DE959211C - Electrical device with a number of output circuits for contracting the muscles - Google Patents

Description

ISSUED FEBRUARY 28, 1957

R 12701 VIII c 121g

has been named as the inventor

The invention relates to an electrical device for achieving muscle contractions with a number of output circles for the contraction of the muscles with an oscillatory current fed from at least one oscillator to the primary circuit of a transformer will.

It is known that the muscles of the human body are strengthened when they are energized Currents are excited in a suitable manner. An alternating current of certain strength creates the contraction of the muscles while a low strength current only stimulates the muscles without that they are contracted. It is also known that certain waveforms of the oscillatory current are more effective than others. A sawtooth-like waveform of the current requires a far lower voltage to contract the muscles as a sinusoidal waveform.

One also wants to treat different muscles of the body at the same time. For this there is already devices that have more than one electrical generator of which each is connected to a specific part of the body.

The invention consists in that each oscillator has a transformer with a number of cores as well as a primary winding common to these cores is assigned and each of the output circuits a secondary winding for itself

has the individual cores of the associated transformer and a current regulator each.

Various advantages are achieved through the proposed invention. It is bandelt according to the invention a simple device with only relatively few and cheap parts. Through this creates a waveform that causes muscle contraction with very little tension evokes. With the help of a single generator ίο different parts of the body can be treated be, if any of the output circuits are set to a higher or lower voltage this does not affect the voltages in the other output circuits. To the generation The muscle contraction is the electrical current going to opposite muscles alternately applied so that a back and forth movement of the body part can be achieved can.

The drawing shows schematically a preferred embodiment of the invention. For easy Understanding the invention, the drawing is divided into six units. They are dashed by Marked with rectangles. These are the following units or parts of the apparatus, ι is the input feed circuit. 2 is the control circuit. 3 and 4 are right and left vibration generators. 5 and 6 are output circles on the right and left. The feed circuit 1 receives power from the lines 7 and 8, which can be connected to an ordinary supply network. the Feed conductors 7 and 8 lead via lines 11 and 12 and via a switch 10 to an autotransformer 9. The autotransformer 9 has series windings or winding sections 13, 14 and 15. Lines 11 and 12 are connected to the ends of winding 14, which thus represents the primary winding of the autotransformer 9.

The vibration generators 3 and 4 have simple triodes 16 and 17. They are cheap and robust types of tubes. The filaments of the electron tubes 16 and 17 receive their current from the winding section 13 of the autotransformer 9 via the lines 18, 19 or 20, 21 at a voltage of 2 ¹ ZaVoIt. A motor 22 is connected to lines 11 and 12. It is energized when the switch ro is closed. The motor 22 is preferably a brushless synchronous motor with a fraction of horse power. Through the shaft 22 _a , the motor 22 rotates a cam or an eccentric disk, which is connected to switching means in the control circuit 2 of the apparatus. In the embodiment shown, the isolated cam 25 is rotated at a speed of 20 revolutions per minute. Other speeds can also be used. The contacts of a switching device S are closed or opened by the cam 25.

The switching device 6 ″ has, as shown schematically, a base plate or support bracket 26 on which a spring contact 24, which is actuated directly by the cam 25, and contacts 27, 28 and 29 are located brought into contact with the contact 27. The cam 25 is divided into sections a, b, c and D. The section α is closest to the center of rotation of the cam and allows the contact 24 to be in contact with the contact 27. Es Assuming cam 25 is moving clockwise from the position shown in the drawing, as a result, portion b of cam 25 will move contact 24 to the left out of contact with contact 27. Substantially touches the center of portion b den Contact 24, so it is brought into contact with contact 28. As the cam 25 continues to rotate clockwise, it moves the contact 24 further to the left, the contact 24 being B e movement to the left on the contact 28 transfers. At this time, the front end of section c of the cam 25 is in contact with the contact 24. The contact 28 will contact the contact 29. This contact between the contacts 28 and 29 remains until the rear end of the section c of the cam 25 is out of contact with the contact 24. Since the section d of the cam 25 then moves transversely to the end face of the contact 24, the contact 24 will move out of contact with the contact 28. If the end of the section d of the cam 25 comes out of engagement with the contact 24, it touches the contact 27. This engagement of the contact 24 with the contact 27 remains, while the section α of the cam 25 extends across the face of the contact 24 emotional. The contacts 24, 27, 28 and 29 are arranged with respect to one another and the cam 25 such that the contact 24 contacts the contact 27 for a period of time corresponding to one third of the revolution of the cam 25. Contact 24 contacts contact 28 for a time substantially equal to half the revolution of the cam. 25. The contact 28 is in engagement with the contact 29 for a time corresponding to approximately one third of the revolution of the cam 25. The arcs formed by the sections b and c represent the time periods between the non-contact of the contact 24 with the contact 27 and the contact of the contact 28 with the contact 29. They correspond to one sixth of the rotation time of the cam 25. With the switch ^ is a Group handset G connected to groups 30, 31, 32 and 33. Each group consists of four stationary contacts and one moving contact. The movement contacts of the individual groups of the hand switch G are moved simultaneously by a button 3O _0.

