DE102017117302A1 - Transcranial magnetic stimulation circuit, stimulator and method for generating the magnetic pulses - Google Patents

Abstract

A transcranial magnetic stimulation circuit, stimulator and method for generating the magnetic pulses. The magnetic stimulation circuit comprises: at least two choke resistors, a DC terminal, a charging circuit, a discharge circuit of the choke resistors, and a controller. The controller is connected to the control side of the electrical switch to control that the at least two throttle resistors generate magnetic pulses at the same time. The method for generating magnetic pulses comprises: overlapping the centerline of the at least two throttle resistors; and outputting the pulses from the controller to control the electrical switch whereby the choke resistors simultaneously generate magnetic pulses, causing the simultaneously generated magnetic pulses to overlap and form the magnetic pulses needed to stimulate the transcranial magnetic stimulation device. The transcranial magnetic stimulation apparatus includes a transcranial magnetic stimulation circuit and a bearing seat, wherein the reactor resistances of the transcranial magnetic stimulation circuit are located within the cavity of the bearing seat, and the center lines of all the reactor resistances overlap each other. The magnetic pulses are generated by multiple choke resistors simultaneously and are converted by the coupling technology to the magnetic stimulation pulses, whereby the pulse current of each individual choke resistor is substantially reduced, making it easier to implement miniaturization of the device.

Description

Technical area:

The present invention relates to transcranial magnetic stimulation, and more particularly to a transcranial magnetic stimulation switch, a stimulator, and a method of generating the magnetic pulses.

Technical background:

des LC Schwingungskreis bestimmt.The principle of transcranial magnetic stimulation is to generate the pulse magnetic field by the pulse current in the electrical throttle resistance. As in 1 represents, the conventional transcranial magnetic stimulator normally uses an RLC circuitry. In 1 . R are resistors, L is an inductance, C is a capacity. The power supply is AC. The working principle is as follows: the voltage of the AC power supply is increased and the waves are filtered. When the switch K1 will be closed K2 opened and the inductance C is charged quickly, and when the switch K1 is opened K2 closed and the inductance C is discharged, and the current in the choke resistor L is rapidly changed by the LC oscillation circuit, resulting in the pulse magnetic field. The width of the single pulse is determined by the period of oscillation $\text{T}\left(\text{T}=2\pi \sqrt{\text{LC}}\right)$

of the LC oscillation circuit.

According to the energy formula J _L = 0.5 × L × I ² of the choke resistances, the magnetic induction (normally, the magnetic induction intensity is a point on the center axis of the choke resistor) that of the choke resistors L To increase generated magnetic pulses, the charging voltage of the inductance C can be increased, whereby the throttle resistance can receive a large pulse current. However, too high a current can lead to a heating up of the choke resistor, which makes the isolation of the choke resistor more difficult, the charging time of the inductance C is extended, the withstand voltage of the control switch must be increased, and the conduction loss of the electrical circuit is increased. As a result, the designed device has a complicated structure, large volumes, and increased manufacturing and utility costs. It is then difficult to realize the miniaturization of the device.

Content of the invention:

The invention has for its object to provide a transcranial magnetic stimulation circuit, a stimulator and a method for generating the magnetic pulses to the o. G. Overcome disadvantages.

The task is solved by:

• -- mindestens zwei Drosselwiderstände;
• -- einen Gleichstromanschluss, der durch einen elektrischen Schalter mit den mindestens zwei Drosselwiderstände einen Ladestromkreis der mindestens zwei Drosselwiderstände bildet,
• --- einen Entladekreis der mindestens zwei Drosselwiderstände, und
• --- einen Controller, der mit der Bedienungsseite des elektrischen Schalters verbunden ist, um zu kontrollieren, dass die mindestens zwei Drosselwiderstände gleichzeitig Magnetimpulse generieren.

