DE2433637A1 - THERMOELECTRIC GENERATOR, ESPECIALLY FOR A PACEMAKER - Google Patents

Description

Indiana, Pa. / V. St. A.

Thermoelectric generator, especially for a cardiac pacemaker

The invention relates to a thermoelectric generator, in particular for a cardiac pacemaker with radioactive Energy source, but is not limited to this application.

The energy source of such a known type of cardiac pacemaker generally consists of plutonium 238, an alpha emitter. The alpha particles have a short range, but when they hit the environment they generate long-range x-rays and neutrons. The amount of radioactive material used is generally sufficient to give the pacemaker a life of about 20 years. The amount required for this in the known pacemakers of this type is 1/3 to 1/2 g PUpxA * ^ ^{s it} is desirable to reduce this amount of radioactive material through better use of energy, on the one hand to reduce the generation of hard X-rays and neutrons and on the other hand to reduce the amount high procurement costs

from

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partially save.

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In the known cardiac pacemakers of this type, the Metal wire thermopile. These have a relatively poor efficiency. As is known, have thermopiles of the solid-state type have a significantly better degree of efficiency and could thus use part of the primary energy required help save, but it has been shown that cardiac pacemakers cause relatively high mechanical shocks during use and have to withstand stresses. However, solid-state thermocouples are very brittle and fragile and can in particular withstand practically no tensile stresses. The use of pacemakers is at the risk of breakage with a thermopile of the solid state type has so far practically failed.

The invention specified in claim 1 is based on the object of specifying a thermoelectric generator, which with the smallest dimensions is better protected against the risk of breakage than before - and thus the use of a thermopile of the solid-state type in a pacemaker.

For this purpose, according to the invention, the thermopile is embedded in a medium that exerts a hydrostatic pressure on the Thermopile exercises. So when the pacemaker experiences a mechanical shock, the pre-compression of the Embedding medium counteracts the impact forces and prevents the thermopile from being damaged.

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Preferably the thermopile, the radioactive primary source and the electrical circuit for converting the of the current given off by the thermopile in pulses in one Containers embedded in the same medium. The parts of the embedding medium between the hot spot of the thermopile and the primary source, as well as between the cold spot and the container serving as a heat sink are very good thermally conductive in order to promote the necessary heat flow.

The primary source consists preferably in a known manner from a radioactive block, which is in a capsule high Strength 'is included. For this purpose, the alloy WC-222, which essentially consists of tungsten, hafnium and tantalum exists, suitable. This capsule is enclosed in a further corrosion-resistant capsule, e.g. made of platinum rhodium. Between Both capsules have a diffusion barrier (preferably aluminum oxide). The whole is in one closed basket, preferably made of tantalum.

The well-known cardiac pacemakers with a radioactive primary source have a metallic conductive housing over its entire surface, which means that it is in electrical contact with everywhere Muscles of the wearer. It has been shown that such pacemakers in some cases cause constant muscle twitching cause. This is due to the fact that the

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Current flowing through the surface of the pacemaker case activates the muscles in contact with the case. Conversely, with normal movement of the wearer, these muscles generate electrical impulses that pass through the conductive housing penetrate the pacemaker and thus disrupt its operation, making it temporarily unreliable and unstable will.

In order to combat this disadvantageous tendency, according to a further development of the invention, the pacemaker is in one metal container enclosed, which is except for a narrowly limited area with an insulator (e.g. an epoxy resin) is covered. The pacemaker can then be implanted in the body of the wearer so that the conductive Area not in contact with any muscle tissue of the wearer.

