragm B is set to be twice the opening of the diaphragm A. Thus, when the switching valve 19 is switched to the air supply mode or the exhaust mode, the air cell 17 is supplied or exhausted, and the air cell 17 expands or contracts accordingly. Further, when the throttles A and B are opened and closed to change the total opening thereof, the speed of air supply or exhaust to the air cell 17 changes.
[0024]
Moreover, the massage machine 1 has the control apparatus 20 which consists of CPU. The detection output of the input device 12 is input to the control device 20. 1 and 2, the input device 12 is the above-described input device, and the detection output of the pressure sensor 210 is transmitted to the control device 20 as a gripping force (massage command indicating massage strength) with respect to the operation member 201. Have been entered. Further, the detection outputs of the limit switches 215 and 216 are input to the control device 20 as the height command (another massage command) of the treatment element 8. Then, the control device 20 stops the lifting motor 10 when no switching signal is input from either of the limit switches 215 and 216, and forwards the lifting motor 10 when a switching signal is input from the limit switch 215, When a switching signal is input from the limit switch 216, the lifting motor 10 is reversed. As a result, when the operation member 201 of the input device 12 is at the reference position, the elevating motor 10 stops, the treatment element 8 stops, the operation member 201 is rotated clockwise, and a switching signal is sent from the limit switch 215. When it is output, the lifting motor 10 rotates in the forward direction and the massage driving unit 6 moves up. When the operation member 201 is turned counterclockwise and a switching signal is output from the limit switch 216, the lifting motor 10 rotates in the reverse direction. Then, the massage driving unit 6 is lowered.
[0025]
As shown in FIG. 4, the massage driving unit 6 is provided with a position sensor 21 for detecting the rotation angle of the swing plate 15 and close to the air cell 17 of the air piping from the air cell 17 to the switching valve 19. A pressure sensor 31 is disposed in the portion, and detection outputs of the position sensor 21 and the pressure sensor 31 are input to the control device 20, respectively. The detection values of the pressure sensor 31 and the position sensor 21 are converted into the pressing force and position of the treatment element 8 in the control device 20, respectively. The position sensor 21 is composed of, for example, a potentiometer, an encoder, and the like. The switching valve 19 has an air supply control coil S and an exhaust control coil E connected to the control device 20, and the switching of the supply and discharge is controlled by the control device 20. The apertures A and B are controlled to be opened and closed by the control device 20.
[0026]
Next, operation | movement of the massage machine 1 comprised as mentioned above is demonstrated using the flowchart of FIG.5 and FIG.6. FIG. 5 is a flowchart showing the contents of the control program stored in the control device 20, and FIG. 6 is a flowchart showing the contents of the feedback control in the flowchart of FIG.
[0027]
Below, operation | movement of the massage machine 1 is demonstrated based on a user's standard operation.
[0028]
1 to 6, when a user sits on the massage machine 1 and turns on a start switch (not shown), the massage machine 1 is started. The user first holds the grip portion 224 of the operation member 201 of the input device 12 with one hand, and turns the operation member 201 clockwise or counterclockwise. Then, the elevating motor 10 rotates normally or reversely, and the massage driving unit 6 rises or descends, whereby the position of the treatment element 8 in the vertical direction is adjusted to suit itself. At this time, if the user grips the grip part 224 of the operation member 201 with one hand, the column 203 is bent according to the physique of the user and the grip part 224 moves back and forth, so that the user can input in a suitable state. The device 12 can be operated.
