CA1307302C - Training device for rehabilitation - Google Patents
Training device for rehabilitationInfo
- Publication number
- CA1307302C CA1307302C CA000541676A CA541676A CA1307302C CA 1307302 C CA1307302 C CA 1307302C CA 000541676 A CA000541676 A CA 000541676A CA 541676 A CA541676 A CA 541676A CA 1307302 C CA1307302 C CA 1307302C
- Authority
- CA
- Canada
- Prior art keywords
- heart rate
- load
- target
- ergometer
- value
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Fee Related
Links
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- 230000007423 decrease Effects 0.000 claims description 5
- 230000001419 dependent effect Effects 0.000 claims 1
- 208000019622 heart disease Diseases 0.000 description 10
- 210000003205 muscle Anatomy 0.000 description 6
- 238000010792 warming Methods 0.000 description 4
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Classifications
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/22—Ergometry; Measuring muscular strength or the force of a muscular blow
- A61B5/221—Ergometry, e.g. by using bicycle type apparatus
- A61B5/222—Ergometry, e.g. by using bicycle type apparatus combined with detection or measurement of physiological parameters, e.g. heart rate
-
- A—HUMAN NECESSITIES
- A63—SPORTS; GAMES; AMUSEMENTS
- A63B—APPARATUS FOR PHYSICAL TRAINING, GYMNASTICS, SWIMMING, CLIMBING, OR FENCING; BALL GAMES; TRAINING EQUIPMENT
- A63B22/00—Exercising apparatus specially adapted for conditioning the cardio-vascular system, for training agility or co-ordination of movements
- A63B22/06—Exercising apparatus specially adapted for conditioning the cardio-vascular system, for training agility or co-ordination of movements with support elements performing a rotating cycling movement, i.e. a closed path movement
- A63B22/0605—Exercising apparatus specially adapted for conditioning the cardio-vascular system, for training agility or co-ordination of movements with support elements performing a rotating cycling movement, i.e. a closed path movement performing a circular movement, e.g. ergometers
-
- A—HUMAN NECESSITIES
- A63—SPORTS; GAMES; AMUSEMENTS
- A63B—APPARATUS FOR PHYSICAL TRAINING, GYMNASTICS, SWIMMING, CLIMBING, OR FENCING; BALL GAMES; TRAINING EQUIPMENT
- A63B24/00—Electric or electronic controls for exercising apparatus of preceding groups; Controlling or monitoring of exercises, sportive games, training or athletic performances
-
- A—HUMAN NECESSITIES
- A63—SPORTS; GAMES; AMUSEMENTS
- A63B—APPARATUS FOR PHYSICAL TRAINING, GYMNASTICS, SWIMMING, CLIMBING, OR FENCING; BALL GAMES; TRAINING EQUIPMENT
- A63B21/00—Exercising apparatus for developing or strengthening the muscles or joints of the body by working against a counterforce, with or without measuring devices
- A63B21/005—Exercising apparatus for developing or strengthening the muscles or joints of the body by working against a counterforce, with or without measuring devices using electromagnetic or electric force-resisters
- A63B21/0051—Exercising apparatus for developing or strengthening the muscles or joints of the body by working against a counterforce, with or without measuring devices using electromagnetic or electric force-resisters using eddy currents induced in moved elements, e.g. by permanent magnets
- A63B21/0052—Exercising apparatus for developing or strengthening the muscles or joints of the body by working against a counterforce, with or without measuring devices using electromagnetic or electric force-resisters using eddy currents induced in moved elements, e.g. by permanent magnets induced by electromagnets
-
- A—HUMAN NECESSITIES
- A63—SPORTS; GAMES; AMUSEMENTS
- A63B—APPARATUS FOR PHYSICAL TRAINING, GYMNASTICS, SWIMMING, CLIMBING, OR FENCING; BALL GAMES; TRAINING EQUIPMENT
- A63B2220/00—Measuring of physical parameters relating to sporting activity
- A63B2220/17—Counting, e.g. counting periodical movements, revolutions or cycles, or including further data processing to determine distances or speed
-
- A—HUMAN NECESSITIES
- A63—SPORTS; GAMES; AMUSEMENTS
- A63B—APPARATUS FOR PHYSICAL TRAINING, GYMNASTICS, SWIMMING, CLIMBING, OR FENCING; BALL GAMES; TRAINING EQUIPMENT
- A63B2230/00—Measuring physiological parameters of the user
- A63B2230/04—Measuring physiological parameters of the user heartbeat characteristics, e.g. ECG, blood pressure modulations
- A63B2230/06—Measuring physiological parameters of the user heartbeat characteristics, e.g. ECG, blood pressure modulations heartbeat rate only
-
- A—HUMAN NECESSITIES
- A63—SPORTS; GAMES; AMUSEMENTS
- A63B—APPARATUS FOR PHYSICAL TRAINING, GYMNASTICS, SWIMMING, CLIMBING, OR FENCING; BALL GAMES; TRAINING EQUIPMENT
- A63B2230/00—Measuring physiological parameters of the user
- A63B2230/04—Measuring physiological parameters of the user heartbeat characteristics, e.g. ECG, blood pressure modulations
- A63B2230/06—Measuring physiological parameters of the user heartbeat characteristics, e.g. ECG, blood pressure modulations heartbeat rate only
- A63B2230/062—Measuring physiological parameters of the user heartbeat characteristics, e.g. ECG, blood pressure modulations heartbeat rate only used as a control parameter for the apparatus
-
- A—HUMAN NECESSITIES
- A63—SPORTS; GAMES; AMUSEMENTS
- A63B—APPARATUS FOR PHYSICAL TRAINING, GYMNASTICS, SWIMMING, CLIMBING, OR FENCING; BALL GAMES; TRAINING EQUIPMENT
- A63B23/00—Exercising apparatus specially adapted for particular parts of the body
- A63B23/035—Exercising apparatus specially adapted for particular parts of the body for limbs, i.e. upper or lower limbs, e.g. simultaneously
- A63B23/04—Exercising apparatus specially adapted for particular parts of the body for limbs, i.e. upper or lower limbs, e.g. simultaneously for lower limbs
- A63B23/0476—Exercising apparatus specially adapted for particular parts of the body for limbs, i.e. upper or lower limbs, e.g. simultaneously for lower limbs by rotating cycling movement
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10S—TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10S482/00—Exercise devices
- Y10S482/901—Exercise devices having computer circuitry
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10S—TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10S482/00—Exercise devices
- Y10S482/901—Exercise devices having computer circuitry
- Y10S482/902—Employing specific graphic or video display
Abstract
ABSTRACT OF THE DISCLOSURE
A rehabilitation training device and method in which a target heart rate is input, the heart rate is measured and a load in an ergometer operated by the person undergoing rehabilitation is changed accordingly. There are four steps in the training: (1) warm up - the load is increased to have the heart rate linearly approach the target value; (2) automatic - the load is varied to maintain the heart rate at the target; (3) interval - the load is alternated between its average value in the automatic step and a fraction thereof, and (4) cool-down-the load is gradually decreased.