An embodiment of the invention is described below with reference to the drawing. Here are:

1 shows a partially sectioned perspective illustration of the pacemaker according to the invention;

Fig. 2 is an end view of the same with parts broken away;

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5 - 3 shows a section along the line III-III in FIG. 2;

1+ shows a longitudinal section of the power generator in the cardiac pacemaker according to FIGS. 1 to 3;

Fig. 5 is a plan view of the tensioning device for compression the embedding medium;

Figure 6 is an end view of the radioactive block holder;

7 shows an end view of the holder from the other side;

8 shows a section of the same along the line VIII-VIII in FIG. 7;

9 shows a section along the line IX-IX in FIG. Zf;

Fig. 1o is an end view of the thermopile of the hot Side forth;

Figure 11 is an end view of the thermopile from the cold Side forth;

12 shows a schematic representation of the manner of connection of the individual thermoelectric elements;

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13 is a block diagram of the pacemaker;

Fig. 1 / f. and 15 schematic representations of various

Possibilities for housing the pacemaker _t in the body of the wearer.

The cardiac pacemaker 21 shown as a whole in Figs. 1 to 3 contains a power generator 23, hereinafter referred to as a battery, printed circuits 25 and 27, solid-state electronics 29, a storage capacitor 31, a magnetic switch 33, a transformer 35 and a connection device 37 for connecting the secondary winding of the transformer 35 with a cable 39 which is attached to the heart muscle. The printed circuits 25 and 2.7 serve as a support for the battery 23. The battery 23, the components 25 to 35 are embedded in a filling compound 4I made of elastic material, which are located in an approximately ellipsoidal container Zf3. The filling compound 1+] consists mainly of a silicone rubber, which has a heat-insulating effect and reacts to pressure like a liquid, ie transfers the pressure evenly in all directions. Such a silicone rubber compound is sold under the name 2CN by Emerson-Cummings Corp. in Pittsburgh, Pa./USA. Part V? However, the filling compound, which is located between the cold end 1 + 9 of the battery 23 and the container is Zf3, aterial of good thermal conductivity ^H, namely, a silicone rubber,

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under the name ECCOSIL 1 + 952. sold by Microtechtronics Corp., Buffalo, New York. The container Zf3 is provided with a coating 50 made of epoxy resin, which leaves only a window 51 free. The silicone rubber i + 1 is a cross-linked polymer of silicon and oxygen with hydrocarbon side branches and has a large proportion of hydrogen atoms, which can absorb neutron energy through repeated collisions. The container if3 serves as a ground connection for the electrical circuit 25 to 35 and as a high-frequency shield for the pacemaker. The window 51 serves to connect the metal container to the wearer's body. The window 51 protrudes outward from the rest of the container Zf3 and lies in the same area as the insulating coating 5o, as FIG. 2 shows. For example, the pacemaker 21 has an overall length of 62.2 mm, a width of V7 »8 mm and a depth of 20.3 mm. The window 51 has a height of approximately 1.3 mm and oval dimensions of approximately if6 χ 30 mm.

The battery 23 (Fig. If) contains a primary source 61 and a thermoelectric converter 63 · The primary source 61 is enclosed in a highly evacuated housing 65, the is surrounded by a heat shield 67.

The primary source 61 contains a ceramic block 71, which is formed from plutonium oxide powder, the plutonium

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contains predominantly the isotope PUp ^ o. For example, the radioactive source consists of about 0.2.72. g P ^u PX8 ⁰ 2 ^'D i ^ese amount of fuel is sufficient to those described herein pacemaker to feed 2o years without a renewal is needed. The radioactive source initially supplies 117 milliwatts and after 20 years another 100 milliwatts. The block 71 is arranged in a holder 73 in an inner capsule 75 designed as a hollow sphere.

The holder 73 (FIGS. 7 to 9) consists of a hollow cylinder 77 with tabs 79j offset by 120 ° which protrude outward from one end, as well as also offset by 120 ° from one another and lying between the tabs 79 and pointing inward from both ends Tabs 81. The block 71 is held in place in the holder 73 by means of the tabs 81. The distance between the tabs 81 corresponds to the length of the block 71. To assembly, the tabs 81 are first bent inwards at one end; then the block 71 is inserted into the cylinder 77 , whereupon the tabs 81 at the other end of the holder are bent inwardly. The outer tabs 79 lie against the inner surface of the hollow ball 75 and serve to support the holder 73 against this hollow ball. The flaps 79 are bent inwards by about 15 ° from the 90 ° position, as shown in FIG.

