CN105629779A - Automatic vertebral body traction bed control method - Google Patents
Automatic vertebral body traction bed control method Download PDFInfo
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- CN105629779A CN105629779A CN201410709607.7A CN201410709607A CN105629779A CN 105629779 A CN105629779 A CN 105629779A CN 201410709607 A CN201410709607 A CN 201410709607A CN 105629779 A CN105629779 A CN 105629779A
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- pull
- tractive
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61H—PHYSICAL THERAPY APPARATUS, e.g. DEVICES FOR LOCATING OR STIMULATING REFLEX POINTS IN THE BODY; ARTIFICIAL RESPIRATION; MASSAGE; BATHING DEVICES FOR SPECIAL THERAPEUTIC OR HYGIENIC PURPOSES OR SPECIFIC PARTS OF THE BODY
- A61H1/00—Apparatus for passive exercising; Vibrating apparatus ; Chiropractic devices, e.g. body impacting devices, external devices for briefly extending or aligning unbroken bones
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- Health & Medical Sciences (AREA)
- Animal Behavior & Ethology (AREA)
- Pain & Pain Management (AREA)
- Physical Education & Sports Medicine (AREA)
- Rehabilitation Therapy (AREA)
- Life Sciences & Earth Sciences (AREA)
- Epidemiology (AREA)
- General Health & Medical Sciences (AREA)
- Public Health (AREA)
- Veterinary Medicine (AREA)
- Orthopedics, Nursing, And Contraception (AREA)
- Invalid Beds And Related Equipment (AREA)
- Prostheses (AREA)
Abstract
The invention relates to an automatic vertebral body traction bed control method. According to an existing microcomputer vertebral body traction bed, in a first traction process, a traction force borne by a human body is applied thoroughly by one step, namely is a set traction force; traction forces in each traction cycle are equal, and as a result, the defects of injury accidents caused by traction and non-obvious traction feeling about second traction of a user which may be brought about, while, with the automatic vertebral body traction bed control method adopted, the above defects can be avoided. According to the automatic vertebral body traction bed control method, a gradual approach is adopted, a traction force is gradually increased and eventually achieves a set traction force, and therefore, the defects in the use of the existing microcomputer vertebral body traction bed can be eliminated, and the use of a vertebral body traction bed can be safer, and the feeling about traction each time is more comfortable.
Description
Technical field
The present invention relates to a kind of vertebral body tractive bed, particularly relate to the control method of a kind of automatic vertebral body tractive bed.
Background technology
The programming Control circuit of micro computer vertebral body tractive bed is made up of main circuit board and control circuit plate two part now, main circuit board is used for controlling electric pushrod and runs, control circuit plate is connected with main circuit board, control circuit plate is used for inputting operational factor, control circuit plate arranges thin film switch or silica gel push-button constitutes manipulation screen, traction force can be set on manipulation screen, the tractive time, off time, the parameters such as total run time or cycle-index, when setting traction force, the setting that traction force can be added one or subtracts one, the traction force adding one and namely setting increases by one kilogram, the traction force subtracting one and namely setting reduces one kilogram. after startup, tractive bed will run according to the parameter set, in a pull-pull cycles, when traction force reaches setting value electric pushrod out of service and by pulling force maintain one set the tractive time, then being discharged pulling force by electric pushrod is back mobile and maintains an off time, subsequently entering next pull-pull cycles until terminating.
Micro computer vertebral body tractive bed uses tensile test step that step mainly includes being sequentially carried out, Parameter setting step, tractive step now, tensile test step includes the value of thrust that method test corpus vertebrae manually bears, and parameter setting step includes setting traction force, tractive time, off time, total time or pull-pull cycles number of times.
Problem is, micro computer vertebral body tractive bed now, in carrying out automatic pull process, starts to last pull-pull cycles to terminate from first time pull-pull cycles, and the traction force that human body is subject to is all setting value, and in pull-pull cycles each time, traction force is all equal. Due to human body exist a process adapted to gradually, if traction force settles at one go, in first time tractive it may happen that damage accident and be likely in traction process subsequently and make user that tractive is felt inconspicuous.
Summary of the invention
In order to solve micro computer vertebral body tractive bed now in first time traction process, the traction force that human body is subject to settles at one go and is setting value, and the pulling force in each pull-pull cycles subsequently is all setting value, so it is likely to cause user to pull accident in first time tractive, it is likely to and causes that tractive subsequently is felt the shortcoming such as inconspicuous by user, the present invention proposes the control method of a kind of automatic vertebral body tractive bed, it adopts incremental method, traction force finally reaches maximum in being gradually increased, can effectively solve the problem that micro computer vertebral body tractive bed traction force now settles produced shortcoming at one go.