A rehabilitation training device and method in which a target heart rate is input, the heart rate is measured and a load in an ergometer operated by the person undergoing rehabilitation is changed accordingly. There are four steps in the training: (1) warm up - the load is increased to have the heart rate linearly approach the target value; (2) automatic - the load is varied to maintain the heart rate at the target; (3) interval - the load is alternated between its average value in the automatic step and a fraction thereof, and (4) cool-down-the load is gradually decreased.
Description
o 7 3 n 2 TRAINING DEVICE FOR REHABILITATION
Field of the Invention This invention relates to a training device for rehabilitation which can be readily used for rehabilitation of a person at his home who has recovered, for instance, from heart disease. In such a training device, the load is controlled by heart rate measuring means, which is based on electro-cardio-potential, in order to maintain a relatively low target heart rate. The load is further controlled suitably in the warming-up stage and in the interval training stage according to the str~ngth of the legs or waist of the person who has recovered from the illness by surgical operation, thereby to ~ncrease his physical strength.
Backqround of the Invention A variety of so-called "bicycle ergometer type training devices" are commercially available in which, in response to instructions from a microcomputer built therein, the physical conditions of a person (age, weight, sex and heart rate) are inputted. There data are processed so that an optimum load value and a controlled heart rate under the load are determined. The exercise of the person (user or operator) is continuously controlled .,~
Field of the Invention This invention relates to a training device for rehabilitation which can be readily used for rehabilitation of a person at his home who has recovered, for instance, from heart disease. In such a training device, the load is controlled by heart rate measuring means, which is based on electro-cardio-potential, in order to maintain a relatively low target heart rate. The load is further controlled suitably in the warming-up stage and in the interval training stage according to the str~ngth of the legs or waist of the person who has recovered from the illness by surgical operation, thereby to ~ncrease his physical strength.
Backqround of the Invention A variety of so-called "bicycle ergometer type training devices" are commercially available in which, in response to instructions from a microcomputer built therein, the physical conditions of a person (age, weight, sex and heart rate) are inputted. There data are processed so that an optimum load value and a controlled heart rate under the load are determined. The exercise of the person (user or operator) is continuously controlled .,~
-2- 1 3 ~ 7 ~
1 according to these data. Reference is made to Canadian Patent No. 1,230,635 entitled ~sicycle Ergometer and Eddy Current srake Therefor~ and Japanese Patent Application No. 69922/1984+ entitled ~'Training Device~ which have been filed by the present applicant.
Of these conventional training devices, one is generally provided for a healthy person in which the load is automatically controlled so as to maintain the heart rate at a predetermined target value and therefore its target heart rate is high. Therefore, the training device is not suitable for a person who is being rehabilitated to restore th~ muscles of the legs and waist which has been weakened by his being confined to bed with a disease.
That is, with the training device, the warming up for allowing the heart rate to reach the target heart rate is considerably strenuous and abrupt for such a person. In addition, even after the heart rate has reached the target value, the load is increased. Thus, the conventional training device is unsuitable for those who need to be rehabilitated.
In almost all the conventional bicycle ergometers for healthy persons, the target heart rate is automatically set according to the statistical central values of past data which have been obtained separately +Published October 28, 1985; Japanese Publica~ion No. 215373/
1985.
A
~3~ 1 3073n2 1 according to ages and sexes. However, no such past data have been provided for those who have recovered from heart disease and are to be rehabilitated. Accordingly, depending on the conventional training device in wnich such past data are automatically setO it is impossible to apply even one of the target numbers of heart rates to these person. That is, the target numbers of heart xates for these persons depend greatly on their recover~
conditions or physical strengths. Accordingly, the target numbers of heart rate and the rehabilitation training fr~equencies for them should be speciied by their personal physicians and input data such as a target heart rate for the rehabilitation training should be manually înputtedO
However, in the above-described training device for healthy people, various data are automatically inputted and~ these input data are those which have been statistically determined from the past data. Therefore, in the conventional training device, it is impossible to input the data which are exactly applicable to those people~ That is~ it is impossible to correctl~
rehabilitate them with the conventional training device.
In the case of rehabilitation of a person who has recovered from heart disease, especially in the case of rehabilitation with a training device, the training itself 25 would be dangerous for the person if it were carried out -4- 1 3073n~
1 without correctly knowing the variations of his physical conditions which may occur during the training in addition to the physical conditions. There are a few facilities which can conduct the rehabilitation by correctly detecting the variations of physical conditions of a person which may occur during the exercise. Examples of such facilities are hospitals and rehabilitation c~nters where doctors are controlling the training. However, only a limited number of persons can utilize such excellent facilities.
For instance in America where the rehabilitation is conducted under such desirable conditions while being controlled by doctors, almost all the training devices are those which are designed for healthy person. Accordingly, thGse training devices are utilized with training programs for~;healthy people converted into ones for rehabilitation.
In the rehabilitation which is conducted with such a training device for those who has recovered from heart disease, the rehabilitation program is obtained merely by rearranging the training program provided for healthy people. For instance, in the case of the bicycle ergometer type training device, a target heart rate is determined in advance and the ergometer load increasing rate is so arranged that the heart rate of a rehabilitating person being trained reaches the target -5- l 3Q7 302 1 heart rate more slowly than those of a healthy person.
Therefore, the training program thus rearranged may be useful for the rehabilitation training in which the heart rate of a person being trained reaches the target value only slowly. On the other handr the fatigue of the muscles of the legs and the waist depends greatly on the physical strengths of persons to be rehabilitated. Por instance, even though the heart rate is increasing slowly according to the aforementioned load increasing rate, i.e., it is ideally reaching the target value, sometimes the fatigue of the muscles of the legs and the waist increases so much that the training cannot be satisfactorily continued.
However, the inventor believes that it is no exaggeration to say that the training device for reh~abilitation of a person who has recovered from heart disease in which the above-described difficulties have been eliminated has never been proposed in the art. There has been a strong demand for the quick development bf a training device used only for rehabilitation of such persons.
SU~MARY OF THE INVENTION
In view of the foregoing, an object of thi~
invention is to provide a training device for rehabilitationc In the train;ng device of the inventiont at least four training steps, warming-up, automatic control, interval and cool-downl are provided. Ph~sical data o~ a person to be rehabilitated who is at rest before the warming-up step and those which are measured several times during the warming-up step are processed by a predetermined processing means SQ that a load control setting range is determined for each of the trainin~
steps. According to the variation of the physical data of the person measured during continuous training, the load is increased or decreased so that the physical conditions conform to the loaa control 4etting ran~es. In this training devicej after the person is held at rest, a relatively long warming-up period is provided so that the heart rate of the person is increased substantiall~
linearly towards the target value during the warmin~-up period. In the automatic control step, the heart rate set for the rehabilitation of the person is maintained substantially constant, and the average load value required for maintaining that heart beats is measured.
