JP2013106834A - Massage machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a massage machine easily conducting heat to a neck part of a user.SOLUTION: When a contacting part of a neck part heating part composed of a wire net is pressed on the neck part, the contacting part is deformed in accordance with a shape of the neck part and adjusts the pressure applied to the neck part. An area where the neck part and the contacting part contact with each other becomes larger by the deformation of the contacting part in accordance with the shape of the neck part.

Description

  The present invention relates to a massage machine in which a massage mechanism and a heat source are incorporated in a backrest portion.

  Traditionally, a chair-type massage machine that incorporates a massage mechanism with kneading balls on the backrest applies a kneading ball to the acupuncture points and meridians on the back to perform predetermined movements and promotes blood circulation, thereby stiffening the shoulders and back. It has been proposed in the past. Such massage machines are widely used in ordinary homes and public facilities.

  Further, in recent massage machines, a heat treatment has been developed by providing a heat source in a massage mechanism to perform thermotherapy in addition to massage by pressing the kneading balls (for example, Patent Document 1).

JP 2011-62448 A

  By the way, the neck (neck) is a site where nerves and blood vessels essential for life support are concentrated, and it is hard to press compared to the back, waist and shoulder. Therefore, in the massage machine of patent document 1, it becomes difficult to press the 2nd heat-transfer part mainly for the heat transfer to a neck part to a treatment part (neck part). For this reason, the second heat transfer section is less likely to transfer heat to the treatment section compared to the first heat transfer section whose main purpose is heat transfer to the back, waist and shoulders. There was a possibility that it could not be warmed.

  The present invention has been made paying attention to such problems existing in the prior art. The purpose is to provide a massage machine that easily transfers heat to the neck of the user.

  In order to achieve the above object, a massage machine according to the present invention has a seat part on which a user can sit and a backrest part provided at the rear part of the seat part, and a massager is provided with a treatment element in the backrest part. In the massaging machine which provides a mechanism and massages the user's body by the massage mechanism, the treatment element can transmit heat from the kneading balls that press the user's body, a heat source, and the heat source to the human body. One or a plurality of heat transfer means different from the kneading balls are provided, and at least one heat transfer means of the heat transfer means is configured to protrude to the neck side from the kneading balls, and the heat transfer means is provided on the neck. It has the function of adjusting the applied pressure.

In the massage machine of the present invention, it is preferable that the heat transfer means is a member having high thermal conductivity and has an elastic force in a direction facing the neck.
Moreover, the massage machine of this invention WHEREIN: It is preferable that the said treatment element is provided with the said heat transfer means through the elastic member which has an elastic force in the direction which opposes a neck part.

Moreover, the massage machine of this invention WHEREIN: It is preferable to form the contact surface which contacts the neck part of the said heat transfer means longer in the vertical direction than the length in a horizontal direction.
Further, in the massage machine of the present invention, a massage mechanism having a seat part on which a user can be seated and a backrest part provided at the rear part of the seat part, and having a treatment element in the backrest part, is provided. In the massage machine that massages the user's body by a mechanism, the treatment element is different from the kneading balls that press the user's body, the heat source, and the kneading balls that can transfer heat from the heat source to the human body. One or more heat transfer means are provided, and at least one of the heat transfer means is configured to protrude to the neck side from the kneading balls, and the contact surface that contacts the neck in the heat transfer means It is preferable that the length in the vertical direction is longer than the length in the horizontal direction.

  In order to achieve the above object, a seating unit on which a user can be seated and a backrest part provided at the rear part of the seating part are provided, and a massage mechanism including a treatment element is provided on the backrest part. In the massage machine that massages the user's body by a massage mechanism, the treatment element is a kneading ball that presses the user's body, a heat source, and the kneading ball that can transfer heat from the heat source to the human body. One or more different heat transfer means are provided, and when the contact surface that contacts the neck of the heat transfer means is brought into contact with the neck, the contact surface is widened so that the contact surface and the neck are in contact with each other. It is preferable to provide an adjustment mechanism that adjusts the angle at which the lens faces.