[0029]
On the other hand, when the massage machine 1 is started, the control device 20 first performs an initial setting of this control program (step S1). This initial setting includes a lower limit value Fmin of a pressing force (hereinafter simply referred to as a pressing force) F of the treatment element 8 to a user, an upper limit value Pmax of the position (hereinafter simply referred to as a position) P of the treatment element 8 and a pressing force F. This is performed by setting one-side dead zone Fd and one-side dead zone Pd at position P. Here, for example, Fmin = 3 kg, Pmax = 30 mm, Fd = 1 kg, and Pd = 1.5 mm. Next, the control device 20 acquires the pressing force F detected by the pressure sensor 31 (step S2), and compares this pressing force F with the lower limit value Fmax (step S3). Here, it is assumed that the user is not drowning in the backrest 2 and the treatment element 8 is not in contact with the user. Then, since the pressing force F is 0 kg, the control device 20 proceeds to step S4, acquires the position P detected by the position sensor 21, and then acquires the instruction value I (step S5). The instruction value I is a grip force input from the input device 12 in the present embodiment. Next, the position of the treatment element 8 is feedback-controlled using the position P, which is an output value, toward the instruction value I. At this time, first, variable conversion is performed (step S6). This is because feedback control for the position of the treatment element 8 and feedback control for the pressing force of the treatment element 8 are performed by a common program. This variable conversion is performed by converting one-side dead zone TDZ = one-side dead zone Pd of position, current value TPF = position P, converted command value I ′ = command value I converted into position, command value TID = I ′. . Here, the instruction value I is converted to I ′ because the instruction value I represents the gripping force with respect to the operation member 201, and this is converted into a position P that is a conversion value of the detection output of the position sensor 21. Because. This conversion is performed by dividing the indicated value I by a predetermined elastic coefficient.
[0030]
Next, feedback control for the position of the treatment element 8 is executed (step S7), and then the process returns to step S1. The contents of this feedback control will be described later. Thereby, the treatment element 8 moves to a position corresponding to the grip deformation amount of the operation member 201. Hereinafter, the control state for the treatment element 8 is referred to as position control. And this position control is continued unless the pressing force F becomes more than the lower limit Fmin in step S3. Here, in the force control described later, when the user is not seated on the massage machine 1, there is no target against which the treatment element 8 comes into contact, so the pressing force F remains zero and the treatment element does not rise. 8 will move forward to that limit, resulting in the problem of an unusual appearance. However, in this control program, since position control is performed at the start of control as described above, such a problem does not occur even if the user is not seated.
[0031]
Next, the user grasps the operation member 201 without applying force (so as not to deform), and the treatment element 8 and the backrest part 2 so that the pressing force F of the treatment element 8 becomes equal to or higher than the lower limit value Fmin. Suppose you drowned.
[0032]
Then, in step S3, since the pressing force F becomes equal to or greater than the lower limit value Fmin, the control device 20 proceeds to step S8 and acquires the position P input from the position sensor 21. Next, the position P is compared with the upper limit value Pmax (step S9). Then, since the operation member 201 is not gripped and thus the position P is 0 mm, the control device 20 proceeds to step S10 and acquires the pressing force F detected by the pressure sensor 31. Next, the instruction value I input from the input device 12 is acquired (step S11). Next, the position of the treatment element 8 is feedback-controlled toward the instruction value I using the pressing force F that is an output value. At this time, first, variable conversion is performed (step S12). This is because the feedback control for the position of the treatment element 8 and the feedback control for the pressing force of the treatment element 8 are performed by a common program as described above. This variable conversion is carried out as follows: one-side dead zone TDZ = one-side dead zone Fd of pressing force F, current value TPF = pressing force F, conversion instruction value I ″ = instruction value I converted to pressing force, instruction value TID = I ″ To do. Here, the instruction value I is converted to I ″ because the instruction value I represents the gripping force with respect to the operation member 201, and this is converted into the pressing force F that is the conversion value of the detection output of the pressure sensor 31. It is to do.
[0033]
Next, feedback control for the position of the treatment element 8 is executed (step S13), and then the process returns to step S8. Thereby, the treatment element 8 presses the user to be treated with a pressing force corresponding to the grip force with respect to the operation member 201. Therefore, the user can adjust the gripping force on the operation member 201 and receive a massage with a desired pressing force. Further, in this control state, even if the back of the user is about to leave the treatment element 8, the air cell 17 is supplied until the pressing force F reaches a value corresponding to the instruction value I, and the treatment element 8 is Since it moves forward, the treatment element 8 sticks to the back of the user and does not leave. Thereby, the user can enjoy a massage close to a manual massage. Hereinafter, the control state for the treatment element 8 is referred to as force control. Then, this force control is continued as long as the position P does not exceed the upper limit value Pmax in step S9.