The right end of winding 14 of the autotransformer 9 ″ is connected to the spring contact 24 of the switch 5 via the conductor 23. The The other end of the winding 14 is connected to the filaments of the triodes 16 via the conductors 19 and 21 and 17 connected. The first, third and fourth

Contacts of switch group 31 are connected. The first and second contact of the switch group

32 are connected to each other. The first, second and fourth contacts of the switch group 33 are connected to one another. Through the line 34, the contact 29 of the switch 5 is connected to the first contact of the switch group 30 and to the second contact of the switch group 31. The line 28 'connects the contact 28 of the switch S with the fourth contact of the switch group 32. The line 37 connects the contact 27 of the switch J? with the first and second contact of the switch group 32. The third contact of the switch group 32 is connected by the line 70 to the right terminal of the winding 15 of the autotransformer 9. The movable contacts of the switch groups 30 and 31 are connected by the line 35 to .einer Leitamg 40, which leads to the left vibration generator 3 of the apparatus. The movable contact of the switch group 32 and the stationary first, third and fourth contact of the switch group 31 are connected via a line 36 to a line 41 which leads to the vibration generator 4 of the apparatus

a5 council leads. The lamps 68 and 69 are used to display the power supply to the lines 40 and 41. One terminal of each of the incandescent lamps 68 and 69 is connected to the line 40 and 41, respectively, while the other terminals are connected to a resistor 67 via a conductor 71 which is connected to the line 70 which leads to the outer terminal of the transformer winding 15.

The generation of the waveform, which is a valuable further feature of the invention Apparatus is done by the specific type of connection and mutual Arrangement of the anode and grid circles of the triodes 16 and 17. In the anode circle of the electron tube 16 there is a primary winding 38 which is connected to the line 40. In the anode circle The primary winding 39, which is connected to the line 41, is located in the triode 17 is. In the grid circles 45 and 46 of the triodes 16 and 17 are the windings 43 and 44, soft over the line 47 with the first, second and third stationary contact of the switch group

33 are connected so that when the movable contact of the switch group 33 is in its

So first, second and fourth position is located, the grid circles are connected to the left terminal of the section 14 of the transformer9.via a line48, part of the line-2o, line 21 and line 19. The windings 38 and 43 or the windings 39 and 44 are inductively coupled by the magnetic field of the transformers 75 and 76, respectively. In addition to the magnetic coupling of the windings of the anode and grid circuits, transformers 75 and 76 also serve to excite output circuits 49, 50 and 51 in output part 5 and output circuits 52, 53 and 54 in output part 6 of the apparatus. The transformers 75 and 76 each have three magnetic field paths or field pieces 77 ', 78 and 79, which are mutually so that the part 80 forms a common piece for the individual field pieces. As shown in the drawing, the windings 38, 43 and 39, 44, respectively, which are connected to the electron tubes 16 and 17, are wound on the common parts 80. The secondary windings of the output circuits 49, 50 and 51 or 52, 53 and 54 are wound on the other parts of the individual field pieces yj, 78 and 79 of the transformers 75 and 76. The output circuits feed their potentiometers 55, 56, 57 or 58, 59 and 60. Good results are obtained when the potentiometers have a resistance of approximately 2000 ohms. The special arrangement of the primary and secondary windings on the individual field pieces J ¹ J, 78 and jg of the two transformers 75 and 76 avoids a change in the current intensity in one output circuit if a potentiometer in another output circuit is set to a different value is set. The output circuits 49 to 54 are with contact sleeve pairs 61 to. 66 connected, into which the electrodes are inserted through flexible insulated conductors. If the switch in section 2 of the apparatus connects the lines 40 and 41 with the line 23, current flows in the anode circuit windings 38 and 39 of the transformers 75 and 76. A voltage is induced in the grid circuit windings 43 and 44. A prestress is created on the grids of the tubes 16 and 17. A feedback is obtained which causes the circles to vibrate and produce a current wave which is useful for stimulating the tissue and contracting the muscles in a manner very similar to that of motor nerve impulses. By suitably balancing the impedances of the anode and grid circuits, an oscillation frequency for the output currents is obtained which, according to the invention, is very close to the physiological speed of the nerve impulse 105.