  According to the present invention, heat can be easily transferred to the neck of the user.

The perspective view which shows the external appearance of a massage machine. Sectional drawing of one treatment element among a pair of treatment elements. The schematic diagram which shows the aspect at the time of making the cervical part press the contact part of the neck thermal part of the treatment element in 1st Embodiment. Sectional drawing of one treatment element among a pair of treatment elements in 2nd Embodiment. The schematic diagram which shows the aspect at the time of making the neck contact | press the contact part of the neck thermal part of the treatment element in 2nd Embodiment. Sectional drawing of one treatment element among a pair of treatment elements in 3rd Embodiment. The schematic diagram which shows the aspect at the time of pressing the contact part of the neck heating part of the treatment element in 3rd Embodiment on the neck. (A) And (b) is sectional drawing of one treatment element among a pair of treatment elements in 4th Embodiment. The schematic diagram which shows the aspect at the time of pressing the contact part of the neck thermal part of the treatment element in 4th Embodiment on the neck.

(First embodiment)
Hereinafter, a first embodiment of the present invention will be described with reference to FIGS.
FIG. 1 shows a schematic configuration of a massage machine 10 according to the present embodiment.

  In the following description, regarding the massage machine 10, in the front view and the width direction X of the massage machine 10, the direction from the center side to the outside is referred to as “outward direction X1”, and the direction from the outside to the center side is “inward direction X2”. As shown. Further, in the front view and the height direction Y of the backrest 13, the direction from the lower side to the upper side is referred to as "upward direction Y1," and the direction from the upper side to the lower side is referred to as "downward direction Y2."

  As shown in FIG. 1, the leg portion 11 of the massage machine 10 is placed on a floor surface (not shown), and a seat portion 12 on which a user can sit is fixed to the upper portion of the leg portion 11. A backrest 13 for allowing the user to lean back is provided at the rear of the seat 12 so that the user can lean on the back, and an ottoman 14 on which the user's legs can be placed on the front of the seat 12. It can be tilted. An armrest 15 for placing the user's arm is provided from the backrest 13 to the front of both sides of the seat 12.

  The backrest part 13 is comprised by the backrest part main body 13a and the cover part 13b which covers the front surface of this backrest part main body 13a. The backrest main body 13a is provided with a guide rail (not shown) along the vertical direction of the backrest 13 in a main body case (not shown) made of a hard resin material having an open front surface, and moves up and down along the guide rail. The massage mechanism 20 is assembled as possible.

Hereinafter, the structure of the massage mechanism 20 is demonstrated based on FIG.
The massage mechanism 20 includes a massaging ball 21 for massaging the body, a back heating unit 22 as a heat transfer means for applying temperature stimulation mainly to the shoulder, back and waist of the body, and temperature stimulation for the neck mainly of the body. And a cervical heating part 23 as a heat transfer means for applying heat. Further, the massage mechanism 20 supports the massaging balls 21, the back heating part 22 and the neck heating part 23, and is connected to the guide rail and the position of the massage mechanism 20 along the guide rail in the height direction Y. And a drive motor (not shown).

  A back heating part 22 is fixed to the arm 24. In addition, a columnar support portion 25 that supports the kneading balls 21 is formed in the back portion heating portion 22 so as to protrude in the inward direction X2. In addition, a heater 30 serving as a heat source is provided inside the back heating unit 22. In addition, as a material of the back | dorsal part heating part 22, aluminum which is a heat conductive (heat conductivity) and a highly rigid raw material is used.

  Further, the kneading balls 21 are supported on the back portion heating unit 22 in a state of being rotatable with respect to the back portion heating unit 22. Specifically, the kneading balls 21 have a first bearing 32 and a second bearing 33 that support rotation with respect to the back portion heating portion 22. Further, the kneading balls 21, the first bearing 32, and the second bearing 33 are formed with holes 21a, 32a, 33a to be inserted into the support portion 25.

