This patent application is a national phase filing under section 371 of PCT/SG2015/000063, filed Feb. 27, 2015, which claims priority to Japanese Patent Application No. 2014-036913, filed Feb. 27, 2014, Japanese Patent Application No. 2014-143214, filed Jul. 11, 2014 and Japanese Patent Application No. 2014-205696, filed Oct. 6, 2014, each of which is incorporated herein by reference in its entirety.
1. Field of the Invention
The present invention generally relates to a massage chair and methods of driving the massage chair. For example, a method of massaging using the massage chair.
2. Description of the Related Art
Massage apparatuses currently available on the market include massage chairs equipped with a massage member capable of applying diverse types of massage actions on a user's body. Typically, the massage apparatuses are designed to simulate massage effect provided by masseurs. According to the needs, a user may select a massage program corresponding to a predetermined combination of movement and pressure actions of the massage member for producing certain desirable relaxing effects. However, the application of the existing programs may not adequately provide satisfactory massage effects on certain regions of the user's body, e.g., shoulders and neck.
Therefore, there is a need for massage apparatuses that can address or improve at least the foregoing issues.
The present application describes a massage chair and methods of driving the massage chair that can dispense effective massage to reduce stress and relieve pain. In one embodiment, the massage chair includes a backrest, and two sets of massage arms assembled with the backrest and spaced apart from each other along a transversal axis of the backrest, each set including a first and a second massage arm that respectively have a first and a second contact member and are movable relative to each other. The method includes positioning the two sets of the massage arms such that at least the first contact members of the first massage arms contact a desired region of a user's body, actuating the two sets of the massage arms to perform a sequence of kneading pulses or a continuous kneading displacement from a wide state to a narrow state, whereby a gripping action is applied on the user's body when the two sets of the massage arms reach the narrow state, and stopping the two sets of the massage arms in the narrow state for a period of time to maintain the gripping action on the user's body.
In another embodiment, a massage chair is described. The massage chair includes a backrest, two sets of massage arms assembled with the backrest and spaced apart from each other along a transversal axis of the backrest, each set including a first and a second massage arm that are movable relative to each other and respectively have a first and a second contact member, and a microcontroller operable to actuate the two sets of the massage arms. The microcontroller is configured to position the two sets of the massage arms such that at least the first contact members of the first massage arms contact with a desired region of a user's body, actuate the first and second massage arms to perform a sequence of kneading pulses or a continuous kneading displacement from a wide state to a narrow state to apply a gripping action on the user's body, and stop the two sets of the massage arms in the narrow state for a period of time to maintain the gripping action on the user's body.
In yet another embodiment, the massage chair includes a backrest, two sets of massage arms assembled with the backrest and spaced apart from each other along a transversal axis of the backrest, and a microcontroller operable to actuate the massage arms. Each set of the massage arms includes a first and a second massage arm that are movable relative to each other and respectively have a first and a second contact member, the two sets of the massage arms further having a wide state in which the two first contact members are transversally spaced apart from each other by a first distance, and a narrow state in which the two first contact members are transversally spaced apart from each other by a second distance smaller than the first distance. The microcontroller is configured to position the two sets of the massage arms such that at least the first contact members of the first massage arms contact a desired region of a user's body, actuate the two sets of the massage arms to perform a continuous kneading displacement from the wide state to the narrow state with a programmable speed for applying a gripping action on the user's body, and stop the two sets of the massage arms in the narrow state for a period of time to maintain the gripping action on the user's body.
In conjunction with
The massage mechanism 120 can include two sets of massage arms 126 and 128, and a driving unit 130 (shown in
The driving unit 130 can include a kneading drive mechanism 140 and a tapping drive mechanism 142 (as shown in
Referring to
The rotary shaft 144 can be disposed through the two massage arms 126 and the two linkages 146. The rotary shaft 144 can be affixed with two cams 154 about which the two massage arms 126 are respectively assembled with the rotary shaft 144. The cams 154 are such that when the rotary shaft 144 is driven in rotation by the kneading motor 150, the two massage arms 126 can respectively swing and wobble or oscillate about the transversal axis Y extending along the rotary shaft 144, which results in a periodic swing motion of the upper contact members 134. In one embodiment, the two cams 154 can be configured to create a phase difference of 180° between the two massage arms 126. When the rotary shaft 144 rotates, the upper contact members 134 of the massage arms 126 can thereby swing toward and away from each other in an alternated manner.