The average load value is utilized in the following -7- l 30730~
l interval steps so that, while the target heart rate is maintained at an optimum value, the load is intermittently decreased thereby to reduce the load applied to the legs and the waist. Thereby the physical strength of the person who has recovered from the heart disease can be suitably increased.
BRIEF DESCRIPTION OF T~E DRAWINGS
FigO l is an explanatory diagram showing one example of a training device for rehabilitation according to this invention and the use thereof.
Fig. 2 is a block diagram of a control section in the training device shown in Fig.l.
Fig. 3 is a perspective view of a control box in the training device.
Fig. 4a and 4b are two parts of a flow chart for a description of the operation of the training device for rehabilitation according to the invention.
Fig. 5 if a time chart showing training program data in the training device according to the invention.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
One example of a training device for rehabilitation according to this invention will be described with reference to the accompanying drawings.
In Fig. l is shown a training device 10 of the invention, namely, a bicycle ergometer which loads the 1 operator with his flexing motion. The training device 10 includes a frame 1 and loading means 2 rotatably supported by the frame 1. The loading means 2 is made up of, for instance, an eddy current brake, only the essential part of which is shown in Fig. 1. The eddy current brake has been described in Japanese Patent Application No. 123171/1983 by the present applicant. Pedals 3 powered by the user rotate the loading means 2. A saddle 4 is mounted on a supporting member extended from the frame 1 in such a manner that the saddle 4 is movable vertically. In front of the saddle 4, there is provided a handle bar 5 which is fixedly mounted on a supporting member extended from t~e frame 1. An input/output box 6 is mounted in the middle of the handle 5. The input/output box 6 is used to input physical conditions (described latér~ and to output and display predetermined data. electro-cardio-potential sensors 7 (each comprising a conductive rubber electrode or an Ag/AgCl disposal electrode) are connected to one side of the input/output box 6. Installed inside the frame 1 are the aforementioned loading means 2, and, as shown in Fig. 2, a power source 8 for supplying current and voltage to various parts o~ the bicycle erogemeter and various other circuits shown in Fig. 2. These other circuits include a constant current control circuit 9, an eddy current brake +Published January 26, 1985: Japanese Publication No. 16169/
1985.
c~
1 11, a rotation sensor 12, a floating .circuit 13, an amplifier 14, a filter 15, an electro-cardio-potential waveform shaping circuit 16 and a microcomputer 2Q
(described later)O
Figc 2 shows the means or controlling the training .device for rehabilltation according to the invention, i~ec~ the bicycle ergometer 10. The cor,trolling means comprises the afoxementioned input/output box 6r an arithmetic and control unit arranged near the loadin~ means 2, and a peripheral unit related thereto. The microcomputer 20 includes an input/output unit (hereinafter referred to as "an I/O unit 21"), a central processing unit ~CPU) 22~ a ~andom access memory (RAM) 23r a read-only memory (ROM) 24, a timer lS circuit 25 and a buzzer 26 ~ ; The microcomputer 20 operates to read processin~
programs for rehabilitation out of the ROM 24. The mi.crocomputer 20 also inputs to the CPU 22 thxough the I~O
unit 21~ according to the processing program thus xead~
both data supplied from the input/output box 6 such as physical conditions (for instance a target heart rate specified by the doctor after a heart d;sease ha$ been cured) as well as signals from the electro-cardio-potehtial sensors 7 and the rotation sensor 12. The microcomputer 20 further operates to store in the RAM 23 -10~ 0 ' 302 1 various data processed by the CPU 22, to transfer the processing program for rehabilitation read out of the ROM
24 to the RAM 23, and to control the amount of load of the loading means 2 through the constant current control circuit 9 according to the processing program thus transferred. Thenr according to the data finally provided by RAM 23, the CPU 22 operates to apply predetermined data such as desired heart rate and a load value through the I/O unit 21 to the inputJoutput box 6 so that the data are 10 displayed.
Fig. 3 shows the front panel of the input/output boa 6. A display section is provided in the upper portion of the front panel for displaying the target heart rate, a range of the variable numbers of heart rates, time, a load value, a calorie value, a distance and the revolutions.
Var~ous keys for inputting various data required for rehabilitation such as physical conditions lage, sex, etc.) are provided in the lower portion of the front panel.
Now, a rehabilitation exercise carried out with the bicycle ergometer 1 thus constructed will be described with reference to Figs. 4a, 4b and 5.
~irst, the operator (or user) sits on the saddle 4 of the bicycle ergometer 1 shown in Fig. 1 and selects a desired program mode by operating the corresponding key on 1 the front panel of the input/output box 6 shown in Fig. 3.
The user then fixes the electro-cardio-potential sensors 7 on the right and left of his chest (with the reset key depressed). Thereafter, he inputs the target heart rate (TER) specified by the doctor. Now, he can start the rehabilitation by depressing the start key.
When the rehabilitation exercise is started in this manner, the desired program is read out of the ROM
24. At the same time, the timer circuit 25 coupled to the CP~ 22 starts its operation, so that pulses from the sensors 7 (with the operator at xest) are measured for abcut one minute (the current heart rate being sampled n ti~es each for m seconds for a correct value). The average heart rate per minute with an operator at rest HRo (hereinafter referred to as "the average heart rate at rest HRol'~ is obtained by averaging the heart rates thus measuredO Then the heart rate reserve HRR is obtained by . subtracting the heart rate at rest HRo from the target heart rate THR ~HRR = THR - HRo). The heart rate reserve is utilized to determine a value for Xl of 1, 2 or 3 according to the program, where a large value of X
corresponds to a large heart rate reserve.
After the measurement of the average heart rate at rest HRo and the heart rate reserve HRR have ~een determinedr the operator pedals in synchronization with -12- l 307302 l sounds produced at equal intervals; that is, the initial warming-up operation of Fig~ 5 is effected. In this case, when the heart rate of the operator exceeds the preset sum of the target heart rate THR plus fifteen (THR * 15), the buzzer 26 operates, thus warning him that he should stop the exercise. The increment of +15 is the numerical value for adjusting the sensitivity of the buzzer. For a rehabilitation exercise, the numerical value of the increment is preferably set to about ~5 thereby to increase the sensitivity of the buzzer because the user can exercise himself feeling at rest. That is, the wanning-up can be continued until the buzzer 26 operates.
In the warming-up period, the load value W of the load means 2 is controlled with a moderate rise of dw/dt =
W/~t, for instance 2w/lO sec, i.e. 0.2 watts/sec, bec~use of the initial warming-up. Further in the initial warming-up, the average heart rate HRl per minute is obtained similarly as in the case of the above-described average heart rate at rest HRo and a value Yl of l, 2 or 3 shown in the flow chart of Fig. 4a is determined. That is, the value Yl is determined according to where the average heart rate HRl is located between the heart rate at rest HRo and the target heart rate THR, with a large value of Yl corresponding to a low heart rate.