  In addition, a cervical heating part 23 is fixed to the tip of the support part 25 of the back heating part 22. Further, the neck portion heating portion 23 is formed with a cylindrical protrusion 23a protruding in the outward direction X1. Further, a hole 23b to be inserted into the support portion 25 is formed in the protruding portion 23a.

Hereinafter, the structure of the 1st bearing 32 inserted in the support part 25, the kneading ball 21, the 2nd bearing 33, and the neck part heating part 23 is demonstrated concretely.
First, the first bearing 32 (the hole 32 a) is inserted into the support portion 25 of the back heating portion 22. The diameter of the hole 32 a of the first bearing 32 is the same as the outer diameter of the support portion 25. Further, the first bearing 32 has a groove 32b that is formed such that an end in the outer direction X1 protrudes in the outer diameter direction, and the bottom forms a right angle. As a material for the first bearing 32, a synthetic resin having low thermal conductivity is used.

  Further, after the first bearing 32, the kneading balls 21 (the holes 21a) are inserted into the support portion 25, and then the second bearings 33 (the holes 33a) are inserted. The diameter of the hole 33 a of the second bearing 33 is the same as the outer diameter of the protruding portion 23 a of the neck heating portion 23. Further, the second bearing 33 has a groove 33b that is formed such that an end portion in the inner direction X2 protrudes in the outer diameter direction, and the bottom forms a right angle.

  And when the 1st bearing 32 and the 2nd bearing 33 are inserted in the support part 25, the recessed part is formed in the outer-diameter direction of each bearing 32 and 33 by the groove | channel 32b and the groove | channel 33b. The kneading balls 21 are sandwiched between the recesses. For this reason, the diameter of the hole 21a of the kneading ball 21 is the same as the outer diameter of the bottom portion of the recess formed by the groove 32b and the groove 33b. The second bearing 33 is made of a synthetic resin having low thermal conductivity, and the kneading balls 21 are made of a rubber material.

  The support portion 25 is positioned next to the kneading balls 21 in the inner direction X2 (neck side) next to the second bearing 33, and protrudes in the inward direction X2 from the kneading balls 21. (Hole 23b) is inserted. Since the diameter of the hole 23 b of the neck heating part 23 is the same as the outer diameter of the support part 25, the inner peripheral surface of the hole 23 b and the outer peripheral surface of the support part 25 come into contact with each other. In addition, by fixing the neck heating portion 23 to the support portion 25, the first bearing 32, the kneading balls 21 and the second bearing 33 inserted into the support portion 25 are prevented from being detached from the support portion 25. Yes.

  In addition, the cervical heating part 23 is a part of the cervical heating part 23 that comes into contact with the cervical part of the human body, and has a contact part 23c having an elastic force in a direction opposite to the cervical part. The contact portion 23c is formed by forming a wire mesh in which a wire is woven into a plain weave shape into a hemispherical shape. And the contact part 23c comprised by hemispherical shape is provided in the neck heating part 23 so that the spherical surface may protrude in the inward direction X2 (neck part side). In addition, as a material of the neck heating part 23 and the contact part 23c, aluminum which is a material having high thermal conductivity is used. Thus, when the heater 30 generates heat, the heat is transferred from the support portion 25 of the back portion heating portion 22 to the protruding portion 23a of the neck portion heating portion 23 that contacts the support portion 25. And the heat transmitted to the protrusion part 23a will be transmitted to the contact part 23c.

Hereinafter, the operation in the present embodiment will be described.
The aspect at the time of giving temperature stimulation with respect to a neck by making the neck heating part 23 (the contact part 23c) in this embodiment contact the neck of a human body is demonstrated based on FIG.

  When the contact part 23c of the neck heating part 23 is brought into contact with the neck of the human body, the contact part 23c is deformed into a shape along the shape of the neck by the contacted pressure. Moreover, since the shape of the contact part 23c deform | transforms into the shape along the shape of a neck part, the area which a neck part and the contact part 23c contact becomes large. Moreover, the contact part 23c closely_contact | adheres to the neck surface by the elastic force which the contact part 23c has.

