TWM550127U - Reset correction device for activating spine with three-dimensional momentum - Google Patents

Description

Activated spine reduction orthosis with three-dimensional momentum

The utility model relates to a resetting device for activating a spine, in particular to a movement mode of a punch which is a telescopic and a rotator.

Modern people suffer from work, exercise, work schedule or long-term posture. More and more people have spinal cord lesions, and the severity varies from person to person. It has been found in the medical community that when the intervertebral disc is developed, the human spine begins to degenerate. Because the spine is the main beam of the human body, it is the main support for the trunk movement, including extension, flexion, and lateral flexion. A site prone to chronic strain. Therefore, in the event of acute trauma, or poor long-term posture, the spine will be advanced or accelerated to produce lesions.

At present, the treatment for spinal lesions is nothing more than surgery, acupuncture, massage, massage, etc. to alleviate pain or symptoms, especially the risk of spinal surgery is high, most patients are not willing to take the risk of surgery Because the effects and sequelae have deterred many patients, there is the so-called Activator Methods Chiropractic Technique (AMCT), which replaces traditional physical therapy.

When the problematic spinal joint undergoes subluxation, the legs will be unbalanced and the symptoms of long and short legs will occur. Different from the hand-to-hand chiropractic technique, a spine reduction orthosis is currently used to perform stimulation at a certain contact point; the spinal activation orthosis has a low strength and high velocity and strikes in the correct direction of the bone to form a Micro-mechanical stimulation, in addition to bone correction, also contains nerve reflexes, so the subluxation of the whole body skeleton joint is now Elephants can be used to find out where the body's skeleton joints are dysfunctional, and in conjunction with the reflex response of nerve tests, to find problems with the body's skeleton joints. Such continually detecting bones with different movements, finding and adjusting the problematic bones, and effectively relieving pain in clinical practice, developed a chiropractic using physical examination, treatment, and evaluation of the vertebral reduction orthosis. Osteopathy technology.

The spinal reduction orthosis is also known as the spinal activation orthosis. Some old manual spinal activation orthotics, such as the Chinese new patent CN201469468U adjustable hand-operated shock-activated orthosis, CN202568748U spine activator structure, that is, the hand movement, so that the movable sleeve (3) retreats and compresses a spring, by firing The spring pushes the movable sleeve (3) to produce a one-dimensional linear momentum to stimulate the spinal treatment point. Readers can get more information about these products from the videos provided at https://www.youtube.com/watch? v=UqJA_SwlvfE.

Because the old type of spine activates the orthosis, it can only be fired once, which is not convenient and labor-saving. Therefore, someone has invented an electric spine activation orthosis that can be continuously fired. For example, the US patent US7144417 motor adjuster (Electromechanical adjusting instrument) ), Chinese invention patent application CN101732145A electric chiseling machine, etc., using electromagnetic coil (21) and spring interaction, can continuously fire, producing one-dimensional linear momentum stimulation of spinal treatment points. Readers can get more information about these products from the videos provided at https://www.youtube.com/watch? v=XrDZyaplJ_U.

Both the old manual spine activation aligner and the later modified motor adjuster can only provide one-dimensional, linear punch impact motion, but the dislocation path of the whole body skeleton joint is a three-dimensional rotational path, the current spine. Activating the aligner can only perform a linear punch impact, and it is impossible for the revamped erector to use the spine activation aligner to flexibly implement the traditional push, squeeze, dial, and turn composite techniques.

In view of the fact that both the old manual spine activation aligner and the later modified motor regulator can only provide one-dimensional, linear punch impact motion, which cannot meet the traditional push, squeeze, dial, and turn hand skills. The creation of the present invention thus provides a reduction orthosis that activates the spine in three-dimensional momentum, the structure of which consists of a casing, a reciprocating mechanism, a movable sleeve, a grooved sleeve and a punch.

The casing can be made of aluminum casting or engineering plastic, and has a housing space for locking the reciprocating mechanism, the movable sleeve and the groove sleeve, and the external part can form a grip for the user to hold (not shown). , you can refer to the handle of the general electric drill).