The problem of this invention address that be the technical scheme is that the control method of a kind of automatic vertebral body tractive bed, mainly include being sequentially carried out tensile test step, Parameter setting step, tractive step, described tensile test step includes the value of thrust that method test corpus vertebrae manually bears, and described parameter setting step includes setting traction force f0, tractive time s, off time p, pull-pull cycles number of times be numerical value n, described tractive step including being automatically performed first time pull-pull cycles, being automatically performed second time pull-pull cycles until completing last pull-pull cycles, it is characterized in that, in the initial several times pull-pull cycles of described tractive step, actual traction force is in gradually increasing state.
Solution preferred version of the present invention is, in the initial several times pull-pull cycles of described tractive step, actual traction force is gradually increased up reaching maximum and continuing to keep this value until tractive terminates with quantitative T.
Solution preferred version of the present invention is, in each pull-pull cycles of described tractive step, actual traction force is gradually increased up reaching maximum with quantitative T.
Solution preferred version of the present invention is, in the initial several times pull-pull cycles of described tractive step, actual traction force gradually increases with quantitative 0.5-1KG.
Solution preferred version of the present invention is, includes more than four times pull-pull cycles in described tractive step, and with KG for unit of force, the value of the first time actual traction force of pull-pull cycles is for setting pulling force f0-T, the value of the second time actual traction force of pull-pull cycles is for setting pulling force f0, the value of the actual traction force of third time pull-pull cycles is for setting pulling force f0In+T each circulation later, the value of traction force remains f0+T��
Solution preferred version of the present invention is, includes three pull-pull cycles in described tractive step, and with KG for unit of force, the value of the first time actual traction force of pull-pull cycles is for setting pulling force f0-T, the value of the second time actual traction force of pull-pull cycles is for setting pulling force f0, the value of the third time actual traction force of pull-pull cycles is for setting pulling force f0+T��
Solution preferred version of the present invention is, includes twice pull-pull cycles in described tractive step, and with KG for unit of force, the value of the first time actual traction force of pull-pull cycles is for setting pulling force f0-T, the actual traction force of second time pull-pull cycles is f0��
In the technical scheme that the present invention proposes, actual traction force is realized by control circuit self in the function gradually automatically increased, and to increase this function in circuit design and Programming Design.
The invention has the beneficial effects as follows: the control method of a kind of automatic vertebral body tractive bed that the present invention proposes, owing to traction force is to adopt incremental method, in initial several times traction process, traction force gradually strengthens and finally reaches maximum, the stress making corpus vertebrae has a process adapted to gradually, using safe, comfortable, user can obtain traction effect more preferably.
Detailed description of the invention
In the prior art, in use, the pulling force in each traction process is not incremental to micro computer vertebral body tractive bed, but settle at one go, the traction force in traction process is equal to setting value each time. Such as, during use, first carry out tensile test step: user first passes through the traction force that manual method test corpus vertebrae bears, it is assumed that the traction force measured is 15KG; Then Parameter setting step is carried out: user can set that traction force 15KG, 2 minutes tractive time, 5 seconds off times, cycle-index 3; Finally carry out tractive step: after program starts, program will automatically control entrance first time traction process, electric pushrod runs, when traction force reaches 15KG, electric pushrod is by out of service and maintain the tractive time 2 minutes, then electric pushrod runs toward rightabout again, and release traction force also maintains 5 seconds off times; Then second time, third time traction process are completed until EP (end of program). There it can be seen that in each traction process, traction force size is all equal. Generally, the traction force that human body bears in first time traction process is not suitable for reaching immediately maximum, otherwise likely can pull accident, if traction force is all equal every time, user may feel that first time dynamics is too big, and it is not enough to be likely to sensation dynamics in each tractive subsequently, cause tractive DeGrain.
