AT400523B - MAGNETIC CEILING OD. DGL. - Google Patents

Description

AT 400 523 B

The invention relates to a magnetic blanket or the like. With a plurality of induction coils which are flat in the axial direction and which are fixed next to one another between cloths of the blanket, and with an excitation current generator which is connected to the induction coils.

Magnetic blankets of this type are used for the magnetic, therapeutic treatment of living things. A 5 patient lies on the blanket for treatment, covers himself with the blanket or moves in the immediate vicinity of the blanket, the induction coils of which are then connected to the excitation current generator in order to induce magnetic fields with the aid of which the therapeutic treatment effect is achieved.

In a known magnetic cushion of this type (DE 38 28 043 A1), the magnetic coils are connected in series and connected to a common excitation current generator. The magnetic fields induced by the individual w coils have the same polarity. The duty cycle can be adjusted to influence the therapeutic effect.

In another known device (DE 38 07 131 A1), a bed part, in particular an upper or lower bed, is provided with excitation coils, wherein the excitation currents can be adjusted with regard to their amplitude, their frequency or their duty cycle. Since the excitation coils for certain 75 parts of the body can be controlled independently of one another, localized treatment of individual parts of the body is possible.

Finally, it is known (DE 34 03 786 A1) to group adjacent induction coils into groups, the partial coils being controlled separately or in groups. For this reason, localized treatment of individual parts of the body is again possible. In order to influence the therapeutic effect, the partial coils can be controlled both in synchronous operation and operated with alternating phase-shifted and also antiphase magnetization. Despite these measures, the therapeutic effect remains limited.

The invention is therefore based on the object of avoiding these deficiencies and improving a magnetic blanket or the like. Of the type described above with simple means so that the therapeutic effect 25 can be increased noticeably.

The invention solves this problem in that adjacent induction coils in. Coil groups are combined, with each coil group being connected via a separate connecting line to the excitation current generator, which has a number of excitation current outputs, which are assigned to different coil groups in terms of circuitry, so that the excitation current generator generates a periodic excitation current, each of which has one with the successive coil groups in the longitudinal direction of the ceiling time offset compared to the respective previous coil group, which makes up a fraction of the period of the excitation current, and that the duty cycle of the periodic excitation current is adjustable.

As a result of these measures, it becomes possible to impart a wandering tendency 35 to the therapeutic magnetic field, because the periodic excitation current is supplied to the coil groups successive in the longitudinal direction of the ceiling, each with a time offset with respect to the respective previous coil group. It has been found that such magnetic traveling fields can achieve an improved therapeutic effect compared to stationary magnetic fields. Particularly favorable conditions result in this connection if the excitation current consists of a periodically repeating sequence of individual pulses, preferably rectangular pulses, and if the frequency of the repeating sequences of individual pulses is 1 to 50 Hz and a pulse duty factor of 2: 8 to 8: 2, preferably 4: 6 with four individual pulses per sequence. With these conditions you get a comparatively fast movement of the magnetic field. In order to achieve a slower movement of the traveling field, which is desirable for other applications, it can be provided in a further embodiment of the invention 45 that the frequency of the periodically repeating sequences of individual pulses is 0.5 to 10 oscillations per minute and, in the case of a rectangular pulse current, a pulse duty factor from 2: 8 to 8: 2, preferably 4: 6 for four individual pulses, and that the frequency of the individual pulses is 1 to 50 Hz and a pulse duty factor 2: 8 to 8: 2, preferably 4: 6. Since the speed of the traveling field depends on the frequency of the periodically repeating sequences of individual pulses of the excitation current, the speed of the traveling field becomes slower than that of one due to the particularly low frequency of the periodically repeating sequences of individual pulses with otherwise the same circuit and arrangement of the induction coils higher frequency for the excitation current. Since the frequency of the individual pulses in the range of each pulse sequence can be selected depending on the most favorable therapeutic influence, no impairment is to be expected in this regard.

The magnetic traveling field can be generated with the same polarity of all induction coils. However, it is also entirely possible to select the polarity of the current excitation of the individual induction coils or coil groups differently in terms of time and / or space, without relying on the wandering tendency of FIG. 2

AT 400 523 B

To have to do without magnetic fields. If the polarity is different, it is advisable to switch induction coils that are spatially adjacent to one another in opposite polarity.

The polarity of the excitation current can be changed in time with the frequency of the periodic sequences of individual pulses. However, it is also possible to change the polarity of the excitation from coil group to coil group and / or periodically over time.

In order to ensure the foldability of a magnetic blanket according to the invention, the base surface of the blanket can have the shape of an elongated rectangle, the blanket being foldable in four longitudinal sections lying one on top of the other. In this case, if the induction coils are distributed over the length in such a way that they form three spaces which are continuous over the entire width of the blanket and are evenly distributed over the length of the blanket, then the blanket can be folded in the spaces in a simple manner.