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The inner capsule 75 consists of two hollow hemispheres and 85, the edges of which are provided with matching recesses and 89 so as to form a perfect sphere 75 together. The hemispheres 83 and 85 have a tolerance of about 0.25 mm. The hollow sphere is preferably made of the tantalum alloy WC-222, which has the following chemical composition: W 9.6 - 11.2%, Hf 2.2 to 2.8%, C 0.008 to 0.075%, the remainder Ta. The inner radius the hollow ball 73 is 3.2 mm and the outer radius 3.9 mm. The capsule 75 is fireproof and has a high strength so that the block 77 remains anchored in the capsule regardless of the fate of the pacemaker and even if the wearer is burned. The tantalum alloy also absorbs hard X-rays. In addition to the hard X-rays, the Pu- ^ o emits neutrons. These are largely absorbed by the silicone compound 1+].

The inner capsule 75 is enclosed in an outer capsule 91 which from a hood 93 in the form of a hemisphere with attached Cylinder and a spherical bottom 95 welded tightly to the edge of the cylinder. The hood 93 has e.g. an inner diameter of 8.03 mm and a thickness of about 0.25 mm. The bottom 95 has the same thickness and is corresponding dimensioned to seal the hood 93. The outer capsule 91 consists of the platinum-rhodium alloy Pt RH.

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It protects the primary source 61 against. Corrosion and Oxidation. A diffusion barrier 97 made of alumina of a thickness of about o, o25 mm is located between the inner and the outer capsule. This diffusion barrier prevents the two capsules 75 and 91 from alloying one another. During assembly, after the block 71 with the holder 73 has been inserted into the hemispheres 83, 85, the ball is underneath A protective gas atmosphere is welded shut and then pushed into the hood 93 of the outer capsule 91. Thereafter, the floor is 95 welded at point 99.

The unit thus formed is located in a basket 1o1, which is preferably made of tantalum. It's in the shape of a Hemisphere that merges into a hollow cylinder. The thickness of the basket 1o1 is about 0.13 nm. Near its outer At the end of the basket 1o1 is welded to the flange 1o3 of a flange socket 1o5 made of tantalum. At the handover part of the cylindrical part 1o7 of this sleeve in the flange part 1o3 is a spherical ring surface of the same radius as the spherical bottom 95 is formed. The base 95 sits on this ring surface. The cylindrical socket part 1o7 is welded to a washer 1o9 made of tantalum. The inner surface of this disc is spherical and sets the spherical ring surface of the flange 1o5 so that the disk 109 also rests against the spherical bottom 95. The disc 1o9 has an outwardly protruding edge 111.

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A disk 113 is brazed to the edge 111, which consists of the titanium alloy Ti6A1 ^ .V. A cylinder 115 made of the same alloy that - the thermo-el ectrical converter 63 is with the outer flange 117 of the disk 113 welded. The flange 117 is provided with a groove on the edge to allow the heat flow from the weld seam to the outside to restrict. The alloy Ti6A1lfV has high strength and low thermal conductivity, and is used for this reason. The weld seam at point 99 »the weld seam between the basket 1o1 and the flange 1o3 and the weld seam between the sleeve part · 1o7 and the disc 1o9 »as well the soldering point between parts 111 and 113 form seals, which prevent the entry of combustion products to the outer capsule 91 made of platinum-rhodium when the Pacemaker wearer is burned. Such products would and could react with capsule 91 destroy, after which the inner capsule 75 would also be attacked.