According to this embodiment, the following effects can be achieved.
(1) Since the contact part 23c of the neck heating part 23 is configured to have an elastic force in a direction facing the neck, even if the contact part 23c is brought into contact with the neck by a certain pressure, the contact part 23c Deformed so that the pressure applied to the neck can be adjusted. For this reason, the cervical thermal part 23 has a function of adjusting the pressure applied to the cervical part, and by the function, the cervical thermal part 23 (the contact part 23c) can be pressed to the cervical part reasonably, It becomes easier to transfer heat to the neck.

  (2) Since the shape of the contact portion 23c is deformed along the shape of the neck when the contact portion 23c of the neck heating portion 23 is pressed against the neck, the area where the neck and the contact portion 23c come into contact with each other. Becomes larger and it becomes easier to transfer heat to the neck. Further, even if the contact portion 23c is pressed against the neck, the shape of the contact portion 23c is deformed, so that excessive pressure is not applied to the neck.

(3) Since the neck heating part 23 including the contact part 23c is made of aluminum which is a member having high thermal conductivity (thermal conductivity), heat from the heater 30 is easily transmitted to the neck.
(Second Embodiment)
A second embodiment of the present invention will be described with reference to FIGS. 4 and 5. In addition, about the structure similar to 1st Embodiment, the same code | symbol is attached | subjected and the description is abbreviate | omitted or simplified.

  In the present embodiment, unlike the first embodiment, the position of the cervical heating part 23 moves in the width direction X. Specifically, as shown in FIG. 4, a spiral spring 40 is interposed between the neck heating portion 23 and the back heating portion 22 so as to have an elastic force in the width direction X. A spring 40 is inserted into the support portion 25. Further, one end of the spring 40 is press-contacted to the back heating part 22, and the other end is pressed to the tip of the protruding part 23 a of the neck heating part 23. Moreover, the neck heating part 23 is prevented from coming off so as not to be detached from the support part 25. For this reason, the neck heating part 23, the spring 40, the first bearing 32, the kneading balls 21, and the second bearing 33 are prevented from being detached from the support part 25. As a material of the spring 40, aluminum which is a material having high thermal conductivity is used.

  In the present embodiment, the diameter of the hole 32 a of the first bearing 32 is set to be longer than the diameter of the spring 40. In addition, grease (lubricant) having high thermal conductivity is applied to the outer peripheral surface of the support portion 25 and the inner peripheral surface of the hole 23b in contact with the outer peripheral surface in the present embodiment.

  Moreover, the contact part 23c used as the part which contacts the neck part among the neck thermal parts 23 in this embodiment is comprised with the member formed by curving the metal surface. In addition, as a material of the neck heating part 23 and the contact part 23c, the aluminum used as a raw material with high heat conductivity is used like 1st Embodiment.

Hereinafter, the operation in the present embodiment will be described.
A mode of applying temperature stimulation to the neck by bringing the neck heating part 23 (the contact part 23c) in the present embodiment into contact with the neck of the human body will be described with reference to FIG.

  If the contact portion 23c of the neck warming portion 23 is brought into contact with the neck of the human body from the point where the contact portion 23c is further brought into close contact with the neck, the length of the spring 40 in the width direction X is shortened, and the neck warming temperature is reduced. The position of the part 23 moves in a direction (outward direction X1) facing the neck.

According to this embodiment, in addition to the effect (3) described in the first embodiment, the following effects can be achieved.
(4) Even if the neck heating part 23 is pressed against the neck with a certain amount of pressure, the spring 40 (elastic member) can be deformed (stretched) to reduce the pressure applied to the neck. At the same time, since the spring 40 is provided so that the elastic force of the spring 40 acts in the direction opposite to the neck, the neck warming portion 23 (the contact portion 23c thereof) can be brought into close contact with the neck by the elastic force of the spring 40. it can. This makes it easier to transfer heat to the neck.