A transcranial magnetic stimulation circuit, wherein the magnetic stimulation circuit comprises:

• - at least two throttle resistors;
• a direct current connection which forms a charging circuit of the at least two throttle resistors by means of an electrical switch with the at least two throttle resistors,
• --- a discharge circuit of at least two choke resistors, and
• --- a controller connected to the operating side of the electrical switch to check that the at least two choke resistors generate magnetic pulses at the same time.

Preferably, the transcranial magnetic stimulation circuit further comprises first resistors whose number is the same as the number of the at least two choke resistors, the first resistors respectively connected in series with one of the at least two choke resistors to set the fixed values of the charge time and the discharge time of the at least two choke resistors It is assured that the at least two throttle resistors generate magnetic pulses at the same time.

Preferably, the discharge circuit comprises a cascade branch circuit consisting of second resistors and diodes.

• -- mindestens zwei Drosselwiderstände;
• -- einen Gleichstromanschluss, der durch einen elektrischen Schalter mit den mindestens zwei Drosselwiderstände einen Ladestromkreis der mindestens zwei Drosselwiderstände bildet,
• --- einen Entladekreis der mindestens zwei Drosselwiderstände, und
• --- einen Controller, der mit der Bedienungsseite des elektrischen Schalters verbunden ist, um zu kontrollieren, dass die mindestens zwei Drosselwiderstände gleichzeitig Magnetimpulse generieren,

das Verfahren zum Generieren Magnetimpulse umfasst:

• --- Überlappen der Mittellinie der mindestens zwei Drosselwiderstände; und
• --- Ausgeben der Impulse vom Controller, um den elektrischen Schalter zu kontrollieren, wodurch die mindestens zwei Drosselwiderstände gleichzeitig Magnetimpulse generieren, wobei die gleichzeitig generierten Magnetimpulse zur Überlagerung gebracht werden und die Magnetimpulse bilden, die für die Stimulation des transkraniellen Magnetstimulationsgeräts gebraucht sind.

A method of generating the magnetic pulses by a transcranial magnetic stimulation device, the magnetic stimulation circuit comprising:

• - at least two throttle resistors;
• a direct current connection which forms a charging circuit of the at least two throttle resistors by means of an electrical switch with the at least two throttle resistors,
• --- a discharge circuit of at least two choke resistors, and
• a controller, which is connected to the operating side of the electrical switch, in order to check that the at least two throttle resistors generate magnetic pulses at the same time,

the method for generating magnetic pulses comprises:

• --- Overlapping the center line of the at least two throttle resistors; and
• Outputting the pulses from the controller to control the electrical switch, whereby the at least two throttle resistors simultaneously generate magnetic pulses, wherein the simultaneously generated magnetic pulses are brought to overlap and form the magnetic pulses used for the stimulation of the transcranial magnetic stimulation device.

Preferably, the method further comprises controlling the frequency of the output pulses in accordance with the parameters input by the user, thereby controlling the generation frequency of the magnetic pulses.

Preferably, the method further comprises controlling the bandwidth of the output pulses in accordance with the parameters input by the user, thereby controlling the intensity of the magnetic pulses.

Preferably, the method further comprises the controller controlling the frequency of the output pulses in accordance with the parameters input by the user, thereby controlling the generation frequency of the magnetic pulses, and controlling the bandwidth of the pulses output according to the user input parameters, thereby increasing the intensity of the pulses Magnetic pulses is controlled.

Preferably, the transcranial magnetic stimulation circuit of the transcranial magnetic stimulation device further comprises first resistors whose number is the same as the number of the at least two inductor resistors, the first resistors respectively connecting in series with one of the at least two inductor resistors, the fixed values of the charging time and the discharging time of the at least two inductor resistors This ensures that the at least two throttle resistors generate magnetic pulses at the same time.