The evacuated housing 65 is delimited by the outer casing 121 and the cylinder 115. These parts are through one Ring 123 connected, which is also preferably made of Ti6A1 / fV consists. The jacket 121 is made of titanium and has a hemispherical end part 125, on the edge of which a cylinder is attached. Extends from the edge of the cylinder to the ring 125 a frustoconical jacket 127. The edges of the end part 125 and the conical jacket 127 are connected to one another

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welds. Behind the weld is a support ring 128, preferably made of titanium. The end portion 125 and the cone jacket 127 have a thickness of for most of their length about 0.25 mm. The cone jacket '127 is tapered at its Thickened to about 2.3 mm at the end of 129. That thickened End 129 is beveled on the outside and flattened on the inside and around the flattened area with welded to the ring 123. The ring 123 is inside with the Cylinder 115 welded. One inside the cylinder 115 The reinforcement ring 124 located is part of the welded joint between the cylinder 115 and the ring 123. The ring is provided with a circumferential groove to suppress the flow of heat from the weld seam to the outside.

The vacuum in the container 65 is maintained by a getter 131, E.g. a commercial product with the name CERALLOY ^ -0O. The getter 131 is in an annular shape Space between the cone jacket 1o7, the flange 1o3 and a cylinder 133 accommodated. The cylinder 133 'goes from the edge of the basket Io1 and is at its end with inside curved teeth 135 '. Getter 131 is from a Ring 137 made of special glass.

The heat shield 67 has a hemispherical section 1 ^ -1, a cylindrical portion I43 and a conical portion H5. The hemispherical section 1 ifI consists of

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a plurality of hemispheres 1Zf 7 made of Monel metal, which are concentric with the capsule 75 and extend between the spherical part of the basket 1 o 1 and the inner surface of the end part 125 of the shell. The hemispheres are provided with spacing depressions 1 ij-9. The cylindrical part 1 Zf3 consists of a tape which contains alternating layers of a foil 151 made of Monel metal and a glass fiber insulation 153. The film layer 151 is about 3.2 mm wide and 0.15 mm thick, while the glass fiber layer 153 is about 3.2 mm wide and 0.13 m thick. The tape is wrapped around a cylinder, which consists of the cylindrical part of the hood 93 »of the basket 1o1. and the cylinder 133. This cylindrical wrapping 1 Zf3 firmly encompasses the basket and the cylinder 133 and supports the relatively heavy primary source 71-75-91 radially so that it cannot move radially. A radial displacement of this arrangement would exert a torque on the connection point 115-123-12Zf and could damage it. So that the winding section 1 Zf3 lies firmly against the arrangement 71-75 * 91, recesses 1ZfZf are provided in the end part 125 of the jacket. The conical section 1Zf5 of the heat shield consists of a plurality of conical shells 161 which run coaxially to the cylinder II5 and are typically made of Monel metal. They each extend from the cylindrical shield 1 Zf3 to a point above the ring 123.

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The shells 161 are near the ring 123 perpendicular to the cylinder 115 bent over and held by an annular spacer 163 »which typically consists of Ti6A1ifV, held in the desired position.

The end portion 125 and the conical portion 127 are initially separated, with the support ring 128 being connected to the end portion 125 by spot welding. When assembling the housing 121, the ring 123 is welded to the end 129 of the conical section 127. The metal strip about 0.13 mm thick, which forms the holding cylinder 133 for the getter I3I, is placed around the cylindrical end of the basket Ιοί . The getter I3I and its holder 137 are inserted and the teeth 135 of the cylinder 133 are bent over. The tape is then 15I - wound Ιοί 93-153 around the cylindrical middle part 133rd The jackets 1V7 are placed on the hemispherical part of the basket Ιοί and the end part 125 of the outer jacket is then placed. The edges of the jackets 1k7 touch the cylindrical shielding ik-3 » The frustoconical jackets 16I are inserted between the spacer 163 and the end of the conical jacket 127 into the latter. The larger jackets I6IA are made of titanium with a thickness of 0.13 mm; the outer jackets I6IB are made of Monel metal with a thickness of 0.1 mm. A hose 171 from

Fiberglass insulation is wrapped around the previous jacket 161 to support the next jacket. the

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Sections 125 and 127 are then joined together, where the support ring 128 bridges the edges of these two parts. Eventually the whole thing is in one at a pressure of 1o ~ Torr evacuated chamber and welded the joint between the edges of parts 125 and 127 and post-treated in such a way that the low pressure is maintained.