(Third embodiment)
A third embodiment of the present invention will be described with reference to FIGS. In addition, about the structure similar to 1st Embodiment, the same code | symbol is attached | subjected and the description is abbreviate | omitted or simplified.

  As shown in FIG. 6A, the contact portion 23c, which is a portion that contacts the cervical portion of the cervical thermal portion 23 that becomes the contact surface in the present embodiment, is arranged in a horizontal direction as viewed from the cervical portion. The length in the vertical direction is made longer than the length of and formed. Further, as shown in FIG. 6B, the contact portion 23c is curved and shaped so as to conform to the shape of the neck surface calculated below from the data of the shapes of the plurality of neck surfaces. In addition, as a material of the neck heating part 23 and the contact part 23c, the aluminum used as a raw material with high heat conductivity is used like 1st Embodiment.

Hereinafter, the operation in the present embodiment will be described.
The aspect at the time of giving temperature stimulation with respect to a neck by making the neck heating part 23 (the contact part 23c) in this embodiment contact the neck of a human body is demonstrated based on FIG.

  When the contact part 23c of the cervical heating part 23 is brought into contact with the cervical part of the human body, the contact part 23c is in close contact with the cervical surface of the human body because it forms along the shape of the cervical surface. As such, the contact portion 23c contacts the neck of the human body.

According to this embodiment, in addition to the effect (3) described in the first embodiment, the following effects can be achieved.
(5) Generally, the surface of the neck of a human body is curved in the horizontal direction, but has a flat shape in the vertical direction. Further, the vertical shape (flat shape) of the surface of the neck of the human body has a smaller individual difference than the horizontal shape (curved shape). For this reason, the shape of the contact portion 23c is set to be longer in the vertical direction than in the horizontal direction. For this reason, whatever area the user uses, the area where the contact portion 23c comes into contact with the neck can be increased, and heat can be easily transferred to the neck. Moreover, even if the pressure which makes the contact part 23c of the neck heating part 23 contact a neck is weak, it becomes easy to transmit heat from the contact part 23c to a neck.

(Fourth embodiment)
A fourth embodiment of the present invention will be described with reference to FIGS. In addition, about the structure similar to 1st Embodiment, the same code | symbol is attached | subjected and the description is abbreviate | omitted or simplified.

  The contact part 23c which becomes a part (contact surface) which contacts a neck part among the neck thermal parts 23 in this embodiment is comprised with the member formed by curving the metal surface. In addition, as a material of the neck heating part 23 and the contact part 23c, the aluminum used as a raw material with high heat conductivity is used like 1st Embodiment.

  In the present embodiment, as shown in FIG. 8A, the first bearing 32 and the second bearing 33 are not inserted into the support portion 25. In this embodiment, a bearing 132 is inserted into the support portion 25 instead of the first bearing 32. The bearing 132 is formed with a hole 132 a for insertion into the support portion 25 and covers the entire outer peripheral surface of the support portion 25. Furthermore, the bearing 132 has a groove 132b that is formed such that an end in the outer direction X1 protrudes in the outer diameter direction, and a bottom is a right angle. Further, after the hole 132a of the bearing 132 is inserted into the support portion 25 so that the bearing 132 is not detached from the support portion 25, the bearing 132 is fixed to the back portion heating portion 22. Further, the kneading balls 21 are fixed to the bearings 132 after the holes 21 a of the kneading balls 21 are inserted into the support portions 25 so that the kneading balls 21 are not detached from the bearings 132.

  Further, the neck heating portion 23 of the present embodiment is formed such that a protruding shaft 123a protrudes in the outward direction X1 instead of the protruding portion 23a. Further, the distal end of the protruding shaft 123 a of the neck heating portion 23 is attached to the distal end of the support portion 25 so as to be rotatable in the height direction Y around the distal end of the support portion 25.

  In addition, a spring 51 is provided on the upper portion of the neck heating portion 23 (portion located in the upward direction Y1 from the protruding portion 23a) so as to have an elastic force in the width direction X. One end of both ends of the spring 51 is fixed to the neck heating unit 23, and the other end is fixed to the bearing 132.