• -- mindestens zwei Drosselwiderstände;
• -- einen Gleichstromanschluss, der durch einen elektrischen Schalter mit den mindestens zwei Drosselwiderstände einen Ladestromkreis der mindestens zwei Drosselwiderstände bildet,
• --- einen Entladekreis der mindestens zwei Drosselwiderstände,
• --- einen Controller, der mit der Bedienungsseite des elektrischen Schalters verbunden ist, um zu kontrollieren, dass die mindestens zwei Drosselwiderstände gleichzeitig Magnetimpulse generieren, und
• --- einen Lagersitz, wobei der Lagersitz mit einer Kavität versehen ist, und bei der Verwendung die Kavität beim Schlaf-induzierenden Bereich des Gehirns liegt, und wobei sich die mindestens zwei Drosselwiderstände des transkraniellen Magnetstimulationsschaltkreis innerhalb der Kavität des Lagersitz befinden, und die Mittellinien aller der Drosselwiderstände miteinander überlappen, und oberhalb der mindestens zwei Drosselwiderstände in der Kavität ein Kissen vorgesehen ist.

A transcranial magnetic stimulation device, the transcranial magnetic stimulation device comprising a transcranial magnetic stimulation circuit, the magnetic stimulation circuit comprising:

• - at least two throttle resistors;
• a direct current connection which forms a charging circuit of the at least two throttle resistors by means of an electrical switch with the at least two throttle resistors,
• --- a discharge circuit of the at least two throttle resistors,
• --- a controller, which is connected to the operating side of the electrical switch to control that the at least two throttle resistors generate magnetic pulses simultaneously, and
• --- a bearing seat, wherein the bearing seat is provided with a cavity, and in use, the cavity is located in the sleep-inducing region of the brain, and wherein the at least two throttle resistors of the transcranial magnetic stimulation circuit are within the cavity of the bearing seat, and the centerlines all of the throttle resistors overlap each other, and above the at least two throttle resistors in the cavity a cushion is provided.

Preferably, the at least two throttle resistors of the transcranial magnetic stimulation circuit are concentric.

In comparison with the prior art, the present invention has at least the following two advantages: the magnetic pulses are generated by multiple choke resistors simultaneously and are converted by the coupling technology to the stimulation magnetic pulses, substantially reducing the pulse current of each choke resistor, and thus avoids that the isolation of the throttle resistance is difficult, the charging time of the inductance C is extended, the withstand voltage of the control switch must be increased, and the conduction loss of the electrical circuit is increased. It is then easier to realize the miniaturization of the device.

list of figures

• 1 is the schematic of a conventional transcranial magnetic stimulator.
• 2 FIG. 13 is a circuit diagram of a transcranial magnetic stimulation circuit according to an embodiment. FIG.
• 3 shows the structure of a transcranial magnetic stimulator according to an embodiment.
• 4 is an enlarged view of the transcranial magnetic stimulator in FIG 3 ,

Embodiment:

The present invention will be further elucidated by the figures and the embodiments.

According to 2 The transcranial magnetic stimulation circuit comprises three choke resistors L1 . L2 . L3 , a DC terminal VC, a discharge circuit of the three choke resistors L1 . L2 . L3 and a controller. The DC connection VC forms a charging circuit of the three throttle resistors L1 . L2 . L3 with the three L1 . L2 . L3 Throttling resistors through the electrical switch K , The controller is with the operating side of the electrical switch K connected to control that the three throttle resistors L1 . L2 . L3 generate magnetic pulses simultaneously. The discharge circuit comprises a cascade branch circuit consisting of second resistors R as well as diodes D consists.

The method for generating magnetic pulses comprises: overlapping the centerline of the three choke resistors L1 . L2 . L3 ; and outputting the pulses from the controller to control the electrical switch, whereby the three choke resistors simultaneously generate magnetic pulses whereby the simultaneously generated magnetic pulses are superimposed to form the magnetic pulses needed for the stimulation of the transcranial magnetic stimulation device. Further, the method includes the controller controlling the frequency of the output pulses in accordance with the parameters input by the user, thereby controlling the generation frequency of the magnetic pulses. The method may further comprise controlling the bandwidth of the output pulses in accordance with the parameters input by the user, thereby controlling the intensity of the magnetic pulses.