The thermoelectric converter 63 is accommodated in the cylinder 115 and consists of a thermopile I8I with solid-state thermocouples, which is embedded in a medium 183 which reacts hydrostatically to pressure like a liquid, i.e. forwards the print in all directions.

The thermopile 18I contains a plurality of positively and negatively doped strips 185 and 187, which preferably consist of bismuth telluride and are embedded in a polymeric insulation (eg epoxy resin 189). A block embedded in this way is inherently shockproof and protects the thermocouple strips 185 and 187 from breakage. For example, 81 such thermal legs I85 and I87 are arranged as FIG. 9 shows. The successive negative and positive thermal legs are connected by soldering strips 191 (FIG. 12) at the hot end of the thermopile 18I and alternating pairs of positive and negative thermal legs are connected by soldering strips 193 at the cold soldering point. So the positive leg I85A and the negative leg 187A are on

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connected to the hot solder joint by a solder strip I9IA (Fig. 1o), while the negative leg I87A and the positive Leg I85B at the cold soldering point through the soldering strip 193B positive diagonally opposite each other and negative terminal strips I85C and 187C (Fig.ll) are with the Output wires 2o1 and 2o3 connected. The thermo leg pairs 185 and 187 form thermocouples which are connected in series between conductor 2o1 "and conductor 2o3.

The embedding J83 includes a disk 111 made of thermally conductive elastic material, e.g. silicone rubber with the trade name ECCOSIL 1 + 952-), which is located between the radioactive primary source 61 and the thermoelectric converter I8I, and a hollow cylinder 213 made of heat-insulating material, e.g. a rubber with the Designation SYLGARD 18 ^, which encloses the transducer! Δι, and an end plate 215 made of ECCOSIL A-952, which has a generally frustoconical rear extension on the inside. The embedding compound 211, 213, 215 serves as an axial support for the cylinder 115 and prevents the parts located in the cylinder from buckling it.

The converter 63 is assembled in cylinder II5. First the cylinder 211 is placed on the undercut disc. Then the thermopile I8I in the middle is on the Disk 211 set. Then the cylinder 213

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pushed over the thermopile 181. One preferably off Titanium existing centering disk 116 is then placed in such a way that that it covers the annular groove 217 of the disk 123. A slotted ring 219, which is also preferably made of T16AI4V exists, is coaxial with the cylinder 115 on the centering disc 216 put on. The ring 219 is elastic, but has one high restoring force. Finally, a mass of thermally conductive silicone rubber is used to form the end disk 215, typically ECCOSIL 4952, introduced into the cylindrical space between the ring 219, the disc 216 and the ring 123. Before When this mass is heat treated, a plug 231 is placed on the outer surface of the mass.

The plug 231 is preferably made of electrolytic copper and has a head 237 slotted in the middle and a main part 239 which merges into a conically tapered part. The main part 239 has a central bore which cooperates with a corresponding opening 241 in the head. In this There is a bushing 243 in the bore.

The line connections 201 and 203 are brought out centrally before the embedding compound is introduced between the slotted ring 219, the centering disk 216 and the ring 123 will. After the introduction, but before the post-treatment of the mass, the lines 201 and 203 are through the ceramic Socket 243 inserted and led out through the slot between the parts of the head 237. Then the

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Plug 231 is placed on the outer end of the heat-conducting compound, taking into account the coaxial position with respect to the cylinder 115. When the mass is heat treated, the ring 219 prevents the mass from expanding radially. After this When it hardens, the plug 231 is pressed into the mass and thus forms the source of hydrostatic pressure within the embedding material 183. The split ring 219 restricts the radial deflection of the mass, but its gap opens up to a predetermined value, which indicates the compression of the mass. The ones out on the crowd Force exerted by ECCOSIL 4952 can be up to 75 kg; however, if the thermopile 181 is resistant to elongation, is the force may only be 7.5 kg. When the annular gap has reached the desired size; becomes the crowd held in place by arms 233 of spring 235 (Fig. 5). The spring 235 consists of a sheet of titanium alloy and is, for example, about 0.13 mm thick. This spring has an annular shape Middle part 2-51, from which the arms 2 33 extend radially evenly distributed over the circumference. To attach the Plug 231 is the central part 251 with the sloping Shoulder 253 of head 237 is spot welded and arms 233 are bent around the head and connected to the thickened end portion 129 of the shell 127 by spot welding.