Particularly simple constructional relationships ultimately result from the fact that the connecting lines of the individual coil groups are combined to form a common cable and are led out of the ceiling for connection to an excitation current generator arranged outside the ceiling.

The subject matter of the invention is shown in the drawing, for example. 1 shows a magnetic blanket according to the invention in a partially opened top view, FIG. 2 shows the folded blanket in a side view in the direction of arrow II of FIG. 1, FIG. 3 shows the circuit arrangement of the induction coils in a simplified block diagram and FIG. 4 up to 7 different diagrams of the excitation current.

1 shows a magnetic blanket 1 in the basic form of an elongated rectangle with a length of, for example, 1.8 m and a width of 0.8 m. This magnetic blanket 1 consists of two outer cloths 2, 3, between which eight induction coils 4 to 11 are arranged in pairs in the longitudinal direction of the magnetic blanket 1 one behind the other. The induction coils 4 to 11, which are identical to one another, each have an insulated electrical conductor, which is spirally wound and is each arranged between two electrically and moisture-insulating foils 12, 13, which are preferably bonded to one another. To hold the induction coils 4 to 11 in the magnetic blanket 1, the induction coils can be glued, tacked or sewn on, for example, through seams surrounding the induction coils with which the outer cloths 2 and 3 are stitched together.

The axes of the induction coils 4 to 11 extend with a flat magnetic blanket 1 all in the same direction perpendicular to the surface of the magnetic blanket, that is perpendicular to the plane of FIG. 1. The induction coils are grouped into four groups 31 to 34, which are evenly distributed over the Distribute ceiling length. The coil group 31 with the induction coils 4 and 5 is therefore assigned to one ceiling edge 47 and the coil group 34 with the induction coils 10 and 11 to the other ceiling edge 48, while the coil groups 32 and 33 with the induction coils 6, 7 and 8, 9 between the edge coil groups 31 and 34 are located. Between the coil groups 31 to 34 there are gaps 14, 15 and 16, which extend over the entire width of the magnetic blanket 1, so that the magnetic blanket 1 can be folded in the area of these gaps 14 to 16, as shown in FIG. 1 is indicated by the dash-dotted fold lines 18 to 20. The spaces 14 to 16 result in four longitudinal sections 71, 72, 73 and 74 which lie one on top of the other in the folded state, as can be seen in FIG. 2. The connecting lines 66 to 69 of the induction coils 4 to 11 laid over the spaces 14 to 16 must accordingly be designed to be flexible.

3, the induction coils 4 to 11 are connected in series in groups, with the same winding direction, so that there is a corresponding orientation of the induced magnetic fields. As an alternative, however, it is also possible to wire so that the magnetic fields of the induction coils of a coil group are oriented differently, so that a checkerboard-like distribution of oppositely oriented magnetic fields results if a different directional excitation is provided from coil group to coil group.

In the circuit shown, however, all coils groups are excited in the same direction, as is indicated in FIG. 3 by the arrows drawn with solid lines. With an excitation directed differently from coil group to coil group, a magnetic field alignment would be achieved, as is illustrated by the dashed arrows in FIG. 3.

The coil groups 31 to 34 are connected via the connecting lines 66 to 69 to separate excitation current outputs 35 to 38 of a current pulse generator 30. The connecting lines 66 to 69 are combined to form a common cable 75 which is led out of the magnetic blanket 1 and can be connected to the current pulse generator via a detachable coupling 76. The current pulse generator housed in a closed housing 77 is operated with mains current.

As can be seen from FIG. 3, the current pulse generator 30 has a clock generator 40 which controls an excitation current generator 41. This clock generator 40 also controls a pulse generator 3

Claims (9)