The reciprocating mechanism can be practiced by a common reciprocating mechanism such as an eccentric wheel and a connecting rod driven by a motor; or can be composed of components such as an electromagnetic coil, a spring and an iron core, and can be electrically mounted in the interior of the casing, at the machine Reciprocating kinetic energy is provided within the casing. For the sake of brevity, the description of this case is only for the latter example, and is not intended to be limited to this example.

The grooved sleeve may be a hollow tubular body fixed to the inside of the casing, and at least one inclined groove is provided on the pipe wall.

The movable sleeve may also be a hollow metal tubular body slidably sleeved in the grooved sleeve, one end connected to the reciprocating mechanism, and reciprocated along the axis of the grooved sleeve when driven by the reciprocating mechanism Movement, the length of the other end is extended to the opening at the front end of the casing. The movable sleeve is radially extended on the peripheral surface, and a convex portion is caught in the inclined groove of the grooved sleeve. Therefore, when the movable sleeve is axially reciprocated in the grooved sleeve, the inclined groove can be used to guide the convex portion. The movement of the part transforms the linear reciprocating motion of the movable sleeve into a telescopic and rotational motion.

The punch has a handle and an elastic end; the handle can fit over the movable sleeve. The elastic end portion may be made of elastic plastic or rubber, and is fixed at the end of the punch by a general process such as socketing, thread locking or glue bonding, for transmitting the telescopic and rotating from the movable sleeve. The momentum of motion releases a non-linear, three-dimensional activation energy to the treatment point.

The reciprocating mechanism can be composed of an electromagnetic coil, an iron core and a return spring. The core passes through the return spring and the electromagnetic coil, and one end is connected to the movable sleeve. Before the current passes through the electromagnetic coil, the free extension of the return spring can cause the core to retract, and the convex portion just stays at a predetermined starting point in the oblique groove, and the punch is also in a retracted state due to the connection of the iron core and the movable sleeve.

When the current passes through the electromagnetic coil, the generated electromagnetic force causes the iron core to rapidly move toward the movable sleeve to compress the return spring, and the inclined groove guides the convex portion to extend the movable sleeve and the punch to the outside with limited rotation.

When the power supply to the electromagnetic coil is stopped, the electromagnetic force of the driving core disappears immediately, and the compressed return spring is re-stretched to retract the core, and the movable sleeve and the punch are rotatively returned to the starting point of the stroke.

The inclined groove on the grooved sleeve may be a single inclined groove, or may be changed to be provided with two inclined grooves which are open at one end and inclined in opposite directions to each other, or may be changed to have two ends communicating with each other and facing each other. The inclined groove with different directions but different inclinations, no matter which kind of alternative, is designed to guide the movement of the convex part, so that the punch releases the angular momentum of the rotation during the telescopic impact to achieve three-dimensional Momentum to activate the spine.

Through the implementation of this creation, the shortcomings common to all current spine activation appliances can be improved, three-dimensional momentum can be generated to activate the spine, and the traditional push, squeeze, dial, turn and other composite techniques can be used to save the skill. .

1‧‧‧Shell

2‧‧‧Reciprocating mechanism

3‧‧‧ Activity sleeve

4‧‧‧ trench sleeve

5‧‧‧ Punch

6‧‧‧Compressed spring

21‧‧‧Electromagnetic coil

22‧‧‧ iron core

23‧‧‧Return spring

31‧‧‧ convex

41‧‧‧ oblique ditch

51‧‧‧ handle

52‧‧‧Flexible ends

42‧‧‧ oblique grooves that are connected at one end and inclined in opposite directions to each other

43‧‧‧ oblique grooves that are connected at one end and are oriented in the same direction but different degrees of inclination