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The Zf3 container, which is made of commercially pure titanium, is designed in two parts. One, cover-like part has a hole 261 through which the output conductor 263 can pass of the transformer 35 · The battery 23, the printed circuits 25 and 27, the electronics block 29, in which a Integrated circuit and individual transistors are cast in epoxy resin, the storage capacitor 31> the magnetic switch 33 and the transformer 35 are initially outside of the container if3 assembled and with each other tied together. The output conductor 263 is also initially provided with a bushing 26 ^ -. This implementation contains a high frequency filter 265 made of ferrite, the electromagnetic Interference suppressed and the conductor 263 encloses. Furthermore, a ceramic insulating piece 267 is provided, into which the conductor 263 is melted in a gas-tight manner. The insulating piece 267 is in a flange tube 269 made of titanium melted down. The ferrite filter 265 is on the inside of the tube 269 fixed by means of a spring ring 271. The conductor 263 has a flexible one at its outer end Connection wire 272 connected.

After wiring the various parts , the battery 23 and the components 25 to 35 are inserted into the pot-like part of the container if3, the battery being placed on the circuit boards 25 and 27. The circuit boards 25 and 27 have an on the inner surface of the container Wb

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adapted outline. The ground connections (FIG. 13) are connected to the container 43. The feed-through arrangement 264 is pushed through the hole 261 so that the flange 273 of the tube 269 comes to lie close to the hole 261. Then the lid of the container 43 is welded to the lower part. The thermally conductive compound 47 between the cold end 49 of the battery and the container 43 is inserted through the hole 261 by means of a syringe. The mass of silicone rubber 2CN, which is used to embed the parts 23 to 35, is then injected through the hole 261. The container Zj_3 and its contents are then placed in a recipient, which is evacuated and then filled with a protective gas (argon) at a pressure of approximately one atmosphere. The protective gas penetrates the transducer 63 through the opening 24I and the passage 243 · I * ¹ the recipient, the flange 253 is welded gas-tight to the edge of the hole 261 and the protective gas atmosphere, so that the container 43 is now sealed gas-tight. The connecting wire 272 is then connected to a connecting terminal 275.

The connecting terminal 275 has the shape of a cuboid with a cylindrical bore through which the inner end 2.77 of the cardiac catheter 39 passes. A set screw 279 (FIG. 2) is driven into the clamping block 275 from the side. The head of the screw 279 is secured by means of an elastic plug 281.

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^The catheter 39 is connected by the doctor who implants the pacemaker in the body. When assembling the device 21, the catheter 39 is replaced by a pin of the same diameter. The pin is surrounded by a sewing collar 283. The fully assembled device is brought into a shape in such a way that the covered projection 51 points downwards. Then the titanium container is provided with the coating 5o made of epoxy resin and at the same time the parts 263, 272, 275 and 283, as well as the replacement pin, are encapsulated with epoxy resin 285. The pen can then be removed.

After the catheter 39 is inserted into the heart of the wearer by the surgeon was inserted, its rear end is 277 in the through The opening formed by the pin is inserted and secured by means of the screw 279. Then the plug 28I is placed on the screw head pressed on and, if necessary, closed by silicone-elastic insulation.

The electrical circuit of the device (Fig. 13) includes besides the battery 23 and the magnetic switch 33 a DC voltage converter 3o1, an amplifier 3o3 »a monostable Multivibrator 3o5, a noise-controlled switch 3o7, a multivibrator reset 3o9, a multivibrator 311 and an output stage 313

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The open circuit voltage of the battery 23 is 0.6 volts. Of the DC voltage converter 301 conducts an operating voltage therefrom from about -5A V. The amplifier 303 amplifies the at its Input terminal 3o5 occurring input signals, if this greater than 1.5 to 2.0 millivolts. At this stage the Ε waves from the heart become the pacemaker impulses and noise occurring at input 315 is amplified. The gain factor this amplifier drops rapidly when the frequency of the input noise is outside the pass band of the amplifier.

