This invention relates to a method for using devices and in particular chairs which aim to prevent and or repair human back and spine problems.
Many people have experienced back pain sometime in their lives. The causes of back pain are numerous. Some back pain is due to accidents, muscle strains, and sports injuries. But nowadays the most common cause is bad sitting habit. Sitting too long at a bad posture, for example, often happens with a computer operator or taxi driver in their daily activity. With correct posture such as standing or lying down, the spine is straight, and the internal pressure is equalized on all parts of the spine and muscles. On the other hand, with sitting with bad posture for several hours, the spine's internal pressure can rise up 5 times higher than that of lying down position. Such persisting pressure can lead to stiff muscles, limited circulation, and long term spine and bone damage.
A normal chair consists of three major components: The leg portion extended from the ground to a suitable height will provide support for the whole structure; The seat portion provides a comfortable flat surface to uphold the human body; The backrest portion provides another flat surface for the human torso to lean on. This basic structure has remained the same from ancient times. Alternatively, a chair without backrest is considered a stool, and a chair with an extra arm rest is called an armchair. Unfortunately, this basic structure gives little relief to back problems. As studies have shown, at an average sitting posture, the pressure on the lower back is 40 to 90 percent higher than that of standing posture, and several times higher than that of lying down posture. In some special cases, such as the person leaning notably forward to stare at the computer screen, the weight of his upper torso will be un-evenly distributed across his spine. Such awful posture increases the tension on his muscle, nerve and bone tissue, and speeds up the aging process. Over several years of exposure to excess pressure, a mid-aged person often experiences back pain, simply by sitting on the average chair for too long. Besides back problems, long sitting often causes other heath related issues, such as edema of lower legs, varicose veins, hemorrhoids, cold feet, and many other venous problems that can be attributed to sitting habits to a certain degree.
The most common type of advice that doctors give to patients with back problems is to refrain from the prolonged sitting posture in daily life. For example, some treatments include climbing a few stairs after half hour of desk work or walking around the building several times each day. All these will help to exercise the muscle around the back, increase blood flow and prevent fatigue, edema and various venous/muscle problems. Also, during walking, the pressure from the upper torso is evenly distributed on the spinal disc, as opposed to concentrated on a single spot during certain sitting positions. Hence the reduced pressure is less likely to cause damage to the disc. However, as an occupational hazard, several careers demand sitting for long period in work. For example, taxi drivers, truck drivers, or air traffic controllers all needs to sit for several hours in their daily work. In many other cases, the person working at a desk tends to forget advice from the doctors, and stay for hours before getting out of the chair. In U.S. Pat. No. 5,113,176, the author presents a lumbar roll device that can alert the user for poor posture or for sitting too long, and can remind the user for the need to exercise. Besides self performed exercises, a few other inventions proposed chairs that assist the user in exercising their lower back. These can typically be classified as ‘exercising chairs’. In U.S. Pat. No. 5,110,121, a chair that can exercise muscle on lower back based on spring resistance back pad and stationary lumbar support pad is introduced. In U.S. Pat. No. 7,377,889 B2, a general use chair that can provide a dynamic thrust motion to exercise the user's spine is proposed. U.S. Pat. Nos. 5,730,688 and 6,312,366, described abdominal-lumbar exercise devices that use flexible upright resilient members so that the user can exercise by pivoting against the resilience. U.S. Pat. No. 6,655,731 presents an orthopedic chair that includes a frame for supporting a contoured chair seat and back that rotate on a horizontal axis. This chair holds the person in a beneficial position for back support.
All the inventions mentioned above aim to exercise the muscle of the lower back, or alternatively, remind the user to quit sitting and engage in more exercise. However, if the user has already suffered a certain type of back spinal problem such as herniated disc, bulging disc, or is confined to the chair due to occupational requirements, the existing inventions provide little to help the situation. In this invention, we propose the method of using a new chair structure that can partially or completely lift the torso of the user from the chair, and hence reducing the weight asserted on the lumbar section of the spine. In this manner, we provide the relief on the spinal disc, and hence preventing any damage on it. The relief of pressure happens whenever the user sits in the chair, and does not require the user to engage in any voluntary exercise activity.
This invention provides a new method of using the general chair. This chair has the capability to detect the weight on the seat portion of the chair. Based on the sensor input (high pressure for certain period of time), the chair will lift up the upper torso of the user, hence reducing the pressure asserted on his spine. The reduction of the pressure helps to prevent and alleviate the damage inflicted from long term sitting. This chair carries the components of a traditional chair. In addition, there is a series of lifting harnesses attached to the back support member of the chair. These harnesses attach the user's upper body to the back support. The back support member of the chair is designed to be able to perform an upward and downward movement, hence lifting the upper body up and down. The lifting action can be activated manually, or on a pre-set timer. Alternatively, a weight sensor installed on the seat member of the chair can provide a real time analysis of the posture of the user. Based on the weight level and duration, the back support can be programmed to lift up automatically or periodically, hence reducing the pressure on the sitter's spine.