FIG. 1 is a schematic cross-sectional view of a three-dimensional momentum-activated spine, and FIG. 2 is a schematic diagram of a three-dimensional momentum-activated spine reduction orthosis, and an exploded view of the embodiment; FIG. It is a schematic diagram of a three-dimensional momentum-activated spine reduction orthosis, a cross-section of the punch when the electromagnetic coil is not energized; Figure 4 is a three-dimensional momentum-activated spine reduction orthosis, punched into the electromagnetic A schematic cross-sectional view of the coil rotating outward after being energized; Figure 5 is a schematic diagram of a three-dimensional momentum-activated spine reduction orthosis, a grooved sleeve deployment schematic (single groove embodiment); Figure 6, a copy A three-dimensional momentum-activated spine reduction orthosis, a schematic diagram of a grooved sleeve deployment (an embodiment of a diagonal groove with two ends communicating and inclined in opposite directions); Figure 7 is a three-dimensional momentum-activated spine Reset aligner, schematic diagram of the unfolding of the grooved sleeve (an example of a slanted groove with two ends communicating and inclined in opposite directions to each other); Figure 8 is a three-dimensional momentum-activated spine Position aligner, schematic diagram of the deployment of the grooved sleeve (the two slanting grooves are connected to each other in the same direction but different degrees of inclination); Figure 9 is a three-dimensional momentum-activated vertebral reduction orthosis, groove Schematic diagram of the development of the grooved sleeve (an example of a diagonal groove in which the two ends communicate with each other in the same direction but with different degrees of inclination).

As shown in FIGS. 1 and 2, the reduction orthosis that activates the spine in three-dimensional momentum is one of many possible embodiments of the present invention, including a casing 1, a reciprocating mechanism 2, a movable sleeve 3, and a groove. Sleeve 4 and a punch 5.

The casing 1 can be made of aluminum casting or engineering plastic injection, and has an accommodating space therein for locking components such as a reciprocating mechanism 2, a movable sleeve 3 and a grooved sleeve 4, and the outside can form a grip for the user to hold. (Not shown, you can refer to the handle of the general drill).

The reciprocating mechanism 2 can be practiced by a common reciprocating mechanism such as an eccentric wheel and a connecting rod driven by a motor; or can be composed of an electromagnetic coil, a spring, an iron core and the like, and can be electrically mounted in the interior of the casing 1 . Reciprocating kinetic energy is provided within the casing. For the sake of brevity, the following description is only for the sake of the latter, and is not intended to be limited to this example.

The grooved sleeve 4 can be a hollow tubular body fixed to the inside of the casing 1, and at least one inclined groove 41 is provided on the pipe wall.

The movable sleeve 3 can also be a hollow metal tubular body slidably sleeved in the groove sleeve 4, one end connected to the reciprocating mechanism 2, and the groove sleeve 4 can be driven by the reciprocating mechanism 2 The shaft is reciprocated, and the length of the other end is extended to the opening of the front end of the casing 1. The movable sleeve 3 is radially extended on the peripheral surface, and a convex portion 31 is caught in the inclined groove 41 of the grooved sleeve 4, so that when the movable sleeve 3 is axially reciprocated in the grooved sleeve 4, The movement of the convex portion 31 is guided by the inclined groove 41, and the linear reciprocating motion of the movable sleeve 3 is converted into a telescopic and rotational motion.

The punch 5 has a shank 51 and a resilient end 52; the shank 51 can fit over the movable sleeve 3. The elastic end portion 52 may be made of elastic plastic or rubber, and is fixed to the end of the punch 5 by a general process such as socketing, thread locking or glue bonding for transmitting the movable sleeve 3. The momentum of the telescopic and rotational motion releases a non-linear, three-dimensional activation energy to the treatment point.

The reciprocating mechanism 2 of the present embodiment can be composed of an electromagnetic coil 21, a core 22, and a return spring 23. The core 22 passes through the return spring 23 and the electromagnetic coil 21, and one end thereof is connected to the movable sleeve 3. As shown in FIG. 3, before the current passes through the electromagnetic coil 21, the return spring 23 is extended to cause the core 22 to retract, and at this time, the convex portion 31 is just stopped at a predetermined starting point in the inclined groove 41, since the core 22 is connected to the movable sleeve 3, The punch 5 is also in a state of contraction.