-13- 1 3n7302 l After the warming-up period of one minute has passed, the middle warming-up operation is effected for about two to four minutes. In the middle warming-up operation, the loading means 2 is controlled according to a load value which is determined by a value Zl where Zl ~
(Xl + Yl)/2 with any non-integer part disregarded, as shown in the flow chart of Fig. 4a. In the middle warming-up stage, because of the middle warming-up, the load rise rate is larger than that in the initial warming-up stage. Specifically, ~W/~t = 2w/lO sec when Zl = l, ~Wf~t = 4w/lO sec when 31 = 2, and ~W/~t = 6w/lO sec when Zl = 3.
In the middle warming-up stage also, the average heart rate HR2 is measured for the third (2 - 3) minute.
The value W is suitably corrected by utilizing the average heart rate HRz and a value JHRn where JHRn = HRo + ~THR -HRo) x (2n - l)/lO and n = l to 5. For instance, W2 = (Wl - l) when HR2 > JHR2 -~ 3, W2 = (Wl + 0) when JHR2 - 3 S
HR2 < JHR2 + 3, and W2 = (Wl ~ l) when HR2 < JHR2 ~ 3-The above-described control of the loading means 2 is carried out also for the fourth (3 - 4) minute. In the fourth minute also, the average heart rate HR3 is measured for the fourth minute. Then, it is determined whether or not the difference between thP average heart rate HR3 and the target heart rate THR is larger than ten (lO) heart -14- l 30730~. -l beats. If the difference (THR - HR3) is larger than ten (lO), then the load value is increased by lOwj and if smaller, he may continue the middle warmin~-up.
In the above-described embodiment, the difference between the average heart rate HR3 and the target heart rate THR is compared with ten (heart beats~ to determined whether or not the load should be increased by lOw.
However, the reference value may be smaller than ten, and the increment W is not limited only tQ lOw.
The third-and-fourth-minute middle warming up staye is followed by the final warmin~-up sta~e which lasts fo~ another two minutes (the fifth and sixth ~inutes).
In the final warming-up stage, the loading means 2 is controlled according to a load value W which is determined ~y the value Zl shown in the flow chart of ~ig. 4b. . In the final warming-up stage, because of the final warming-up the load rise rate is smaller than that in the middle warming-up stage; ~W3/~t = ~W2/~t when Zl =
l, ~3/~t = 3w/10 sec when Zl = 2, and ~W3/~t - 4w~10 sec when Zl = 3. In the final warming-up sta~e also, the average heart rate HR4 is measured for the fifth (4 - 5) minute. The avera~e heart rate HR4 and a value JHR4 are utili~ed to suitably correct the value W. Namely ~W4/~t =
(~W4/~t - 1) when HR4 > JHR4 + 3, AW4/~t = (~w3/At + 0~
-15- l 307302 l when JHR4 - 3 < HR4 ~ JHR4 ~ 3, and ~W~/~t = (~W3/~t + l) when HR4 < JHR4 - 3.
The control of the loading means 2 is carried out in the same manner for the sixth 55 - 6) minute. In the S sixth minute also, the average heart rate HR5 is measured.
Then, it is determined whether or not the difference between the target heart rate THR and the average heart rate HR5 (THR - HR5) is larger than ten (10) heart rate.
If the difference is larger than ten (lO), then the load value W is further increased by 10 watts, and if smaller, the operator may continue the final warming-up.
In the above-described embodiment, the difference between the average heaEt rate HR5 and the target heart rate T~R is compared with ten (heart beats) to determine whether or not the load should be increased by lO~.
However, the reference value may be smaller than ten, and the increment to W is not limited only to lOw.
Thus, the loading means 2 has been so controlled by the five-minutes warming up that it is most suitable to the user.
If, even after the warming-up, the heart rate does reach the target heart rate THR, the load value W is maintained as it is. When the heart rate exceeds the target heart rate THR, the load value is decreased by about 20%. The decrease of the load value depends on the -16- l 307302 1 physical conditions and strength of the person being rehabilitated. However it has been found through past experimental rehabilitations that, if, after the warming-up, the load means 2 is controlled with the load value determined in the final warming-up stage, the heart rate of the operator greatly exceeds the target heart rate THR.
Therefore, the decrease of the load value is so programmed that it is carried out within about two minutes after the warming-upO According, in the embodiment, with the load value W decreased by about 20%, an automatic control is carried out after the eighth minute. That is, a rehabilitation exercise is conducted for about six minutes with the heart rate being maintained equal to the target heart rate THR.
In the automatic control, the load is determined by the following expression:
~W = Gp (~HR~ HRn'_l) + Gi-~HRn' (W) where aw is the amount of adjustment of the load W, HRn' is the heart rate at the time instant tn~ ~HRnl =
HRn' - THR so that ~HRn' is the deviation, Gp is a proportional constant, TH~ is the target heart rate, Gi is an integra constant, and tS = tn ~ tn_l is the HRn sampling period. In the preferred embodiment Gp = l, Gi = 1, and ts = 20 sec. However, these values may be changed.
-17- l 307 ~02 l The automatic control rehabilitation training period described above is followed by an interval training period. For the interval training period, an average load value W~ is determined for the last five minutes of the s auto~atic control rehabilitation training period and is used as an upper reference value. A lower reference is value WL is determined as WL. = W~ x 0.6. The two reference load values WH and WL are alternately and repeatedly given for the load value W to the extent that the heart rate does not exceed the target heart rate THR.
The average load value W~ can either be measured or, more easily, be calculated from previously set values of the load W over the period of 9" to 14".
This interval training period is the most specific feature of the invention. As was described before, immediately after the heart disease has been cured, the patient's physical condition is much lower than that of a healthy person. Therefore, a warming-up exercise is suitably conducted before the rehabilitation training, the rise of the heart rate and the increase in fatigue of the muscles of the legs and the waist are liable to be unbalanced with each other. Accordin~ly, even in the case where it seems that the heart rate of the operator is much different from the target heart rate, the muscles of the feet and the waist are often greatly fatigued. Under this -18- l 3(~730~
l condition, continuation of the above-described automatic control training is not suitable fo~ the rehabilitation, and may sometimes be considerately dangerous for him.
In order to eliminate the above-described difficulties, in the invention, the interval training period is provided in the training program, so that the rehabilitation training is effectively and safely carried out with good balance kept between the rise of the heart rate and the increase in fatigue of the muscles of the legs and the waist.
In the above-described embodiment, the upper interval load value WH is multiplied by a factor of 0.6 to obtain the lower interval load Yalue WL. However, the factor may be changed according to the physical condition of the operator in formin~ the training program.
~ The above-described interval training period is followed by a cool-down period (three minutes). The cool-down period is so programmed that the load value is decreased by half every minute and finally set to zero.
Thus, one cycle of rehabilitation training has been accomplished.