The two linkages 146 are respectively connected with the two massage arms 128 and the rotary shaft 144. More specifically, each linkage 146 can have a first end portion connected with one corresponding massage arm 128 about a pivot connection 156 (better shown in
The two cams 158 can create a phase difference of 180° between the two linkages 146 such that when the rotary shaft 144 rotates, the two linkages 146 can swing toward and away from each other in an alternated manner. Moreover, the cams 154 and 158 are further configured to create a differential rotation between the massage arm 126 and the linkage 146 connected thereto about the transversal axis Y. When the rotary shaft 144 rotates, the linkage 146 can accordingly drive the corresponding massage arm 128 to rotate about the pivot connection 156 to have the lower contact member 136 of the massage arm 128 to move alternately toward and away from the upper contact member 134 of the massage arm 126.
With the aforementioned construction, rotation of the rotary shaft 144 can drive the upper contact members 134 of the massage arms 126 and the lower contact members 136 of the massage arms 128 to alternately swing toward and away from each other in an alternated manner, the upper contact members 134 and the lower contact members 136 moving in phase toward and away from each other. In the meantime, the lower contact members 136 of the massage arms 128 can also respectively move alternately toward and away from the upper contact members 134 of the massage arms 126 along the lengthwise axis Z. The aforementioned motion can produce effective kneading massage actions on a desired region of the user's body.
Referring to
Rotation of the rotary shaft 160 and the cams 162 driven by the tapping motor 168 can cause reciprocated vertical displacement of the crankshafts 164, which in turn drive the massage arms 126 to respectively pivot about the rotary shaft 144 and the upper contact members 134 to move along the front-rear axis X. More specifically, the motion of the left and right massage arms 126 can occur in alternate manner owing to the 180° phase difference between the two cams 162 (e.g., the upper contact member 134 of the left massage arm 126 moves forward while the upper contact member 134 of the right massage arm 126 moves rearward, and vice versa). This operation can produce a tapping action on the user's body.
The output of the kneading motor 150 can further be controlled so as to position the upper contact members 134 of the massage arms 126 relatively closer or farther from each other along the transversal axis Y.
In
The kneading drive mechanism 140 can actuate the massage arms 126 and 128 to perform kneading displacements between the narrow state and the wide state. In addition, the kneading drive mechanism 140 can actuate the massage arms 126 and 128 to perform kneading displacements to any positions between the narrow state and the wide state.
Referring again to
The guide body 174 can be affixed with the frame 166, and can have the shape of a box that has a slot along which the slider 176 can be guided for vertical movement along the lengthwise axis Z. The slider 176 can have a vertical threaded hole through which the feed screw 178 can be engaged. The feed screw 178 can be operatively connected with an electric motor (not shown). A rotation of the feed screw 178 driven by the electric motor can thereby cause up and down movements of the slider 176 in the guide body 174.
When the feed screw 178 rotates in a first direction, the slider 176 can move upward until it abuts against an upper edge of the guide body 174. Once the slider 176 engages with the upper edge of the guide body 174, further rotation of the feed screw 178 in the first direction causes the slider 176 to push the guide body 174, the frame 166 and the tapping motor 168 upward. The upward displacement of the frame 166 and the tapping motor 168 can be transmitted through the crankshafts 164 to the massage arms 126, which cause the massage arms 126 to rotate about the rotary shaft 144 in a direction for concurrently moving the upper contact members 134 forward and retracting the lower contact members 136 backward. This displacement may allow the upper contact members 134 and/or lower contact members 136 to apply pressure on desired regions of the body.