To solve the problem that the single choke resistor of a conventional RLC electrical circuit must have large pulse current to generate high intensity magnetic pulse, the transcranial magnetic stimulation circuit of the present invention has the following two inventive features: 1) The use of the RL electrical circuit. The single choke resistor generates magnetic pulse with certain intensity due to small pulse current. 2) The use of the coupling technology. The multiple concentric (or with overlapped centerlines) choke resistors simultaneously generate magnetic pulses. According to the principle of vector superposition of the magnetic induction, the magnetic pulse reaches the designed value after superposition at a popular point on the center line. As in the embodiment in 2 represents, assuming that after the three throttle resistors L1 . L2 . L3 Have current with the same vector, the magnetic field strength at the point H on the central axis are respectively B ₁ , B ₂ and B ₃ . The magnetic field strength at the point H after synchronous coupling is then B = B ₁ + B ₂ + B ₃ . After using the synchronous clutch technology, the pulse current used by the single choke resistor can be substantially reduced, thereby not only preventing the isolation of the choke resistor from becoming difficult, the charging time of the inductance C is extended, the withstand voltage of the control switch must be increased, and the conduction loss of the electric circuit is increased, but also that it is easier to realize the miniaturization of the device. It is understood by those skilled in the art that although in 2 When three throttle resistors are used, two or more synchronous clutch throttle resistors may be used when needed in practical application.

In the above embodiment, to assure that the three choke resistors L1 . L2 . L3 generate magnetic pulses simultaneously, the transcranial magnetic stimulation circuit further comprises three first resistors R1 . R2 . R3 , where the first three resistors R1 . R2 . R3 each with one of the three throttle resistors L1 . L2 . L3 correspondingly in series. The resistance values of the first three resistors R1 . R2 . R3 be designed so that the fixed values of the charging time and the discharging time of the three choke resistors are almost identical, which ensures that the three choke resistors L1 . L2 . L3 generate magnetic pulses simultaneously.

The transcranial magnetic stimulation circuit of the present invention and the magnetic pulse generation method of the present invention solve the series problems of conventional transcranial magnetic stimulators by the DC TMS coupling technology. The structure of the device is simplified, the power consumption is reduced, and the manufacturing cost of the devices is reduced. The present invention can be used with various mini transcranial magnetic stimulators.

3 and 4 show the structure of a typical transcranial magnetic stimulator. As in 3 and 4 1, the transcranial magnetic stimulator includes a bearing seat and a transcranial magnetic stimulation circuit. The transcranial magnetic stimulation circuit can use any of the above transcranial magnetic stimulation circuits. The bearing seat 1 is with a cavity 11 provided, and in use, the cavity 11 in the sleep-inducing region of the brain, and where all the choke resistors of the transcranial magnetic stimulation circuit are within the cavity 11 of the camp seat 1 are located, and the throttle resistors are concentric. Above the throttling resistances in the cavity 11 is a pillow 2 intended. The cushion serves to buffer the contact pressure between the head and the choke resistors to insure the comfort of the pillow. The pillow 2 is up with a protection 4 Mistake.

All choke resistors in the transcranial magnetic stimulation circuit are in a container 3 intended. The container 3 is in the middle with a hole 31 Mistake. The centerlines of all choke resistors overlap with the centerline of the hole 31 of the container 3 , The bottom of the cavity 11 The bearing seat is with an outstanding part 12 Mistake. The hole 31 of the container 3 fits the outstanding part 12 the cavity 11 , The pillow 2 extends through a magnet hole 21 ,

The bearing seat 1 uses memory foam or emulsion materials. The pillow 2 uses memory foam or emulsion materials. The protection 4 uses emulsion materials.

The o. G. Embodiments enlighten the present invention but not limited to the scope of the invention.