[0034]
Next, it is assumed that a user who has received a sufficient massage has greatly separated his / her back from the backrest 2 and the treatment element 8. Then, in step S9, since the position P becomes equal to or higher than the upper limit value Pmax, the control device 20 proceeds to step S4. That is, the control device 20 switches to position control. As a result, the treatment element 8 is prevented from sticking to the back of the user and moving forward to the limit, and exhibiting an odd appearance.
[0035]
Next, feedback control for the treatment element 8 will be described. Referring also to FIG. 6, in steps S7 and S13 of FIG. 5, the control device 20 first calculates a deviation HEN by subtracting the current value TPF from the instruction value TID (step S21). Next, the absolute value of the deviation HEN is taken to calculate the absolute deviation AHEN (step S22). Next, the absolute deviation AHEN is compared with the dead zone TDZ (step S23) and processed as follows.
[0036]
If the absolute deviation AHEN is below the dead zone TDZ, the process proceeds to the next step in FIG.
[0037]
If the absolute deviation AHEN is 1 to 2 times the dead zone TDZ, these are controlled so that the aperture A with a small opening is opened and the aperture B with a large opening is closed (step S24). If the absolute deviation AHEN is not less than 2 times and less than 3 times the dead zone TDZ, these are controlled so that the aperture A with a small opening is closed and the aperture B with a large opening is opened (step S25). Further, when the absolute deviation AHEN is three times or more of the dead zone TDZ, these are controlled to open both the apertures A and B (step S26). Next, the sign of the deviation HEN is determined (step S27). If the deviation HEN is negative, the switching valve 19 is controlled to switch to the exhaust mode (step S28), and the deviation HEN is zero or positive. The control valve 19 is controlled to switch to the air supply mode (step S29). Thereafter, the process proceeds to the next step in FIG.
[0038]
Therefore, even if the current value TPF is deviated from the indicated value TID, if the deviation HEN is within the dead zone TDZ, the air cell 17 is not supplied or exhausted, so the position of the treatment element 8 or a slight pressing force is not obtained. The feedback control by the control device 20 is prevented from being performed on the deviation. Further, when the current value TPF is greatly below the instruction value TID, that is, when the deviation HEN is negative and the absolute value is large, the air cell 17 is initially supplied using both the apertures A and B. Accordingly, as the absolute value of the deviation HEN becomes smaller, the air cell 17 is supplied so that the total opening degree of the throttles A and B becomes smaller. On the contrary, when the current value TPF greatly exceeds the instruction value TID, that is, when the deviation HEN is positive and the absolute value is large, the air cell 17 is initially used by using both the apertures A and B. As the absolute value of the deviation HEN decreases, the air cell 17 is exhausted so that the total opening of the throttles A and B decreases. Accordingly, the position or pressure of the treatment element 8 is feedback controlled so as not to overshoot. As a result, the occurrence of hunting is prevented, and the controllability for the treatment element 8 is improved.
[0039]
As described above, in the massage machine 1 according to the present embodiment, the control for the treatment element 8 is automatically switched between the position control and the force control, so that the massage close to the manual massage is performed by the force control. When the user is far away from the backrest 2 or when the user is not seated, the position of the user 8 advances to the limit by automatically switching to position control. And an unusual appearance is prevented.
[0040]
Further, in the massage machine 1 according to the present embodiment, the user performs a massage with a desired pressing force while artificially perceiving the strength of the massage by increasing or decreasing the grip strength with respect to the operation member 201 of the input device 12. Can receive. Further, since the operation member 201 having the grip portion 224 extending along the central axis 301 is fixed to the base body 202 so as to be rotatable around the central axis 301, the massage strength and the treatment element 8 are improved. Two types of massage commands can be input by operating one operation member 201, and the massage strength can be input by elastically deforming the grip portion 224 of the operation member 201 in the radial direction. The height of the treatment element 8 can be easily input while rotating the grip portion 224.
[0041]
In the above embodiment, the operation member 201 of the input device 12 is fixed to the base 202 so as to be rotatable. However, it may be fixed so as not to move on the base 202.
[0042]
In the above embodiment, the rotation of the operation member 201 of the input device 12 is detected by a pair of limit switches to detect whether or not a predetermined amount has been rotated, that is, detected as a digital amount. May be detected as an analog quantity.