As was described above, in the training device for rehabilitation according to the invention, the load control means is provided to allow the heart rate to smoothly reach the target value at a predetermined rate in l the warming-up exercise. After the target value has been reached, the load is controlled so that the target value is maintained within the predetermined range. The load value for a predetermined period is measured, and the interval training period is included in which the load is alternately increased and decreased according to the load value thus measured. Furthermore the load control means is provided so that, before the training is ended, the cool-down period is provlded to gradually decrease the load value. The load value is so controlled that the heart rate measured is compared with that measured earlier so that the difference therebetween is corrected.
Therefore the training device for rehabilitation according to the invention is considerably effective in rehabilitating the person who is attempting to regain his heaIth after heart disease.
As was described above, the rehabilitation training program is the invention has at least four training steps; warming up, automatic control, interval, and cool-down. The physical data of the operator at rest before the warming-up and those measured several times during the warming-up period are processed by the predetermined processing means so that the load control range is determined for each of the aforementioned steps.
The load is increased or decreased according to the -20- ~ 307302 1 variation of the physical data of the operator which are measured during his continuous training SQ that the physical conditions of the operator conform to the above-described rangeO Therefore in the invention, after the operator is held at rest, a relatively long warmi~g-up period is provided so that the heart rate of the operator is increased substant.ially linearly toward~ the target value during the warming-up periodc In the automatic control step, the heart rate set for the rehabllitation of the operator is maintained substantially constant and the average load value required for maintaining that heart rate i~ measured. The average load value thus measured i.s utilized in the following interval step SQ that, while the target heart rate is maintained optionally, the load i.s intermittently decreased to thereby decrease the load appIied to the legs and waistO Therefore~ the ph~sical power o.a person who has recovered, or instance, fxom heart disease can be increased with the training device of the invention~ Furthermore, the training device of the invention is so designed that the target heart rate is inputted accordir.g to the doctor's instructîon for the person who has recovered from the heart disease.
Therefore, the rehabilitation can be readily conducted at places other than rehabilitation centers.
1 according to these data. Reference is made to Canadian Patent No. 1,230,635 entitled ~sicycle Ergometer and Eddy Current srake Therefor~ and Japanese Patent Application No. 69922/1984+ entitled ~'Training Device~ which have been filed by the present applicant.
Of these conventional training devices, one is generally provided for a healthy person in which the load is automatically controlled so as to maintain the heart rate at a predetermined target value and therefore its target heart rate is high. Therefore, the training device is not suitable for a person who is being rehabilitated to restore th~ muscles of the legs and waist which has been weakened by his being confined to bed with a disease.
That is, with the training device, the warming up for allowing the heart rate to reach the target heart rate is considerably strenuous and abrupt for such a person. In addition, even after the heart rate has reached the target value, the load is increased. Thus, the conventional training device is unsuitable for those who need to be rehabilitated.
In almost all the conventional bicycle ergometers for healthy persons, the target heart rate is automatically set according to the statistical central values of past data which have been obtained separately +Published October 28, 1985; Japanese Publica~ion No. 215373/
1985.
A
~3~ 1 3073n2 1 according to ages and sexes. However, no such past data have been provided for those who have recovered from heart disease and are to be rehabilitated. Accordingly, depending on the conventional training device in wnich such past data are automatically setO it is impossible to apply even one of the target numbers of heart rates to these person. That is, the target numbers of heart xates for these persons depend greatly on their recover~
conditions or physical strengths. Accordingly, the target numbers of heart rate and the rehabilitation training fr~equencies for them should be speciied by their personal physicians and input data such as a target heart rate for the rehabilitation training should be manually înputtedO
However, in the above-described training device for healthy people, various data are automatically inputted and~ these input data are those which have been statistically determined from the past data. Therefore, in the conventional training device, it is impossible to input the data which are exactly applicable to those people~ That is~ it is impossible to correctl~
rehabilitate them with the conventional training device.
In the case of rehabilitation of a person who has recovered from heart disease, especially in the case of rehabilitation with a training device, the training itself 25 would be dangerous for the person if it were carried out -4- 1 3073n~
1 without correctly knowing the variations of his physical conditions which may occur during the training in addition to the physical conditions. There are a few facilities which can conduct the rehabilitation by correctly detecting the variations of physical conditions of a person which may occur during the exercise. Examples of such facilities are hospitals and rehabilitation c~nters where doctors are controlling the training. However, only a limited number of persons can utilize such excellent facilities.
For instance in America where the rehabilitation is conducted under such desirable conditions while being controlled by doctors, almost all the training devices are those which are designed for healthy person. Accordingly, thGse training devices are utilized with training programs for~;healthy people converted into ones for rehabilitation.
In the rehabilitation which is conducted with such a training device for those who has recovered from heart disease, the rehabilitation program is obtained merely by rearranging the training program provided for healthy people. For instance, in the case of the bicycle ergometer type training device, a target heart rate is determined in advance and the ergometer load increasing rate is so arranged that the heart rate of a rehabilitating person being trained reaches the target -5- l 3Q7 302 1 heart rate more slowly than those of a healthy person.
Therefore, the training program thus rearranged may be useful for the rehabilitation training in which the heart rate of a person being trained reaches the target value only slowly. On the other handr the fatigue of the muscles of the legs and the waist depends greatly on the physical strengths of persons to be rehabilitated. Por instance, even though the heart rate is increasing slowly according to the aforementioned load increasing rate, i.e., it is ideally reaching the target value, sometimes the fatigue of the muscles of the legs and the waist increases so much that the training cannot be satisfactorily continued.
However, the inventor believes that it is no exaggeration to say that the training device for reh~abilitation of a person who has recovered from heart disease in which the above-described difficulties have been eliminated has never been proposed in the art. There has been a strong demand for the quick development bf a training device used only for rehabilitation of such persons.
SU~MARY OF THE INVENTION
In view of the foregoing, an object of thi~
invention is to provide a training device for rehabilitationc In the train;ng device of the inventiont at least four training steps, warming-up, automatic control, interval and cool-downl are provided. Ph~sical data o~ a person to be rehabilitated who is at rest before the warming-up step and those which are measured several times during the warming-up step are processed by a predetermined processing means SQ that a load control setting range is determined for each of the trainin~
steps. According to the variation of the physical data of the person measured during continuous training, the load is increased or decreased so that the physical conditions conform to the loaa control 4etting ran~es. In this training devicej after the person is held at rest, a relatively long warming-up period is provided so that the heart rate of the person is increased substantiall~
linearly towards the target value during the warmin~-up period. In the automatic control step, the heart rate set for the rehabilitation of the person is maintained substantially constant, and the average load value required for maintaining that heart beats is measured.
The average load value is utilized in the following -7- l 30730~
l interval steps so that, while the target heart rate is maintained at an optimum value, the load is intermittently decreased thereby to reduce the load applied to the legs and the waist. Thereby the physical strength of the person who has recovered from the heart disease can be suitably increased.