The monostable multivibrator 3o5 has two different tasks. When triggered by a signal from amplifier 3o3, it emits a square-wave pulse of o.275 seconds. It can only be started again when this time interval has expired. The operation of the pacemaker cannot be influenced from the outside during this period. The amplifier 303 remains sensitive, but the multivibrator 311 can only be reset when the monostable circuit 3o5 has completed a pulse of 0.2-5 seconds. The amplifier 3o3 remains effective so long that it can act on the noise switch 307. The second task of the monostable multivibrator 3 ° 5 is to reset the multivibrator 311.

The multivibrator 311 controls the frequency and length of the output pulses of the pacemaker 21. The multivibrator can with

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vibrate two different frequencies. One frequency is the normal pulse rate of 7o - 2 beats per minute. The other frequency is the noise frequency of 85-5 laps per minute. In both types of vibration, the pulse length is 1.1 - 0.1 milliseconds.

The output stage 313 generates the negative pulse that is applied to the Heart of the wearer is given. The cuck sub-stage 3o9 blocks the multivibrator 311 against the delivery of a pacemaker pulse. If a pulse from the monostable multivibrator 3o5 occurs because an R wave is coming back from the heart or a Pacemaker pulse is given, stage 3o9 discharges the frequency-determining capacitor of the multivibrator 311 almost completely. Every time the multivibrator 311 has been reset, wait 85o milliseconds (? o, 6 beats per minute) before it sends out the next pacemaker pulse. Every time the pacemaker 21 itself one Emits impulse, it puts itself back.

The high frequency switch 3o7 constantly monitors the output of the amplifier 3o3 · When it finds that the frequency the output pulse of the amplifier has a certain value of 15-5 Hz, it blocks the monostable stage 3o5. As a result, the reset stage 3 ° 9 is prevented from the Discharge capacitor in multivibrator 311. If the frequency-determining Capacitor is not discharged, which every-

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times occurs when the monostable stage 3o5 has its impulse of o.275 seconds, the multivibrator 311 oscillates further, but the capacitor does not discharge completely with each pulse, which brings the pulse frequency to the noise frequency increases from 85-5 beats per minute. When the magnetic switch 33 is connected to the body of the Magnet applied to the carrier is closed, the pacemaker 21 continuously emits pulses at the noise frequency.

When R-waves occur, they lock the multivibrator 311; pacemaker impulses are only generated if there are no such R waves submitted.

In the embodiment described, the pacemaker has the following properties, for example:

1. Pulse length

Nominal 1.1 milliseconds; Variation range 1, o - 1.2 milliseconds. It is a sufficiently long pulse length provided in order to always ensure that the heart goes along. However, the pulse length should not be too long, to save electrical energy. For a substantial reduction of less than 1.1 milliseconds, the required Amplitude be so large that cardiac fibrillation is caused.

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2. Pulse height

Nominal value 8 milliamps, fluctuation range J, 5 to 8.5 milliamps. This amplitude always results in an effective excitation, even if the voltage level rises after the electrode has healed. A higher amplitude of around 10 mAmp can be considered, since pacemakers with a radioactive primary source do not have to save as much energy as with a dry battery, but at such amplitudes cardiac fibrillation is possible. A lower amplitude can occasionally lead to insufficient stimulation of the heart.

3. Fundamental frequency

Nominal value 7o beats, fluctuation range 68 to 72 beats. This frequency is the most common.

Zf. Noise frequency

Nominal value 85 beats, fluctuation range 8o to 1oo beats. This is the rate at which the pacemaker operates when the noise interference is so great that it affects the normal Q-R-S complex obscure the currents of the heart. A higher frequency than the base frequency was chosen to avoid the possibility to rule out interference with the normal heart rhythm.