As shown in FIG. 4, when a current passes through the electromagnetic coil 21, the generated electromagnetic force causes the core 22 to rapidly move in the direction of the movable sleeve 3 to compress the return spring 23, and the inclined groove 41 guides the action of the convex portion 31 to make the movable sleeve 3 and the punch 5 is extended to the outside with limited rotation.

Referring to FIG. 3 again, when the power supply to the electromagnetic coil 21 is stopped, the electromagnetic force of the driving core 22 disappears immediately, and the compressed return spring 23 is re-stretched to retract the core 22, and the movable sleeve 3 and the punch are connected together. 5 Rotate back to the starting point of its trip.

The connection scheme of the movable sleeve 3 and the core 22 should include screwing, screwing after fixing, or gluing after socketing. In order to facilitate the repair and replacement of components, reference may be made to the preferred solution provided in FIG. 2, by using a screw bolt or a screw to pass through the inclined groove 41, and then locking the movable sleeve 3 against the core 22 for the purpose of fixing, the head of the screw bolt or the screw Then, the convex portion 31 is formed to achieve multiple functions of simplifying the structure and saving components.

The inclined groove 41 on the grooved sleeve 4 is designed to cause the punch 5 to simultaneously release the rotational angular momentum during the telescopic impact by guiding the movable trajectory of the convex portion 31. The oblique groove 41 on the grooved sleeve 4 can have a variety of variations based on the same creative purpose.

5 is a circumferential development view of the grooved sleeve 4, which means that the inclined groove 41 on the grooved sleeve 4 can be a single straight or slightly curved groove shape (the latter is a simple geometric change of a single straight line of the former, Not shown).

The circumferential development of the grooved sleeve 4 of Figs. 6 to 7 shows that the inclined groove 41 on the grooved sleeve 4 can be changed to be provided with two inclined grooves 42 which are open at opposite ends and are inclined in opposite directions to each other. In order to change the position of the convex portion 31, a compression spring 6 may be disposed between the reciprocating mechanism 2 and the movable sleeve 3, so that the convex portion 31 is kept away from the inclined grooves 42 which are open at one end and inclined in opposite directions to each other. a communicating channel, and when the punch 5 is forced against the movable sleeve 3, the movable sleeve 3 can compress the compression spring 6 so that the convex portion 31 can be switched to the other end to communicate with each other in opposite directions Oblique inclined groove 42.

Further, as shown in the circumferential development view of the grooved sleeve 4 of FIGS. 8 to 9, it is indicated that the inclined groove 41 of the above-mentioned grooved sleeve 4 can be changed to be provided with two ends communicating with each other in the same direction but different degrees of inclination. Oblique groove 43. Similarly, a compression spring 6 may be disposed between the reciprocating mechanism 2 and the movable sleeve 3, so that the convex portion 31 is kept away from the groove communicating with one end of each strip and communicating with the inclined grooves 43 which are in the same direction but different degrees of inclination. When the punch 5 is forced against the movable sleeve 3, the movable sleeve 3 will compress the compression spring 6, so that the convex portion 31 can be switched to the other inclined groove which is open at one end and different in inclination to each other. 43.

In FIGS. 5 to 9, the vertical arrows represent the stroke length and direction of the punch 5, and the horizontal arrows represent the magnitude and direction of the angular momentum of the rotation of the punch 5. It can be seen that the convex portions 31 have different angular momentum amounts or directions of rotation on the same stroke in the oblique grooves 41, 42, 43 of different inclinations and directions.

Through the implementation of this creation, the shortcomings common to all current manual and electric spine activation appliances can be improved, and three-dimensional momentum can be generated to activate the spine, so that traditional push, squeeze, dial, and turn composite techniques can be used to make new tools. Labor-saving and ingenious play.