AT 400 523 B tor 44, which generates individual pulses 45 with a frequency of, for example, 6 Hz and a duty cycle of 4: 6 with four individual pulses. A periodically repeating sequence 42 of individual pulses is selected by the excitation current generator 41 from the individual pulses 45 of the pulse generator 44 and passed on as excitation current 55 to the excitation current outputs 35 to 38. The frequency of the periodically repeating sequence 42 of individual pulses 45 is 0.5 to 10 oscillations per minute. This frequency of the sequences 42 of individual pulses 45 can be set on the clock generator 40. The pulse duty factor is between 2: 8 to 8: 2 and is selected on the excitation current generator 41. The periodic excitation current 55 provided at the output of the modulator circuit 46 is applied to the excitation current outputs 35 to 38 via an amplitude selector 50, 52, 56 and 59 and a pole reverser 51, 54, 58 and 61, respectively. The arrangement is such that additional time delay elements 53, 57 and 60 are provided in the connection between the modulator circuit and the excitation current outputs 36 to 38, which delay the excitation currents present at the excitation current outputs 35 to 38. To control the respective excitation current amplitudes, an amplitude control circuit 62 is provided, which is acted upon by the clock generator 40 and which controls the amplitude selectors 50, 52, 56 and 59. The time delays 53, 57 and 60 are controlled by a corresponding control device 63 for the time delay, the pole changers 51, 54, 58 and 61 in an analogous manner via a control device 64 for the pole reversal. The clocking of these circuits 63 and 64 takes place again via the clock generator 40. In addition to these switching devices 62, 63 and 64, the amplitude selectors 50, 52, 56 and 59, the time delays 53, 57 and 60 as well as the pole changers 51, 54, 58 and 61 can also be adjusted by hand. If the amplitudes and polarities of the excitation currents 55 match for the individual induction coils or induction coil groups, a temporal excitation current curve results, as is shown in FIG. 4. The time axes A, B, C and D are each assigned to the excitation current outputs 35 to 38, it being apparent that the time offset 70 of the excitation current between the successive excitation current outputs 35 to 38 corresponds to 1/4 of the total period of the excitation current. With this arrangement, this is a prerequisite for a uniform traveling field over the individual coil groups 31 to 34. Although the excitation current has square-wave pulses, this pulse shape is by no means absolutely necessary. In special applications, a sinusoidal alternating current can also prove to be advantageous. As can be seen from FIGS. 5 to 7, the current pulse generator 30 can be used to generate a variety of excitation current forms which are advantageously suitable for achieving certain therapeutic effects. 5 to 7, the time axes A to D are again assigned to the individual coil groups 31 to 34 2, the time axis separating negative and positive amplitudes from one another. Accordingly, DC pulses are provided in FIG. 5, but AC pulses are provided for the excitation currents in FIGS. 6 and 7. 1. Magnetic blanket or the like. With a plurality of flat induction coils in the axial direction, which are fixed next to each other between cloths of the blanket, and with an excitation current generator which is connected to the induction coils, characterized in that adjacent induction coils (4 to 11) in coil groups ( 31 to 34) are summarized, each coil group being connected via a separate connecting line (66 to 69) to the excitation current generator (41), which has a number of excitation current outputs (35 to 38) which are assigned to different coil groups in terms of circuitry, so that the excitation current generator (41 ) generates a periodic excitation current, which arrives at the coil groups (31 to 34) successive in the longitudinal direction of the ceiling, each with a time offset compared to the respectively preceding coil group, which makes up a fraction of the period of the excitation current, and that the duty cycle of the periodic excitation current mes is adjustable. 2. Magnetic blanket or the like. According to claim 1, characterized in that the excitation current consists of a periodically repeating sequence of individual pulses, preferably rectangular pulses, and that the frequency of the periodically repeating sequences of individual pulses is 1 to 50 Hz and a duty cycle of 2: 8 to 8: 2, preferably 4: 6 with four individual pulses per sequence. 4 AT 400 523 B 3. Magnetic blanket or the like. According to claim 1, characterized in that the frequency of the periodically repeating sequences of individual pulses is 0.5 to 10 vibrations per minute and in the case of a rectangular pulse current a pulse duty factor of 2: 8 to 8: 2, preferably 4: 6 for four individual pulses, and that the frequency of the individual pulses is 1 to 50 Hz and a pulse duty factor 2: 8 to 8: 2, preferably 4: 6. 4. Magnetic blanket or the like. According to one of claims 1 to 3, characterized in that the polarity of the current excitation of the individual induction coils (4 to 11) or coil groups (31 to 34) is different in time and / or space. 5. magnetic blanket or the like. According to claim 4, characterized in that mutually spatially adjacent induction coils (4, 5, 6) are connected in opposite polarity to each other. 6. magnetic blanket or the like. According to claim 4, characterized in that the polarity of the excitation current is changed in time with the frequency of the sequences of individual pulses. 7. magnetic blanket or the like. According to claim 4, characterized in that the polarity of the excitation from coil group to coil group (31 to 34) and / or periodically changed. 8. magnetic blanket or the like. According to one of claims 1 to 7, characterized in that the base of the blanket (1) has the shape of an elongated rectangle, that the blanket (1) in four longitudinal sections (71 to 71) is foldable one on top of the other that the induction coils (4 to 11) are arranged distributed over the length, with three continuous gaps (14 to 16) that are evenly distributed over the entire length of the blanket (1) and that the blanket is in the spaces in between are foldable. (Fig. 2) 9. magnetic blanket or the like. According to one of claims 1 to 8, characterized in that the connecting lines (66 to 69) of the individual coil groups (31 to 34) combined into a common cable (75) and for connection to an outside of the ceiling (1) arranged excitation current generator (41) are led out of the ceiling. Including 4 sheets of drawings 5