Specific embodiment one
In each pull-pull cycles, actual traction force is realized by control circuit self in the function gradually automatically increased, circuit design and Programming Design to increase this function, in this example, in circuit design and Programming Design, the amount that traction force gradually increases automatically being set as 1KG (kilogram), this functionality completes in equipment Manufacture Process. During use, being set in described tractive step and include more than four times pull-pull cycles, with KG for unit of force, the value of the first time actual traction force of pull-pull cycles is for setting pulling force f0-1, the value of the second time actual traction force of pull-pull cycles is for setting pulling force f0, the value of the actual traction force of third time pull-pull cycles is for setting pulling force f0+ 1 and later each time circulation in the value of traction force remain f0+1��
During use, first user carries out tensile test step: user first passes through the traction force that manual method test corpus vertebrae bears, it is assumed that the traction force measured is 15KG; Then Parameter setting step is carried out: user can set that traction force f0=15KG, 2 minutes tractive time, 5 seconds off times, cycle-index 4; Finally carry out tractive step: after program starts, equipment will carry out follow procedure automatically:
Oneth, program will automatically into first time traction process, and electric pushrod runs, when the value of traction force reaches f0During the i.e. 15KG-1KG=14KG of-1KG, electric pushrod is by out of service and maintain the tractive time 2 minutes, and then electric pushrod runs toward rightabout, and release traction force also maintains 5 seconds off times;
2nd, subsequently enters second time traction process, and electric pushrod runs, when the value of traction force reaches f0Namely, during 15KG, electric pushrod is by out of service and maintaining 2 minutes tractive time, and then electric pushrod runs toward rightabout, and release traction force also maintains 5 seconds off times;
3rd. subsequently entering third time traction process, electric pushrod runs, when the value of traction force reaches f0+ 1 namely 15KG+1KG=16KG time, electric pushrod is by out of service and maintaining 2 minutes tractive time, and then electric pushrod runs toward rightabout, and release traction force also maintains 5 seconds off times;
4th. subsequently entering the 4th traction process, electric pushrod runs, when the value of traction force reaches f0+ 1 namely 16KG time, electric pushrod by out of service and maintain 2 minutes tractive time, then electric pushrod toward rightabout run until tractive terminates.
Specific embodiment two
With first embodiment the difference is that, in this example, in circuit design and Programming Design, the amount that traction force gradually increases automatically is decided to be 0.5KG (kilogram), this functionality completes in equipment Manufacture Process.
Specific embodiment three
In this example, in circuit design and Programming Design, the amount that traction force gradually increases automatically being decided to be 1KG (kilogram), this functionality completes in equipment Manufacture Process.
During use, first user carries out tensile test step: user first passes through the traction force that manual method test corpus vertebrae bears, it is assumed that the traction force measured is 15KG; Then Parameter setting step is carried out: user can set that traction force f0=15KG, 2 minutes tractive time, 5 seconds off times, with first embodiment the difference is that, in this example, circulation time is set as several 3; Finally carry out tractive step: after program starts, equipment will carry out follow procedure automatically:
Oneth, program will automatically into first time traction process, and electric pushrod runs, when the value of traction force reaches f0During the i.e. 15KG-1KG=14KG of-1KG, electric pushrod is by out of service and maintain the tractive time 2 minutes, and then electric pushrod runs toward rightabout, and release traction force also maintains 5 seconds off times;
2nd, subsequently enters second time traction process, and electric pushrod runs, when the value of traction force reaches f0Namely, during 15KG, electric pushrod is by out of service and maintaining 2 minutes tractive time, and then electric pushrod runs toward rightabout, and release traction force also maintains 5 seconds off times;
3rd. subsequently entering third time traction process, electric pushrod runs, when the value of traction force reaches f0+ 1 namely 16KG time, electric pushrod by out of service and maintain 2 minutes tractive time, then electric pushrod toward rightabout run until tractive terminates.
Specific embodiment four
In this example, in circuit design and Programming Design, the amount that traction force gradually increases automatically being decided to be 1KG (kilogram), this functionality completes in equipment Manufacture Process.
During use, first user carries out tensile test step: user first passes through the traction force that manual method test corpus vertebrae bears, it is assumed that the traction force measured is 15KG; Then Parameter setting step is carried out: user can set that traction force f0=15KG, 2 minutes tractive time, 5 seconds off times, with first embodiment the difference is that, in this example, circulation time is set as several 2; Finally carry out tractive step: after program starts, equipment will carry out follow procedure automatically:
Oneth, program will automatically into first time traction process, and electric pushrod runs, when the value of traction force reaches f0During the i.e. 15KG-1KG=14KG of-1KG, electric pushrod is by out of service and maintain the tractive time 2 minutes, and then electric pushrod runs toward rightabout, and release traction force also maintains 5 seconds off times;
2nd, subsequently enters second time traction process, and electric pushrod runs, when the value of traction force reaches f0Namely during 15KG, electric pushrod by out of service and maintain 2 minutes tractive time, then electric pushrod toward rightabout run until tractive terminates.
From each embodiment above-mentioned, the control method of a kind of automatic vertebral body tractive bed that the present invention proposes, owing to pulling force is incremental, therefore, using safer, comfortable, user can obtain traction effect more preferably.