  Further, one end of a wire 52 is attached to the lower part of the neck heating part 23 (the part located in the lower direction Y2 from the protruding part 23a). Further, holes 132c, 22a, 30a, and 24a through which the wire 52 is passed are formed in the bearing 132, the back portion heating portion 22, the heater 30, and the arm 24. One end of the wire 52 that is not attached to the neck heating part 23 is attached to a driving device (not shown) through the holes 132c, 22a, 30a, and 24a.

  When the contact part 23c of the neck heating part 23 is brought into contact with the neck and the heat is transmitted to the neck, the driving device is moved so that the tension in the outward direction X1 is applied to the wire 52. . At this time, the driving device adjusts the tension applied to the wire 52 so as to adjust the angle at which the contact portion 23c is directed so that the contact area 23c of the neck heating portion 23 contacts the neck. It has become. In addition, the area where the contact part 23c of the neck heating part 23 contacts with the neck is the widest when the surface of the contact part 23c and the surface of the contacting neck are in a parallel relationship. In the present embodiment, the wire 52 and the driving device for adjusting the angle at which the contact portion 23c of the cervical heating portion 23 faces function as an adjusting mechanism.

Hereinafter, the operation in the present embodiment will be described.
First, modes of the neck heating unit 23 when the wire 52 is tensioned and when tension is not applied will be described with reference to FIG.

When no tension is applied to the wire 52, the neck heating portion 23 (the contact portion 23c thereof) is positioned at a predetermined position by the spring 51, as shown in FIG.
When a tension is applied to the wire 52, as shown in FIG. 8 (b), the lower part of the neck heating part 23 is pulled in the outward direction X1 and rotated downward Y2 around the tip of the support part 25. Move. At this time, as described above, the tension is applied to the wire 52 so that the contact area 23c of the neck heating portion 23 and the area where the neck contacts is widened.

Next, the aspect at the time of giving temperature stimulation with respect to a neck by making the neck heating part 23 (the contact part 23c) in this embodiment contact the neck of a human body is demonstrated based on FIG.
When the contact portion 23c of the neck heating portion 23 is brought into contact with the neck of the human body, the contact portion 23c has a large area in contact with the neck, that is, the surface of the contact portion 23c and the neck surface are in a parallel relationship. Thus, the angle (direction) at which the contact portion 23c faces is adjusted by applying tension to the wire 52. When the contact portion 23c is brought into contact with the neck of the human body in a state where the angle at which the contact portion 23c faces is adjusted, the area where the contact portion 23c contacts the neck than when the angle at which the contact portion 23c faces is not adjusted. Becomes wider. At the same time, the contact portion 23c of the cervical heating portion 23 can be brought into close contact with the cervical surface, making it easier to transfer heat to the cervical portion.

According to this embodiment, in addition to the effect (3) described in the first embodiment, the following effects can be achieved.
(6) When the contact part 23c of the neck heating part 23 is brought into contact with the neck, the angle at which the contact surface faces is adjusted so that the area where the contact part 23c and the neck contact is widened. As a result, when the contact portion 23c is brought into contact with the neck, the contact area between the contact portion 23c and the neck becomes wide, and heat can be easily transferred to the neck.

  (7) Only when the heat is transmitted to the neck by the contact part 23c of the neck heating part 23, the angle to which the contact part 23c faces is adjusted. You can prevent it from warming up. In addition, when massaging a part other than the neck (for example, the waist), the angle at which the contact portion 23c faces can be adjusted so that the contact portion 23c does not interfere (obstruct).

(Other embodiments)
Note that the embodiments of the present invention are not limited to the above-described embodiments, and can be modified as shown below, for example. The following modifications are not applied only to the above-described embodiments, and different modifications may be combined with each other.