1‧‧‧Shell

2‧‧‧Reciprocating mechanism

3‧‧‧ Activity sleeve

4‧‧‧ trench sleeve

5‧‧‧ Punch

6‧‧‧Compressed spring

21‧‧‧Electromagnetic coil

22‧‧‧ iron core

23‧‧‧Return spring

31‧‧‧ convex

41‧‧‧ oblique ditch

51‧‧‧ handle

52‧‧‧Flexible ends

Claims (7)

A resetting aligner for activating a spine with three-dimensional momentum, comprising: a casing (1) having an accommodating space inside for externally holding by a user; and a reciprocating mechanism (2) electrically operably mounted on The inside of the casing (1) provides reciprocating kinetic energy; a grooved sleeve (4) is a hollow metal tubular body fixed to the inside of the casing (1), and has at least one inclined groove on the pipe wall (41); a movable sleeve (3), which is a hollow metal tubular body slidably sleeved in the grooved sleeve (4), and one end is connected to the reciprocating mechanism (2), and is reciprocated The moving mechanism (2) can reciprocate along the axis of the groove sleeve (4) while driving, and the other end protrudes from the casing (1); the movable sleeve (3) is attached to the circumferential surface radially A protruding portion (31) is engaged with the inclined groove (41) to guide the movement direction of the convex portion (31) by the inclined groove (41) when the movable sleeve (3) is reciprocated, so that the movement The reciprocating motion of the sleeve (3) is converted into a telescopic and rotational motion; and a punch (5) having a handle (51) and an elastic end (52); the handle (51) can be sleeved Into the movable sleeve (3), the bullet An end portion (52) provided in the punch lines (5) of the end portion to the movable sleeve momentum transfer (3) and the telescopic motion of rotation, for the treatment of non-linear release point, three-dimensional activating energy. A resetting caliper for activating a spine in three-dimensional momentum according to claim 1, wherein the reciprocating mechanism (2) comprises an electromagnetic coil (21), a core (22) and a return spring (23); the core (22) Passing through the return spring (23) and the electromagnetic coil (21), one end of which is connected to the movable sleeve (3); when an electric current passes through the electromagnetic coil (21), an electromagnetic force is generated to compress the core (22) The return spring (23) rotates the movable sleeve (3) and the punch (5) outwardly; when the current passing through the electromagnetic coil (21) is cut off, the electromagnetic force disappears, and the return spring ( 23) The core (22) is reset to revolve the movable sleeve (3) and the punch (5). A resetting aligner for activating a spine in three-dimensional momentum as claimed in claim 1, wherein the convex portion (31) A bolt or screw is locked into the movable sleeve (3). A resetting aligner for activating a spine in three-dimensional momentum as claimed in claim 1, wherein the grooved sleeve (4) is provided with two inclined grooves (42) which are open at one end and are inclined in opposite directions to each other. The resetting aligner for activating the spine in three-dimensional momentum according to claim 4, wherein a compression spring (6) is disposed between the reciprocating mechanism (2) and the movable sleeve (3), so that the convex portion (31) Keeping away from the channel between the inclined grooves (42) which are open to each other and inclined in opposite directions to each other, and when the punch (5) is forced to push against the movable sleeve (3), the movable sleeve The cylinder (3) is capable of compressing the compression spring (6) so that the convex portion (31) is switched to a diagonal groove (42) which is open at the other end and inclined in opposite directions to each other. A resetting aligner for activating a spine in three-dimensional momentum as claimed in claim 1, wherein the grooved sleeve (4) is provided with two inclined grooves (43) which are open at one end and are oriented in the same direction but different degrees of inclination. The resetting aligner for activating the spine in three-dimensional momentum according to claim 6, wherein a compression spring (6) is disposed between the reciprocating mechanism (2) and the movable sleeve (3), so that the convex portion (31) Maintaining a channel that communicates with each of the inclined grooves (43) that are in the same direction but different in inclination to each other, and when the punch (5) is forced against the movable sleeve (3), The movable sleeve (3) is capable of compressing the compression spring (6) so that the convex portion (31) is switched to a diagonal groove (43) which is open at the other end and is oriented in the same direction but different degrees of inclination.