BRIEF DESCRIPTION OF T~E DRAWINGS
FigO l is an explanatory diagram showing one example of a training device for rehabilitation according to this invention and the use thereof.
Fig. 2 is a block diagram of a control section in the training device shown in Fig.l.
Fig. 3 is a perspective view of a control box in the training device.
Fig. 4a and 4b are two parts of a flow chart for a description of the operation of the training device for rehabilitation according to the invention.
Fig. 5 if a time chart showing training program data in the training device according to the invention.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
One example of a training device for rehabilitation according to this invention will be described with reference to the accompanying drawings.
In Fig. l is shown a training device 10 of the invention, namely, a bicycle ergometer which loads the 1 operator with his flexing motion. The training device 10 includes a frame 1 and loading means 2 rotatably supported by the frame 1. The loading means 2 is made up of, for instance, an eddy current brake, only the essential part of which is shown in Fig. 1. The eddy current brake has been described in Japanese Patent Application No. 123171/1983 by the present applicant. Pedals 3 powered by the user rotate the loading means 2. A saddle 4 is mounted on a supporting member extended from the frame 1 in such a manner that the saddle 4 is movable vertically. In front of the saddle 4, there is provided a handle bar 5 which is fixedly mounted on a supporting member extended from t~e frame 1. An input/output box 6 is mounted in the middle of the handle 5. The input/output box 6 is used to input physical conditions (described latér~ and to output and display predetermined data. electro-cardio-potential sensors 7 (each comprising a conductive rubber electrode or an Ag/AgCl disposal electrode) are connected to one side of the input/output box 6. Installed inside the frame 1 are the aforementioned loading means 2, and, as shown in Fig. 2, a power source 8 for supplying current and voltage to various parts o~ the bicycle erogemeter and various other circuits shown in Fig. 2. These other circuits include a constant current control circuit 9, an eddy current brake +Published January 26, 1985: Japanese Publication No. 16169/
1985.
c~
1 11, a rotation sensor 12, a floating .circuit 13, an amplifier 14, a filter 15, an electro-cardio-potential waveform shaping circuit 16 and a microcomputer 2Q
(described later)O
Figc 2 shows the means or controlling the training .device for rehabilltation according to the invention, i~ec~ the bicycle ergometer 10. The cor,trolling means comprises the afoxementioned input/output box 6r an arithmetic and control unit arranged near the loadin~ means 2, and a peripheral unit related thereto. The microcomputer 20 includes an input/output unit (hereinafter referred to as "an I/O unit 21"), a central processing unit ~CPU) 22~ a ~andom access memory (RAM) 23r a read-only memory (ROM) 24, a timer lS circuit 25 and a buzzer 26 ~ ; The microcomputer 20 operates to read processin~
programs for rehabilitation out of the ROM 24. The mi.crocomputer 20 also inputs to the CPU 22 thxough the I~O
unit 21~ according to the processing program thus xead~
both data supplied from the input/output box 6 such as physical conditions (for instance a target heart rate specified by the doctor after a heart d;sease ha$ been cured) as well as signals from the electro-cardio-potehtial sensors 7 and the rotation sensor 12. The microcomputer 20 further operates to store in the RAM 23 -10~ 0 ' 302 1 various data processed by the CPU 22, to transfer the processing program for rehabilitation read out of the ROM
24 to the RAM 23, and to control the amount of load of the loading means 2 through the constant current control circuit 9 according to the processing program thus transferred. Thenr according to the data finally provided by RAM 23, the CPU 22 operates to apply predetermined data such as desired heart rate and a load value through the I/O unit 21 to the inputJoutput box 6 so that the data are 10 displayed.
Fig. 3 shows the front panel of the input/output boa 6. A display section is provided in the upper portion of the front panel for displaying the target heart rate, a range of the variable numbers of heart rates, time, a load value, a calorie value, a distance and the revolutions.
Var~ous keys for inputting various data required for rehabilitation such as physical conditions lage, sex, etc.) are provided in the lower portion of the front panel.
Now, a rehabilitation exercise carried out with the bicycle ergometer 1 thus constructed will be described with reference to Figs. 4a, 4b and 5.
~irst, the operator (or user) sits on the saddle 4 of the bicycle ergometer 1 shown in Fig. 1 and selects a desired program mode by operating the corresponding key on 1 the front panel of the input/output box 6 shown in Fig. 3.
The user then fixes the electro-cardio-potential sensors 7 on the right and left of his chest (with the reset key depressed). Thereafter, he inputs the target heart rate (TER) specified by the doctor. Now, he can start the rehabilitation by depressing the start key.
When the rehabilitation exercise is started in this manner, the desired program is read out of the ROM
24. At the same time, the timer circuit 25 coupled to the CP~ 22 starts its operation, so that pulses from the sensors 7 (with the operator at xest) are measured for abcut one minute (the current heart rate being sampled n ti~es each for m seconds for a correct value). The average heart rate per minute with an operator at rest HRo (hereinafter referred to as "the average heart rate at rest HRol'~ is obtained by averaging the heart rates thus measuredO Then the heart rate reserve HRR is obtained by . subtracting the heart rate at rest HRo from the target heart rate THR ~HRR = THR - HRo). The heart rate reserve is utilized to determine a value for Xl of 1, 2 or 3 according to the program, where a large value of X
corresponds to a large heart rate reserve.
After the measurement of the average heart rate at rest HRo and the heart rate reserve HRR have ~een determinedr the operator pedals in synchronization with -12- l 307302 l sounds produced at equal intervals; that is, the initial warming-up operation of Fig~ 5 is effected. In this case, when the heart rate of the operator exceeds the preset sum of the target heart rate THR plus fifteen (THR * 15), the buzzer 26 operates, thus warning him that he should stop the exercise. The increment of +15 is the numerical value for adjusting the sensitivity of the buzzer. For a rehabilitation exercise, the numerical value of the increment is preferably set to about ~5 thereby to increase the sensitivity of the buzzer because the user can exercise himself feeling at rest. That is, the wanning-up can be continued until the buzzer 26 operates.
In the warming-up period, the load value W of the load means 2 is controlled with a moderate rise of dw/dt =
W/~t, for instance 2w/lO sec, i.e. 0.2 watts/sec, bec~use of the initial warming-up. Further in the initial warming-up, the average heart rate HRl per minute is obtained similarly as in the case of the above-described average heart rate at rest HRo and a value Yl of l, 2 or 3 shown in the flow chart of Fig. 4a is determined. That is, the value Yl is determined according to where the average heart rate HRl is located between the heart rate at rest HRo and the target heart rate THR, with a large value of Yl corresponding to a low heart rate.