In this disclosure, the concept of chair includes any sitting device that can be used in daily life. This chair can be made of wood, metal, plastic or any other material or combination of materials. The various components of the chair can be adjusted to a number of different configurations within the scope of this invention. For instance, the seat and leg portions of the chair can be adaptable to various size, shape, or operation, including standard four leg chairs, office chairs with one cylinder base with wheels on the bottom, or one piece chair in automobiles. The described chair can be used in many locations or scenarios, such as family rooms, dinning rooms, offices, buses, airplanes, or fitness centers.
The primary objective of this invention is to provide a method for adjusting posture which provides a means to lift the upper torso of the sitter, thus the pressure asserted on his lumbar spine is reduced. The reduced pressure will encourage blood circulation, relax the muscle and nerves, and prevent damage to the spinal disc, joint, and surrounding tissues. The sitter can still enjoy free movement and operation as in the conventional chair, and his health and comfort are improved.
It is also an important objective of the present invention to provide a method for adjusting the posture of a sitter that utilizes lifting motion to reduce and prevent problems associated with a long duration of sitting in a chair, such as fatigue, pain, numbness, and other discomforts.
It is also an important objective of this invention to provide a method for monitoring an occupant of a chair that has a variety of sensors installed on the seat member of the chair that can detect the posture and weight distribution of the user's sitting time. These sensors will help activate the lifting operation of the back support unit.
The above and other objectives of the present invention will be explained in greater detail in attached figures and descriptions which follows. As set forth herein, the present invention resides in the novel features of form, construction, mode of operation, and combination of these processes.
Elements in the figures have not necessarily been drawn to scale in order to enhance their clarity and improve understanding of these various elements and embodiments depicting the method of the invention. Furthermore, elements that are known to be common and well understood to those in the industry are not depicted in order to provide a clear view of the various embodiments, thus the drawings are generalized in form in the interest of clarity and conciseness.
The description and figures are merely demonstration of the preferred embodiments and several examples of the implementation of the present invention. It should be known that variations on specific components, materials, shapes, configurations, and usage can be made without changing the scope and function of present invention.
The present invention has several different implementations. The first implementation is specified as Embodiment A and it is depicted in
It should be pointed out that even without the weight sensor 50 and extra seat board 12, the flat board 11 is still capable to support the sitter and can still perform the lifting functionality and provide most of the health benefit. However, it is recommended that the weight sensor 50 and extra seat board 12 being adopted for better performance. This is because without this weight sensor, the uplifting power can not be accurately monitored. The force to lift the sitter has to be either manually configured by the user based on his feeling, or set to a fixed value. Neither of these cases will provide optimal health advantage. With the pressure sensors 50, the chair and user can constantly monitor the duration and magnitude of the pressure that has been asserted on the spine of the sitter, hence making corresponding adjustment. In one exemplary implementation, when the user has just sat on the chair, no up-lifting force will be applied, and the weight sensor will detect and calculate the original pressure asserted on the user's spine. After a few minutes, the uplifting mechanism will be activated and lifting the upper torso of the user. As time goes by, the chair will apply more and more lifting force on the user, and hence give the lumbar and spine more and more relief. During the whole time, the weight sensor will be able to detect the pressure change and make sure the correct lifting force is being applied. More importantly, when the sitter changes his sitting pose, and causes the pressure level variation on his spine. The weight sensor will be able to detect this activity and send this information to the control unit in the lifting assembly. The lifting assembly will be able to make adjustment on the lifting force to make sure the pressure level on the spine remains at a constant level for maximum health benefit or user comfort. Overall, the combination of pressure sensor and lifting mechanism will render a closed-loop control system with a real-time feedback link. This design allows much better control and optimization of the system operation, and it can also give certain safety guarantee to prevent too much lifting force.
In practice, chair 10 can be adapted to any type of general use chair, such as power seat in automobiles with no legs but a support base assembly, or a typical office chair with a single supporting base. In this configuration, the same design on weigh sensors 50 and seat board 12 can be adopted, and it is still preferable to have weight sensor 50 deployed between support board 11 and seat board 12, hence it can monitor the pressure change continuously.
In
The weight sensor reading can be distributed to other parts of the chair or the user either through wire line communications such as I2C or UART links, or through wireless links such as WIFI or Bluetooth connections. In addition, the pressure reading can be exhibited on a display panel on the chair, transferred to the user's computer, phone, or other electronic device through wireline/wireless connection, or as an audio/vibration signal to alert un-healthy pressure levels for a certain duration of time. The various kinds of implementations on pressure information all require the implementation of the weight sensor 50 being included as an important part of the present invention.