Claims (7)
1. the control method of an automatic vertebral body tractive bed, mainly include being sequentially carried out tensile test step, Parameter setting step, tractive step, described tensile test step includes the value of thrust that method test corpus vertebrae manually bears, and described parameter setting step includes setting traction force f0, tractive time s, off time p, pull-pull cycles number of times be numerical value n, described tractive step including being automatically performed first time pull-pull cycles, being automatically performed second time pull-pull cycles until completing last pull-pull cycles, it is characterized in that, in the initial several times pull-pull cycles of described tractive step, actual traction force is in gradually increasing state.
2. the control method of a kind of automatic vertebral body tractive bed according to claim 1, it is characterized in that, in the initial several times pull-pull cycles of described tractive step, actual traction force is gradually increased up reaching maximum and continuing to keep this value until tractive terminates with quantitative T.
3. the control method of a kind of automatic vertebral body tractive bed according to claim 1, is characterized in that, in each pull-pull cycles of described tractive step, actual traction force is gradually increased up reaching maximum with quantitative T.
4. the control method of a kind of automatic vertebral body tractive bed according to Claims 2 or 3, is characterized in that, described T is 0.5-1KG.
5. the control method of a kind of automatic vertebral body tractive bed according to claim 4, is characterized in that, include more than four times pull-pull cycles in described tractive step, and with KG for unit of force, the value of the first time actual traction force of pull-pull cycles is for setting pulling force f0-T, the value of the second time actual traction force of pull-pull cycles is for setting pulling force f0, the value of the actual traction force of third time pull-pull cycles is for setting pulling force f0In+T each circulation later, the value of traction force remains f0+T��
6. the control method of a kind of automatic vertebral body tractive bed according to claim 4, is characterized in that, include three pull-pull cycles in described tractive step, and with KG for unit of force, the value of the first time actual traction force of pull-pull cycles is for setting pulling force f0-T, the value of the second time actual traction force of pull-pull cycles is for setting pulling force f0, the value of the third time actual traction force of pull-pull cycles is for setting pulling force f0+T��
7. the control method of a kind of automatic vertebral body tractive bed according to claim 4, is characterized in that, include twice pull-pull cycles in described tractive step, and with KG for unit of force, the value of the first time actual traction force of pull-pull cycles is for setting pulling force f0-T, the actual traction force of second time pull-pull cycles is f0��
Priority Applications (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201410709607.7A CN105629779A (en) | 2014-11-28 | 2014-11-28 | Automatic vertebral body traction bed control method |
PCT/CN2015/076321 WO2016082421A1 (en) | 2014-11-28 | 2015-04-10 | Control method for automatic vertebral traction table |
LT2015035A LT6302B (en) | 2014-11-28 | 2015-05-06 | A control method for an automatic centrum pulling bed |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201410709607.7A CN105629779A (en) | 2014-11-28 | 2014-11-28 | Automatic vertebral body traction bed control method |
Publications (1)
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CN105629779A true CN105629779A (en) | 2016-06-01 |
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CN201410709607.7A Pending CN105629779A (en) | 2014-11-28 | 2014-11-28 | Automatic vertebral body traction bed control method |
Country Status (3)
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CN (1) | CN105629779A (en) |
LT (1) | LT6302B (en) |
WO (1) | WO2016082421A1 (en) |
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IL141848A0 (en) * | 1998-08-12 | 2002-03-10 | Dyer Allan E | Operation of a vertebral axial decompression table |
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2014
- 2014-11-28 CN CN201410709607.7A patent/CN105629779A/en active Pending
-
2015
- 2015-04-10 WO PCT/CN2015/076321 patent/WO2016082421A1/en active Application Filing
- 2015-05-06 LT LT2015035A patent/LT6302B/en not_active IP Right Cessation
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WO2000069388A3 (en) * | 1999-05-12 | 2001-02-01 | Gregory Kevin Picou | Coin-operated massage table and method and system for providing high quality massage |
GB2359751A (en) * | 2000-03-02 | 2001-09-05 | Abdel Malek George | Self controlled orthopaedic traction table |
US7127757B2 (en) * | 2004-03-05 | 2006-10-31 | Christopher Matthew Roberto | Adjustable traction table |
CN101287426A (en) * | 2005-04-01 | 2008-10-15 | 大卫·B.·巴斯 | Recliner spinal traction device |
DE102008050233A1 (en) * | 2008-10-02 | 2010-04-08 | Copf jun., Franz, Dr. | Instrument for measuring the distraction pressure between vertebral bodies |
CN203710200U (en) * | 2013-07-30 | 2014-07-16 | 孙从府 | Traction table |
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Also Published As
Publication number | Publication date |
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LT2015035A (en) | 2016-06-10 |
WO2016082421A1 (en) | 2016-06-02 |
LT6302B (en) | 2016-08-25 |
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Application publication date: 20160601 |