-13- 1 3n7302 l After the warming-up period of one minute has passed, the middle warming-up operation is effected for about two to four minutes. In the middle warming-up operation, the loading means 2 is controlled according to a load value which is determined by a value Zl where Zl ~
(Xl + Yl)/2 with any non-integer part disregarded, as shown in the flow chart of Fig. 4a. In the middle warming-up stage, because of the middle warming-up, the load rise rate is larger than that in the initial warming-up stage. Specifically, ~W/~t = 2w/lO sec when Zl = l, ~Wf~t = 4w/lO sec when 31 = 2, and ~W/~t = 6w/lO sec when Zl = 3.
In the middle warming-up stage also, the average heart rate HR2 is measured for the third (2 - 3) minute.
The value W is suitably corrected by utilizing the average heart rate HRz and a value JHRn where JHRn = HRo + ~THR -HRo) x (2n - l)/lO and n = l to 5. For instance, W2 = (Wl - l) when HR2 > JHR2 -~ 3, W2 = (Wl + 0) when JHR2 - 3 S
HR2 < JHR2 + 3, and W2 = (Wl ~ l) when HR2 < JHR2 ~ 3-The above-described control of the loading means 2 is carried out also for the fourth (3 - 4) minute. In the fourth minute also, the average heart rate HR3 is measured for the fourth minute. Then, it is determined whether or not the difference between thP average heart rate HR3 and the target heart rate THR is larger than ten (lO) heart -14- l 30730~. -l beats. If the difference (THR - HR3) is larger than ten (lO), then the load value is increased by lOwj and if smaller, he may continue the middle warmin~-up.
In the above-described embodiment, the difference between the average heart rate HR3 and the target heart rate THR is compared with ten (heart beats~ to determined whether or not the load should be increased by lOw.
However, the reference value may be smaller than ten, and the increment W is not limited only tQ lOw.
The third-and-fourth-minute middle warming up staye is followed by the final warmin~-up sta~e which lasts fo~ another two minutes (the fifth and sixth ~inutes).
In the final warming-up stage, the loading means 2 is controlled according to a load value W which is determined ~y the value Zl shown in the flow chart of ~ig. 4b. . In the final warming-up stage, because of the final warming-up the load rise rate is smaller than that in the middle warming-up stage; ~W3/~t = ~W2/~t when Zl =
l, ~3/~t = 3w/10 sec when Zl = 2, and ~W3/~t - 4w~10 sec when Zl = 3. In the final warming-up sta~e also, the average heart rate HR4 is measured for the fifth (4 - 5) minute. The avera~e heart rate HR4 and a value JHR4 are utili~ed to suitably correct the value W. Namely ~W4/~t =
(~W4/~t - 1) when HR4 > JHR4 + 3, AW4/~t = (~w3/At + 0~
-15- l 307302 l when JHR4 - 3 < HR4 ~ JHR4 ~ 3, and ~W~/~t = (~W3/~t + l) when HR4 < JHR4 - 3.
The control of the loading means 2 is carried out in the same manner for the sixth 55 - 6) minute. In the S sixth minute also, the average heart rate HR5 is measured.
Then, it is determined whether or not the difference between the target heart rate THR and the average heart rate HR5 (THR - HR5) is larger than ten (10) heart rate.
If the difference is larger than ten (lO), then the load value W is further increased by 10 watts, and if smaller, the operator may continue the final warming-up.
In the above-described embodiment, the difference between the average heaEt rate HR5 and the target heart rate T~R is compared with ten (heart beats) to determine whether or not the load should be increased by lO~.
However, the reference value may be smaller than ten, and the increment to W is not limited only to lOw.
Thus, the loading means 2 has been so controlled by the five-minutes warming up that it is most suitable to the user.
If, even after the warming-up, the heart rate does reach the target heart rate THR, the load value W is maintained as it is. When the heart rate exceeds the target heart rate THR, the load value is decreased by about 20%. The decrease of the load value depends on the -16- l 307302 1 physical conditions and strength of the person being rehabilitated. However it has been found through past experimental rehabilitations that, if, after the warming-up, the load means 2 is controlled with the load value determined in the final warming-up stage, the heart rate of the operator greatly exceeds the target heart rate THR.
Therefore, the decrease of the load value is so programmed that it is carried out within about two minutes after the warming-upO According, in the embodiment, with the load value W decreased by about 20%, an automatic control is carried out after the eighth minute. That is, a rehabilitation exercise is conducted for about six minutes with the heart rate being maintained equal to the target heart rate THR.
In the automatic control, the load is determined by the following expression:
~W = Gp (~HR~ HRn'_l) + Gi-~HRn' (W) where aw is the amount of adjustment of the load W, HRn' is the heart rate at the time instant tn~ ~HRnl =
HRn' - THR so that ~HRn' is the deviation, Gp is a proportional constant, TH~ is the target heart rate, Gi is an integra constant, and tS = tn ~ tn_l is the HRn sampling period. In the preferred embodiment Gp = l, Gi = 1, and ts = 20 sec. However, these values may be changed.
-17- l 307 ~02 l The automatic control rehabilitation training period described above is followed by an interval training period. For the interval training period, an average load value W~ is determined for the last five minutes of the s auto~atic control rehabilitation training period and is used as an upper reference value. A lower reference is value WL is determined as WL. = W~ x 0.6. The two reference load values WH and WL are alternately and repeatedly given for the load value W to the extent that the heart rate does not exceed the target heart rate THR.
The average load value W~ can either be measured or, more easily, be calculated from previously set values of the load W over the period of 9" to 14".
This interval training period is the most specific feature of the invention. As was described before, immediately after the heart disease has been cured, the patient's physical condition is much lower than that of a healthy person. Therefore, a warming-up exercise is suitably conducted before the rehabilitation training, the rise of the heart rate and the increase in fatigue of the muscles of the legs and the waist are liable to be unbalanced with each other. Accordin~ly, even in the case where it seems that the heart rate of the operator is much different from the target heart rate, the muscles of the feet and the waist are often greatly fatigued. Under this -18- l 3(~730~
l condition, continuation of the above-described automatic control training is not suitable fo~ the rehabilitation, and may sometimes be considerately dangerous for him.
In order to eliminate the above-described difficulties, in the invention, the interval training period is provided in the training program, so that the rehabilitation training is effectively and safely carried out with good balance kept between the rise of the heart rate and the increase in fatigue of the muscles of the legs and the waist.
In the above-described embodiment, the upper interval load value WH is multiplied by a factor of 0.6 to obtain the lower interval load Yalue WL. However, the factor may be changed according to the physical condition of the operator in formin~ the training program.
~ The above-described interval training period is followed by a cool-down period (three minutes). The cool-down period is so programmed that the load value is decreased by half every minute and finally set to zero.
Thus, one cycle of rehabilitation training has been accomplished.
As was described above, in the training device for rehabilitation according to the invention, the load control means is provided to allow the heart rate to smoothly reach the target value at a predetermined rate in l the warming-up exercise. After the target value has been reached, the load is controlled so that the target value is maintained within the predetermined range. The load value for a predetermined period is measured, and the interval training period is included in which the load is alternately increased and decreased according to the load value thus measured. Furthermore the load control means is provided so that, before the training is ended, the cool-down period is provlded to gradually decrease the load value. The load value is so controlled that the heart rate measured is compared with that measured earlier so that the difference therebetween is corrected.