Directly above leg assembly 17 is the lifting assembly 20. The vertical member 21 extends directly above leg assembly 17. Alternatively, vertical member 21 may also be attached to the side of the bottom of the flat board member 11, or built in place of the leg 17 and extended directly to the ground. Since the lift assembly 20 may sustain a big portion of the sitter's weight as well as its own weight, it is recommended that the vertical member 21 be assembled with solid durable materials such as steel and possess adequate thickness and size. The vertical member 21 can be built into a geared rack structure 24 with toothed bars or rods on its forward facing surface. This rack 24 can be paired with a Pinion structure inside the motor assembly 22. The motor assembly 22 is a box shaped structure that encircles vertical member 21. Inside the motor assembly 22, there should be an electrical motor that drives geared Pinions. The Pinions will run along the toothed surface of rack 24, and hence convert the rotational torque of the electrical motor into vertical linear movement. Once enabled, the motor box 22 will provide a vertical upward/downward motion 70 along the rack track 24. The back support board 23 is a vertical board that is attached to the forward facing surface of motor box 22. So when the motor box 22 starts a vertical linear movement, the back support board 23 can also engage into the same vertical motion. The support board 23 functions similarly as the back support part of a conventional chair. The main difference in this invention is that this back supporting board is capable of engaging in vertical linear motions 70 instead of being a static element.
In
The main purpose of motor box 22 is to provide a vertical motion 70 for the back board 23. In
The rest of blocks, such as controller unit 76 and connection wires 77 remain the same. When the controller unit 76 activates the motion 70, the torque generating units 79 will climb up and down the lead screw 78, and hence lift up the attached motor box 22 and back support board 23 into vertical motions.
The possible power source can be manually steered by the user, or electricity, or hydraulic power, or other types of power supplies, as long as they produce vertical motion 70 for back board 23 and box structure 22. For a few examples, the lifting mechanisms in standard forklifts, elevator systems, or horizontal movement mechanisms in automobile power seats can all be adopted and modified here, as long as they provide a vertical motion 70 for the supporting board 23 and the lifting handle 60 on it.
Directly above seat board 12 is the optional thigh restraint assembly 80, which consists of the belt element 82, attachment fixture element 81, restraint element 85, the male buckle elements 84 and female receptacle buckle elements 83. The fixture elements 81 will attach the thigh restraint assembly 80 to the side of seat board 12 (or 11) through straps 82. The belt element 82 run around the user's thighs (or knees) and is capable to fasten sitter's thigh to the seat board 12. When the lift assembly 60 engages in an uplifting motion 70, a strong force might be able to completely or partially raise the sitter's torso from the seat board 12, and the sitter's thigh will be gradually hauled up and away from the seat board 12. When the sitter is partially or completely detached from seat board 12, he may have a feeling of discomfort. The restraint assembly 80 is employed here to ensure the sitter's thigh is always attached to the seat board 12 and prevent any such feeling of discomfort. The buckle elements 83 and 84 and restraint element 85 should allow the belts 82 to be fastened or loosen freely, which gives sufficient resistance to ensure the seat's thigh is always making contact with seat board 12. In the mean time, the buckle elements 83/84 should also be easily released if the user needs to get out of the chair or terminate the lifting operation. Note the adoption of restraint assembly 80 is optional, and it is desirable to have good size and shape on belt element 82 to make sure the sitter has maximum comfort.
In a preferred way to implement this proposed invention, there should be a controller device build inside the chair, such as the controller unit 76 in
On back board 23, there are multiple screw holes depicted as 66 in
In
In practice, there are several variations to mount the lift handle 60 onto chair 10. One variation is that the back support board 23 is detached from motor box 22. The support board 23 is permanently affixed to vertical member 17 (or 21) or horizontal member 11 or 12, so it becomes a static element and loses its mobility. On back support board 23, there are several openings, and these openings will allow the lift handle 60 to be directly attached to the motor box 22. So when Motor box 22 engages in vertical motion 70, the lift handle 60 will also move vertically through the opening on back board 23. Another alternative is that the support board 23 is permanently affixed to the vertical member 17 or 21, or horizontal member 12 or 11, and the motor box 22 is connected to lift handle 60 through the left or right side of support board 23 through a holding arm structure. This alternative will be further discussed in Embodiment C. The main advantage of these alternative designs is that a static back board 23 is widely used in conventional chair design. By modifying existing chairs, such as open holes on back support board 23, and adding lifting assembly 20 and lift handle assembly 60, a traditional chair can be converted into a back lift chair 10.