The group switch G schematically shown working in conjunction with the switch 6 "such that four circuit configurations are given for four kinds of stimuli. They are a fast Intermattieren, alternate energisation ·, an oscillating intermitting and slow intermitting. If the knob is 3o _a in In its first position, as shown in the drawing, the moving contacts of switches 30 to 35 are all on the first stationary contacts, at which time contacts 27 and 29 are both connected to leads 40 and 41. When the cam rotates 25, the contact 24 delivers current to the contact 27. If the cam 25 moves the contact 24 to the left, the current is delivered from the contact 24 to the contact 28 and to the contact 29. The contacts 27 and 29 receive current intermittently are connected to lines 40 and 41. In the vibration generators of sections 4 and 4 of the apparatus

rates result in oscillations of 40 periods per minute. If the button is _a 3o in its position 2 moves, the movable contacts of the Schaltergirtuppen be gebradht 30 to 33 au ^l f -their second stationary contacts. At this time, the contact 29 is connected to the line 40 and the contact 27 is only connected to the line 41. Since the contact 24 swings backwards and forwards as a result of the rotation of the cam 25, the contacts 27 and 29 are alternately connected to the line 23. The anode circuits of the tubes 16 and 17 are alternately connected to the line 23. The three output circuits 49, 50 and 51 are energized as a group, followed by energization of the output circuits 52, 53 and 54. There is a temporal relationship between any one or more of the output circuits 49, 50 and 51 and any one or more of the output circuits 52, 53 and 54 such that the output circuits of the transformer 75 with one or more flexor muscles and the output circuits of the transformer 76 with one or more extensor muscles can be connected, so that a back and forth movement of ^a part of the body can be achieved. When the knob 30 _a is moved to its position 3, the movable contacts of the switch groups 30 reach 'to 33 to their third fixed contacts. The conductors 40 and 41 are connected to the conductor 70 by the switch groups 31 and 32. The switch group 33 also connects the filaments of the tubes 16 and 17 to the line 70 via a resistor 74 UT.d a line 48. The anode voltage is now supplied by the windings 14 and 15 of the transformer 9. A capacitor 72 with the shunt resistor 73 is connected between the line 48 and the line 47, which leads to the grid circuit windings 43 and 44. The increasing current in the anode circuit windings 38 and 39 induces a voltage in the grid circuit windings 43 and 44. The capacitor 72 is charged. With each oscillation in the oscillators, the capacitor 72 is charged to a higher value, so that the grid bias voltage supplied by the capacitor reaches a value at which the tubes are blocked and the generation of oscillations ceases. The capacitor 72 is then discharged via a shunt resistor 73, since the grid circuit winding no longer generates a charging voltage as a result of the interruption of the anode current. As soon as the pre-tensioning of the grid is sufficiently reduced, the generation of vibrations starts again. But the oscillation generation only takes a few oscillations, since the voltage induced in the lattice circle denotes the con-. capacitor charges to block the tubes again. This gives you electrical oscillation impulses of a characteristic wave shape and frequency, which you feel from the oscillation when the current is applied to parts of the body. While the oscillation current is being supplied, the neon lamps light up continuously. But in the other positions of the button 3O ₀ the neon indicator lamps only glow when there is current in the lines 40 and! 41 flows.

If the button 3O _{0 is turned} to its position 4, the movable contacts of the Schalitergruippen 30 to 33 reach their fourth stationary contacts. The switching groups 31 and 32 now connect both lines 40 and 41 to the switch contact 28. The anode current flow is now completely controlled by the contacts 24 and 28. If the cam 25 rotates at a speed of 20 revolutions per minute, the contact 24 is brought into engagement with the contact 28 at this same frequency during periods of rest between the energization periods which are of essentially the same time value. This is the slow pulse rate of the device according to the invention.

Claims (4)

PATENT CLAIMS: i. Electrical device with a number of output circuits for contracting the muscles, in the case of which an oscillating current of. at least one oscillator is fed to the primary circuit of a transformer, characterized in that each oscillator (3 and 4) has a transformer (75 or 76) with a number of cores (jj, 78, 79) and a primary winding (38 or . 39) and each of the output circuits (49, 50, 51 or 52, 53, 54) has a secondary winding on the individual cores of the associated transformer and a current regulator (55, 56, 57 or 58, 59, 60). 2. Device according to claim 1, characterized in that that the oscillators each have a three-pole tube (16 or 17) in the feedback circuit . contain the primary winding of one of the transformers in the anode circuit. (75 or 76) and the grid of which is connected to a further winding (43 or 44) which is also common to all cores of the associated transformer. 3. Device according to claim 2, characterized in that each set of the transformer cores {yy " 78, 79) consists of a number of rectangular cores which are arranged so that one side of the one core rests against one side of each of the remaining cores, wherein the primary winding (38 or 39) and the grid circular winding (43 or 44) are applied to the mutually adjacent sides of the cores, while the secondary windings. ' for the individual output circles are on the other sides of the individual cores. 4. Device according to one of claims 1 to 3, characterized in that the oscillators are controlled by a motor-driven switch (S) such that the groups of output circuits (49, 50, 51 or 52, 53, 54) are alternately excited will. 5. Device according to claim 4, characterized in that the switch (S), which is preferably a time switch, has a cam (25) and a motor (22) for rotating the cam, a movable contact ( 24) is moved back and forth by means of the cam, in such a way that alternately a first contact (27) and a second and third contact (28, 29) are successively connected to the movable contact (24), the contacts (27, 28 , 29) control the oscillators via a multi-stage switch (30/31, 32). 1 sheet of drawings G 609 616/393 8.56 (609 809 2.57)