When the feed screw 178 rotates in a second direction opposite to the first direction, the slider 176 can move downward until it abuts against a lower edge (not shown) of the guide body 174. Once the slider 176 engages with the lower edge of the guide body 174, further rotation of the feed screw 178 in the second direction causes the slider 176 to push the guide body 174, the frame 166 and the tapping motor 168 downward. The downward displacement of the frame 166 and the tapping motor 168 can be transmitted through the crankshafts 164 to the massage arms 126, which cause the massage arms 126 to rotate about the rotary shaft 144 in another direction for concurrently moving the lower contact members 136 forward and retracting the upper contact members 134 backward.
Referring again to
The control interface 206 can be connected with sensors and limit switches arranged in the massage apparatus 100, and can deliver various detection signals to the microcontroller 208 to provide information such as physical height of the user, limits of movements, motor revolutions, etc.
The microcontroller 208 can control and supervise the operation of the massage apparatus 100. In one embodiment, the microcontroller 208 can exemplary be a 32-bit Reduced Instruction Set Computing (RISC) microcontroller. The microcontroller 208 can select one of a plurality of massage programs stored internally, and execute the selected massage program through the drivers 204. In one embodiment, the microcontroller 208 can exemplary include a processing unit 210, a memory 212 for storing massage program codes, and input/output (I/O) ports 214 through which the processing unit 210 can exchange signals with the drivers 204 and the control interface 206.
The memory 212 can store the codes of multiple massage programs 220 available in the massage apparatus 100. Each of the massage programs 220 can be executable by the processing unit 210 of the microcontroller 208 so as to actuate the massage arms 126 and 128 to perform a sequence of predetermined massage actions on a user's body. All the displacements of the massage arms 126 and 128 can be conducted in a spatial coordinate system defined by the lengthwise axis Z, the transversal axis Y and the front-rear axis X.
In conjunction with
In next step 304, the kneading drive mechanism 140 can actuate the two sets of the massage arms 126 and 128 to place the upper contact members 134 in the wide state as shown in
In next step 306, while the massage arms 126 and 128 are in the wide state, the kneading drive mechanism 140 then can actuate the massage arms 126 and 128 to perform a sequence of kneading pulses or a continuous kneading displacement from the wide state to the narrow state.
In case kneading pulses are applied in step 306, each kneading pulse can be accomplished by a limited rotational movement of the rotary shaft 144, which can result in a limited kneading displacement of the two massage arms 126 and 128. Moreover, the contact members 134 and 136 in each set of the massage arms 126 and 128 can gradually move toward each other at each kneading pulse.
Each of the kneading pulses as described above has a pulse duration, and two successive kneading pulses are timely separated by a hold interval during which the massage arms 126 and 128 remain stationary, the pulse duration being shorter than the hold interval. In one embodiment, the pulse duration may be constant throughout the sequence of the kneading pulses. Moreover, each kneading pulse can have a pulse duration less than 1 second. For example, the pulse duration can be about 0.2 seconds, and the hold interval can be about 0.4 seconds. These time intervals may vary, e.g., the pulse duration and the hold interval may be longer, such as 0.3 seconds and 0.5 seconds, 0.4 seconds and 0.6 seconds, etc. The massage arms 126 and 128 can perform the aforementioned kneading pulses until the narrow state (e.g., as shown in
In case a continuous kneading action is applied in step 306, the rotary shaft 144 may continuously rotate to cause a continuous kneading displacement of the massage arms 126 and 128 from the wide state to the narrow state (i.e., without stop between the wide and narrow state). Like previously described, the contact members 134 and 136 in each set of the massage arms 126 and 128 can move toward each other during this continuous kneading displacement so that a massage gripping action can be applied on the user' body along both the transversal axis Y and the lengthwise axis Z.
The aforementioned pulse or continuous kneading movement from the wide state to the narrow state can result in a massage gripping or pinching action that is applied on the user' body along both the transversal axis Y and the lengthwise axis Z. A maximum gripping effect can be provided when the two sets of the massage arms 126 and 128 reach the narrow state.