Therefore the training device for rehabilitation according to the invention is considerably effective in rehabilitating the person who is attempting to regain his heaIth after heart disease.
As was described above, the rehabilitation training program is the invention has at least four training steps; warming up, automatic control, interval, and cool-down. The physical data of the operator at rest before the warming-up and those measured several times during the warming-up period are processed by the predetermined processing means so that the load control range is determined for each of the aforementioned steps.
The load is increased or decreased according to the -20- ~ 307302 1 variation of the physical data of the operator which are measured during his continuous training SQ that the physical conditions of the operator conform to the above-described rangeO Therefore in the invention, after the operator is held at rest, a relatively long warmi~g-up period is provided so that the heart rate of the operator is increased substant.ially linearly toward~ the target value during the warming-up periodc In the automatic control step, the heart rate set for the rehabllitation of the operator is maintained substantially constant and the average load value required for maintaining that heart rate i~ measured. The average load value thus measured i.s utilized in the following interval step SQ that, while the target heart rate is maintained optionally, the load i.s intermittently decreased to thereby decrease the load appIied to the legs and waistO Therefore~ the ph~sical power o.a person who has recovered, or instance, fxom heart disease can be increased with the training device of the invention~ Furthermore, the training device of the invention is so designed that the target heart rate is inputted accordir.g to the doctor's instructîon for the person who has recovered from the heart disease.
Therefore, the rehabilitation can be readily conducted at places other than rehabilitation centers.
Claims (4)
1. A rehabilitation training device in which at least four training steps, warming-up automatic control, an interval and cool-down are provided, comprising:
number-of-heart rate measuring means for detecting a heart rate of a user when he is at rest before said training steps and during said training steps;
data inputting means for freely setting a target heart rate as an exercise reference for said user;
a processing circuit for processing input data from said number-of-heart rate measuring means and said data inputting means;
an ergometer operatively connected with said user and having a load controlled by an output of said processing circuit;
warm-up control means for increasing said load of said ergometer during said warm-up step until said detected heart rate reaches said target number;
automatic control means for controlling said load of said ergometer during said automatic control step so that after reaching said target heart rate said detected heart rate is maintained within a predetermined tolerance of said target rate;
interval control means for changing said load of said ergometer during said interval control step at intervals according to an average load value of said load during a predetermined period of said automatic control period; and cool-down control means for gradually decreasing said load of said ergometer during said cool-down step following said interval control step, said warm-up control means, said automatic control means, said interval control means and said cool-down control means being included in said processing circuit.
number-of-heart rate measuring means for detecting a heart rate of a user when he is at rest before said training steps and during said training steps;
data inputting means for freely setting a target heart rate as an exercise reference for said user;
a processing circuit for processing input data from said number-of-heart rate measuring means and said data inputting means;
an ergometer operatively connected with said user and having a load controlled by an output of said processing circuit;
warm-up control means for increasing said load of said ergometer during said warm-up step until said detected heart rate reaches said target number;
automatic control means for controlling said load of said ergometer during said automatic control step so that after reaching said target heart rate said detected heart rate is maintained within a predetermined tolerance of said target rate;
interval control means for changing said load of said ergometer during said interval control step at intervals according to an average load value of said load during a predetermined period of said automatic control period; and cool-down control means for gradually decreasing said load of said ergometer during said cool-down step following said interval control step, said warm-up control means, said automatic control means, said interval control means and said cool-down control means being included in said processing circuit.
2. A rehabilitation training device as recited in Claim 1, wherein said processing circuit determines a load control setting range for each of said steps and dependent upon said input data from said heart rate measuring means increases or decreases said load of said ergometer so that said detected heart rate is maintained within said load control setting range.
3. A rehabilitation training device as recited in Claim 2, wherein said interval control means alternately changes said load between said average value and a predetermined fraction of said average value.
4. A method for controlling a rehabilitation training device including an ergometer having a variable load and operatively connected to a user and a sensor for measuring heart beats of said user, comprising the steps of:
inputting a target heart rate as an exercise reference for said user;
measuring a heart rate of said user while at rest and while training on said ergometer;
processing said target heart rate and said measured heart rate to produce a load value for said ergometer; and setting a load on said ergometer to said load value;
said processing step including:
increasing said load value during a warm-up period until said measured heart rate reaches said target number;
controlling said load value during an automatic control period so that after reaching said target value said measured heart rate is maintained within a predetermined tolerance of said target heart rate;
changing said load value at intervals during an interval training period according to an average value of said load value during said controlling step; and gradually decreasing said load value in a cool-down period following said changing step.
inputting a target heart rate as an exercise reference for said user;
measuring a heart rate of said user while at rest and while training on said ergometer;
processing said target heart rate and said measured heart rate to produce a load value for said ergometer; and setting a load on said ergometer to said load value;
said processing step including:
increasing said load value during a warm-up period until said measured heart rate reaches said target number;
controlling said load value during an automatic control period so that after reaching said target value said measured heart rate is maintained within a predetermined tolerance of said target heart rate;
changing said load value at intervals during an interval training period according to an average value of said load value during said controlling step; and gradually decreasing said load value in a cool-down period following said changing step.
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP61178470A JPS6335254A (en) | 1986-07-29 | 1986-07-29 | Training apparatus for rehabilitation |
JP178470/86 | 1986-07-29 |
Publications (1)
Publication Number | Publication Date |
---|---|
CA1307302C true CA1307302C (en) | 1992-09-08 |
Family
ID=16049068
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CA000541676A Expired - Fee Related CA1307302C (en) | 1986-07-29 | 1987-07-09 | Training device for rehabilitation |
Country Status (5)
Country | Link |
---|---|
US (1) | US4790528A (en) |
EP (1) | EP0255621B1 (en) |
JP (1) | JPS6335254A (en) |
CA (1) | CA1307302C (en) |
DE (1) | DE3765715D1 (en) |
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-
1986
- 1986-07-29 JP JP61178470A patent/JPS6335254A/en active Granted
-
1987
- 1987-03-31 US US07/032,647 patent/US4790528A/en not_active Expired - Lifetime
- 1987-07-09 EP EP87109929A patent/EP0255621B1/en not_active Expired
- 1987-07-09 CA CA000541676A patent/CA1307302C/en not_active Expired - Fee Related
- 1987-07-09 DE DE8787109929T patent/DE3765715D1/en not_active Expired - Lifetime
Also Published As
Publication number | Publication date |
---|---|
EP0255621A1 (en) | 1988-02-10 |
JPH0214056B2 (en) | 1990-04-06 |
DE3765715D1 (en) | 1990-11-29 |
JPS6335254A (en) | 1988-02-15 |
US4790528A (en) | 1988-12-13 |
EP0255621B1 (en) | 1990-10-24 |
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