[0043]
In the above embodiment, the grip portion 224 of the operation member 201 is formed in a spindle shape, but this may be any shape that extends along a predetermined axis.
[0044]
In the above embodiment, the grip portion 224 is constituted by the container 204 made of a flexible elastic body and the fluid 9 made of air. However, the grip portion 224 only needs to have elasticity as a whole, and the fluid is elastic. If the container has elasticity, the container does not necessarily have elasticity. Conversely, if the container has elasticity, the fluid does not necessarily have elasticity. In addition, the container may be, for example, one whose peripheral wall is formed in a bellows shape in the circumferential direction and thereby elastically deformable in the radial direction.
【The invention's effect】
[0045]
INDUSTRIAL APPLICABILITY The present invention is implemented in the form as described above, and has an effect that it is possible to provide a massage machine using an input device suitable for a massage machine capable of controlling a pressing force on a user.
[Brief description of the drawings]
[0051]
FIG. 1 is a longitudinal sectional view showing a configuration of an input device according to an embodiment of the present invention.
FIG. 2 is a view taken in the direction of arrow A in FIG.
FIG. 3 is a perspective view showing the overall configuration of the massage machine according to the embodiment of the present invention.
4 is a piping and block diagram showing a configuration of a control system of the massage machine of FIG. 3; FIG.
FIG. 5 is a flowchart showing the contents of a control program stored in the control device 20;
6 is a flowchart showing the content of feedback control in the flowchart of FIG. 5. FIG.
[Explanation of symbols]
[0052]
DESCRIPTION OF SYMBOLS 1 Massage machine 2 Backrest part 3 Seat part 4 Armrest part 5 Lifting mechanism 6 Massage drive part 7 Base 7a Screwing part 8 Therapeutic element 9 Ball screw
10 Lifting motor
12 Input device
13 Support member
14 Rotation axis
15 Swing plate
17 Air cell
18 Air pump
19 Switching valve
20 Control unit
21 Position sensor
31 Pressure sensor
201 Operation member
202 substrate
202a Shaft hole
202b, 202c through hole
202d plug
203 prop
204
204a, 204b end
205 Fixed shaft
205a Small diameter part
205b Large diameter part
205c groove
206 Plug body
206a inlet
206b End face
206c Large diameter part
207 balls
208 compression spring
209 Fluid
210 Pressure sensor
211,217,218 Signal line
212 Set screw
213 Return spring
214 Dog
215,216 Limit switch
219 Signal line harness
221 Washer
222 Retaining ring
223 plug
224 grip
301 Central axis E Exhaust control coil M Motor S Air supply control coil

Claims (4)

This is detected by detecting the increase and decrease of the pressure of the fluid due to the elastic deformation of the grip portion and the closed container-shaped grip portion that is filled with the fluid and is elastically deformable at least in the radial direction. An input device having a first pressure sensor for outputting a signal;
A treatment device for giving massage to the user;
An air cell that massages the treatment element by its expansion and contraction;
A second pressure sensor that is disposed in an air pipe for supplying and discharging air for expanding and contracting the air cell to and from the air cell, and that detects a pressing force of the treatment element on a user;
Based on the pressing force detected by the second pressure sensor, the pressing force of the treatment element on the user is passed through the air cell in accordance with a detection signal output from the first pressure sensor of the input device. And a control means for controlling. The input device includes an operation member in which the grip portion is formed in a shape extending along a predetermined axis, and a fixed portion is formed at one end of the grip portion;
A base on which the fixed portion of the operating member is fixed to be rotatable about the predetermined axis;
A rotation amount detecting means for detecting the rotation amount of the operation member and outputting the detection signal;
The massage machine according to claim 1, wherein the control means controls the operation of the treatment element based on a detection signal output from the rotation amount detection means. The massage machine is of the chair type,
The massage machine according to claim 2, wherein the input device further includes a bendable column that supports the base body, and is attached to the armrest of the massage machine by the column.   The massage machine according to any one of claims 1 to 3, wherein a grip portion of the input device is formed in a sealed bag shape made of an elastic body, and the fluid is air.

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