As shown in
In next step 308, once the narrow state is reached (e.g., corresponding to the position P5 shown in
In next step 310, once the hold period of time elapses, the kneading drive mechanism 140 then can drive the massage arms 126 and 128 to move from the narrow state to the wide state for releasing the massage gripping action. This releasing displacement can result in the contact members 134 and 136 in each set of the massage arms 126 and 128 moving away from each other. In one embodiment, the massage arms 126 and 128 can perform a plurality of kneading pulses from the narrow state to the wide state to release the massage grip action. These kneading pulses can be imparted by rotational displacements of the rotary shaft 144 in either direction. For example, the rotary shaft 144 may rotate in a first direction to apply the kneading pulses in step 306, and in a second direction opposite to the first direction to release the massage grip action in step 310 (i.e., the upper contact member 134 moves along the same path portion (i.e., either of the upper and lower path portion U and L) from the wide to narrow state and reversely. Alternatively, the rotary shaft 144 may rotate in the same direction to apply the kneading pulses in step 306 and release the massage grip action in step 310 (i.e., each of the upper contact member 134 can move along one of the upper and lower path portion U and L from the wide to narrow state, and then along the other one of the upper and lower path portion U and L from the narrow to wide state). The kneading pulses for releasing the massage grip action may be similar or different from the kneading pulses performed in step 306, i.e., with similar or different pulse duration and/or hold interval.
The sequence of massage actions in steps 302 through 310 can be completed in a relatively short time, e.g., less than 60 seconds, or even less than 20 seconds.
In conjunction with
In next step 404, the kneading drive mechanism 140 can actuate the two sets of the massage arms 126 and 128 to place the upper contact members 134 in the wide state as shown in
In next step 406, while the massage arms 126 and 128 are in the wide state, the kneading drive mechanism 140 can actuate the massage arms 126 and 128 to perform a continuous kneading displacement from the wide state to the narrow state with a programmable speed. The rotational speed of the rotary shaft 144 may be selected among a range of low to high speed values to desirably set the speed at which the massage arms 126 and 128 move from the wide state toward the narrow state. Like previously described, the contact members 134 and 136 in each set of the massage arms 126 and 128 can continuously move toward each other along the lengthwise axis Z during the kneading displacement from the wide state to the narrow state. This can create in a massage gripping action on the user' body.
As shown in
In next step 408, once the narrow state is reached, the two sets of the massage arms 126 and 128 are stopped for a period of time to hold the gripping action. This hold period of time may be a few seconds, e.g., 1, 2 or 3 seconds.
In next step 410, once the hold period of time elapses, the kneading drive mechanism 140 can drive the massage arms 126 and 128 to move from the narrow state back to the wide state for releasing the massage gripping action. During this release displacement, the contact members 134 and 136 in each set of the massage arms 126 and 128 can move away from each other. In one embodiment, the massage arms 126 and 128 can perform a continuous kneading displacement from the narrow state to the wide state to release the massage gripping action. For example, the rotary shaft 144 can rotate continuously in a first direction from the wide state to the narrow state to apply the massage gripping action, and then rotate continuously in an opposite second direction from the narrow state to the wide state to release the massage grip action. In another embodiment, the massage arms 126 and 128 may also perform a plurality of kneading pulses from the narrow state to the wide state to release the massage grip action as described previously.
Advantages of the systems and methods described herein include the ability to apply massage grip actions that can effectively relieve stress and pain for different regions of the body, such as a shoulder area. As a result, a user can enjoy enhanced massage experience and obtain effective relief of muscular tension and pain.
Realizations of the systems and methods have been described only in the context of particular embodiments. These embodiments are meant to be illustrative and not limiting. Many variations, modifications, additions, and improvements are possible. Accordingly, plural instances may be provided for components described herein as a single instance. Structures and functionality presented as discrete components in the exemplary configurations may be implemented as a combined structure or component. These and other variations, modifications, additions, and improvements may fall within the scope of the inventions as defined in the claims that follow.
Number | Date | Country | Kind |
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2014-036913 | Feb 2014 | JP | national |
2014-143214 | Jul 2014 | JP | national |
2014-205696 | Oct 2014 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/SG2015/000063 | 2/27/2015 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2015/130232 | 9/3/2015 | WO | A |
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