-In above-mentioned 1st Embodiment-4th Embodiment, if it is a raw material with high heat conductivity as a material of the neck heating part 23, it may not be aluminum. Also, it need not be a metal.
-In the said 1st Embodiment, it is not necessary to make the contact part 23c of the neck heating part 23 into the wire mesh by which the wire was knitted in the plain weave form. For example, as long as it is configured to have elasticity in a direction facing the neck (mainly in the width direction X), the wire may be a wire mesh knitted in a twill shape.

  -In the said 1st Embodiment, you may change the shape of the contact part 23c into the shape curved according to the shape of the neck of a human body so that it may describe in 3rd Embodiment. As a result, the contact portion 23c can be brought into contact with the neck more, and the contact area is widened. This further facilitates heat transfer to the neck.

  -In the said 2nd Embodiment, if interposed so that it may have an elastic force in the width direction, it is elastic members other than a spring (for example, rubber | gum etc.) between the neck part heating part 23 and the back part heating part 22. May be used. Further, it is not necessary to insert the elastic member into the support portion 25.

  -In the said 3rd Embodiment, when the shape of the contact part 23c of the neck heating part 23 is longer than the length of a horizontal width when it sees from the width direction X, it follows the shape of a neck. There is no need to bend.

  -In the said 4th Embodiment, when the angle which the contact part 23c faces is changed when massaging a neck part, you may make it adjust the angle by what kind of structure. For example, the angle at which the contact portion 23c faces may be adjusted by driving the motor.

  DESCRIPTION OF SYMBOLS 10 ... Massage machine, 12 ... Seat part, 13 ... Backrest part, 20 ... Massage mechanism, 21 ... Grudge ball, 22 ... Back heating part, 23 ... Neck heating part, 23c ... Contact part, 24 ... Arm, 30 ... Heater 40 ... spring, 51 ... spring, 52 ... wire.

Claims (6)

A seat that can be seated by a user and a backrest provided at the back of the seat, and a massage mechanism including a treatment element is provided in the backrest, and the body of the user is massaged by the massage mechanism In the massage machine
The treatment element includes one or more kneading balls that press the user's body, a heat source, and one or a plurality of heat transfer means different from the kneading balls that can transfer heat from the heat source to the human body,
A massaging machine characterized in that at least one heat transfer means among the heat transfer means is configured to protrude to the neck side from the kneading balls and has a function of adjusting the pressure applied to the neck by the heat transfer means. .   The massage machine according to claim 1, wherein the heat transfer means is a member having a high thermal conductivity and has an elastic force in a direction facing the neck.   The massage machine according to claim 1 or 2, wherein the treatment element includes the heat transfer means via an elastic member having an elastic force in a direction facing the neck.   The massage machine according to any one of claims 1 to 3, wherein a contact surface that contacts the neck of the heat transfer means is formed longer in the vertical direction than in the horizontal direction. A seat that can be seated by a user and a backrest provided at the back of the seat, and a massage mechanism including a treatment element is provided in the backrest, and the body of the user is massaged by the massage mechanism In the massage machine
The treatment element includes one or more kneading balls that press the user's body, a heat source, and one or a plurality of heat transfer means different from the kneading balls that can transfer heat from the heat source to the human body,
At least one heat transfer means of the heat transfer means is configured to protrude to the neck side from the kneading balls, and the contact surface that contacts the neck in the heat transfer means is longer than the length in the lateral direction. A massage machine characterized in that the length of the direction is long. A seating unit on which a user can be seated and a backrest unit provided at the back of the seating unit, and a massage mechanism provided with a treatment element is provided on the backrest unit, and the body of the user is massaged by the massage mechanism In the massage machine
The treatment element includes one or more kneading balls that press the user's body, a heat source, and one or a plurality of heat transfer means different from the kneading balls that can transfer heat from the heat source to the human body,
An adjustment mechanism for adjusting an angle at which the contact surface is directed so that an area of contact between the contact surface and the neck portion is widened when the contact surface that contacts the neck portion of the heat transfer means is brought into contact with the neck portion; A massage machine characterized by that.