When a lifting force is applied on the user's axillae for a prolonged duration, the pressure under the user's arm will make the sitter un-comfortable. Therefore, it is important to have a pad 61 on top of the lift bar 62. The pad 61 can be made with soft materials such as foam, fabric or leather. Also, it is desirable to have good size and shape on the pad 61 that best match the sitter's body structure. Through proper design, the soft pad 61 will afford sufficient comfort when the sitter is partially or fully lifted. It is obvious that lift handles of various sizes, shapes, materials and designs should be considered to give the user maximum comfort. However, these different considerations all serve one unique purpose, which is to lift the sitter through his axillae in a healthy manner.
The Embodiment A utilizing the method of the present invention can effectively lift up partially or fully the user's upper torso, and hence reduce the pressure on his lower spine and provide significant health benefit. However, since all the lifting force is exerted at his axilla area, even with the soft element 61, the sitter may still experience discomfort after long term of stress around his arms. It is desirable to employ some other methods to disperse the stress of the lifting force and reduce the discomfort to a minimum level. Toward this goal, we propose the Embodiment B. In this embodiment, the hauling force is evenly scattered around the sitter's upper torso, and hence avoid the feeling of discomfort in his axilla area.
The Embodiment B is depicted in
Around the strap belt 32, there are several restraint members 35. These elements will make sure the belt elements 32 stay at fix locations on the vest 31 instead of sliding freely. With elements 35, the lifting force will not cause dislocation of the strap belt. In Embodiment B, we have shown 3 belt and buckle elements 32 through 34. However, it is obvious that various members of belt or buckle elements can be employed. It is understandable that the more belts and buckle elements around the user's torso, the more evenly the lifting force will be distributed, hence more comfort will be offered. However, more belt and buckle elements will be inconvenient for the user to adjust, and it will be harder to get out of the chair. So, the manufactures should carefully consider the number of belt elements 32. Also, when multiple belt and buckle elements are adopted on vest 31, they can be placed at various vertical locations. The highest belt can be wrapped around the users axilla area, and the lowest belt can be at the sitter's lower back area. With the multiple belts available, the user can tighten the specific belts that provide the most comfort and loosen the belts that give distress during the lifting actions.
To illustrate the Embodiment B employing the method of the present invention,
The tightening action around the human body on the belts 32 in Embodiment B is critical for the lifting action. If the belts are loosely wrapped around the torso, there will not be enough resistance between the vest 31 and the user's torso. The belt will slip alone the human body and hence loss its grip and fail to lift the user. If the belts are intensely bound to the user's torso, it will provide enough resistance to lift up the upper body. However, the intense pressure and attrition from the lifting motion will make the user uncomfortable. Compare to Embodiment A, the main advantage of Embodiment B is that it distributes the lifting force evenly along the user's upper body, instead of focusing on a specific spot at the axilla area. In an advanced design, the tightening action on each belt 32 should be driven by a motor and controlled by a controller device. In this way, the optimal tightening and releasing of belt 32 will allow the sitter to enjoy the minimum amount of distress. However, to control the tightening on each belt presents a cost and implementation challenge. In what follows, we introduce Embodiment C which gives an alternative implementation to lift, the user's body.
The Embodiment C is depicted in
In
In Embodiment C, the back support board 23 can be detached from motor box 22, and becomes a static element as in a traditional chair. It is also obvious that by adding motor box 22 and holding assembly 40, a traditional chair can be converted into a back lift chair 10 as in Embodiment C.
Another obvious improvement for the proposed back lifting chair 10 is that it can be combined with other types of chairs, such as massage chairs or rocking chairs, yet it should maintain most of its health advantage. Also, the user should be able to perform most of his normal activities without any trouble.
The proposed method of the invention, as depicted in the 3 embodiments, can be easily employed to the seat on a moving communication vehicle. In this case, it is desired to have an automatic or manual lock and release mechanism. It is especially important for Embodiment B and Embodiment C, in which a fast release mechanism should be installed on the lift vest assembly 30 or holding assembly 40. So, when the vehicle encounters an accident, the vest assembly 30 or holding assembly 40 can be immediately and automatically released, allowing the user to get away from his seat.
While several alternative embodiments demonstrating the method of the present invention have been described, it is readily clear to those skilled in the art that the present invention is subjected to all kinds of variation, reorganization, combination and simplification without departing from the spirit and scope of this invention. It is intended, therefore, by this document to cover all such modifications and changes all falling within the scope and spirit of the invention.
This application is a divisional application of co-pending U.S. Nonprovisional application Ser. No. 15/377,543, filed Dec. 13, 2016, which claims the benefit of U.S. Provisional Application No. 62/276,949 filed Jan. 10, 2016.
Number | Date | Country | |
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62276949 | Jan 2016 | US |
Number | Date | Country | |
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Parent | 15377543 | Dec 2016 | US |
Child | 16039955 | US |