Claims (10)

Transcranial magnetic stimulation circuit, characterized in that the magnetic stimulation circuit comprises: - at least two throttle resistors; a direct current connection which forms a charging circuit of the at least two throttle resistors by means of an electrical switch with the at least two throttle resistors, a discharge circuit of the at least two throttle resistors, and a controller which is connected to the operating side of the electrical switch, to control that the at least two choke resistors generate magnetic pulses at the same time. Transcranial magnetic stimulation circuit according to Claim 1 characterized in that the transcranial magnetic stimulation circuit further comprises first resistors whose number is the same as the number of the at least two choke resistors, the first resistors respectively connecting in series with one of the at least two choke resistors, the fixed values of the charge time and the discharge time of the at least two Throttle resistors, thereby ensuring that the at least two throttle resistors generate magnetic pulses simultaneously. Transcranial magnetic stimulation circuit according to Claim 1 , characterized in that the discharge circuit comprises a Kaskadenabzweigkreis consisting of second resistors and diodes. Method for generating the magnetic pulses by a transcranial magnetic stimulation device, characterized in that the magnetic stimulation circuit comprises: - at least two throttle resistors; a direct current connection which forms a charging circuit of the at least two throttle resistors by means of an electrical switch with the at least two throttle resistors, a discharge circuit of the at least two throttle resistors, and a controller which is connected to the operating side of the electrical switch, to control that the at least two choke resistors simultaneously generate magnetic pulses, the method of generating magnetic pulses comprises: --- overlapping the centerline of the at least two choke resistors; and --- outputting the pulses from the controller to control the electrical switch, whereby the at least two choke resistors simultaneously generate magnetic pulses, causing the simultaneously generated magnetic pulses to overlap and form the magnetic pulses needed for the stimulation of the transcranial magnetic stimulation device. Method for generating the magnetic pulses by a transcranial magnetic stimulation device according to Claim 4 characterized in that the method further comprises controlling the frequency of the output pulses in accordance with the parameters input by the user, thereby controlling the generation frequency of the magnetic pulses. Method for generating the magnetic pulses by a transcranial magnetic stimulation device according to Claim 4 characterized in that the method further comprises controlling the bandwidth of the output pulses in accordance with the parameters input by the user, thereby controlling the intensity of the magnetic pulses. Method for generating the magnetic pulses by a transcranial magnetic stimulation device according to Claim 4 characterized in that the method further comprises the controller controlling the frequency of the output pulses in accordance with the parameters input by the user, thereby controlling the generation frequency of the magnetic pulses, and the controller controlling the bandwidth of the output pulses according to the user input parameters, whereby the intensity of the magnetic pulses is controlled. Method for generating magnetic pulses by a transcranial magnetic stimulation device Claim 4 , characterized in that the transcranial magnetic stimulation circuit of the transcranial magnetic stimulation device further comprises first resistors whose number is the same as the number of the at least two throttle resistors, wherein the first resistors in each case with one of the at least two throttle resistors in series to set the fixed values of the charging time and the discharge time of the at least two throttle resistors, whereby it is assured that the at least two throttle resistors generate magnetic pulses simultaneously. A transcranial magnetic stimulation device, characterized in that the transcranial magnetic stimulation device comprises a transcranial magnetic stimulation circuit, the magnetic stimulation circuit comprising: - at least two throttle resistors; a direct current connection which forms a charging circuit of the at least two throttle resistors by means of an electrical switch with the at least two throttle resistors, a discharge circuit of the at least two throttle resistors, a controller which is connected to the operating side of the electrical switch to control that the at least two choke resistors simultaneously generate magnetic pulses, and --- a bearing seat, wherein the bearing seat is provided with a cavity, and in use the cavity is located in the sleep-inducing region of the brain, and wherein the at least two choke resistors of the transcranial magnetic stimulation circuit are located within the cavity of the bearing seat, and the center lines of all of the throttle resistors overlap each other, and above the at least two throttle resistors in the cavity a cushion is provided. Transcranial magnetic stimulation device according to Claim 9 , characterized in that the at least two throttle resistors of the transcranial magnetic stimulation circuit are concentric.

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