5. Noise cut-in frequency - about 2o Hz

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This frequency is chosen to exclude interference from all conceivable sources of noise, in particular from Microwave ovens and the like, except for a sporadic impulse that would not be a problem. The chosen one Frequency is sufficiently far below the usual mains frequencies. of 5o and 6o Hz, in particular because of the increasing Use of microwave ovens are the most likely sources of interference.

6. Magnetic switch frequency

Face value 85 strokes; Range of fluctuation 8o to. loo blows per minute. This rate is a fixed beat rate at which the pacemaker operates when a magnet moves is applied externally to the built-in magnetic switch. This allows the operation of the pacemaker to be checked from the outside because in normal operation the doctor cannot determine whether the pacemaker is working.

7. R-wave sensitivity

Nominal value - 1.75 millivolts, fluctuation range 1.5 to 2, ο millivolts. This sensitivity ensures that the R-wave will be noticed and is high enough to prevent interference from anomalous p-waves.

8. Blocking interval

Nominal value 275 RUBBISH seconds, fluctuation range 25o to 3oo Milliseconds. This electronic blocking interval begins

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either with a normal R-wave or the pacemaker pulse. It is long enough to prevent excitation pulses during the rise or fall of the P-wave this interval is critical for the stimulation of cardiac fibrillation by the pacemaker, i.e. during the T wave of normal repolarization of the heart can not Pacemaker impulse occur.

To implant the described pacemaker in the body of a wearer, the surgeon makes an incision Zfo1 (Fig.1Zf and 15) in the body of the wearer 102, preferably in the chest above the heart. The catheter is then inserted through a vein into the heart muscle Catheter inserted into the pacemaker capsule 21 and fastened there. Then the pacemaker is placed in the incision inserted so that the insulating coating 5o in contact with the pectoral muscle Zfo3 or ZfoZf, while the exposed projection 51 with a non-muscular part of the thorax, namely either the ^ ippen ifo5 (Fig. 1Zf) or the skin Zfο6 (Fig. 15).

All of the above numerical values and material information are to be regarded as non-binding guidelines only.

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Claims (1)

Patent attorney * 5 / ο O co *? - ;: j-n-chnn 22 Munich, the. ^ ^v : - ¹ - ·· / ■ "- · -5 -'3 C.536 - Dr.Hk/rie 4 * Coratomic Inc. Indiana, Pa. / V. St. A. Claims ζ I. ^ Thermoelectric generator, in particular for a cardiac pacemaker with radioactive energy source, which contains a thermopile of the solid-state type, characterized in that the thermopile (63) is embedded in a medium (183) which exerts a hydrostatic pressure on the thermopile located in the thermopile Can exercise thermocouples. 2. Generator according to claim 1, characterized in that the part (211, 215) located between the hot end (191) of the thermopile and the heat source (61) or between the cold end (193) of the thermopile and the heat sink (51) , k7) of the embedding medium consists of a material of high thermal conductivity. 3. Generator according to claim 1 or 2, characterized by a device (235) for precompressing the embedding medium and thus the thermopile. 409885/1089 l ±. Generator according to Claim 3 »characterized by a display device (219) for the applied hydrostatic pressure. 5. Generator according to claim 1, in which the energy source, the thermopile and the embedding medium are enclosed together with a pulse generator by a container, characterized in that the cavities of the container (k3) are filled by another embedding medium (kl ), which is also can transmit a hydrostatic pressure. 6. Generator according to claim 5> in which the radioactive energy source Emits neutrons, characterized in that the additional embedding medium (if1) absorbs neutrons 7. Generator according to claim 5 »characterized in that only that part (1 + 7) of the embedding medium, which is located between the container wall and the cold side of the thermopile, has good thermal conductivity properties. 8. Generator according to claim 1, characterized in that the energy source (61) mechanically with the hot side. (191) is connected to the thermopile and together with it is enclosed in a housing (65), the cavities of which are filled by the embedding medium (I83). 409885/1089 9. Generator according to claim 8, characterized in that the energy source (61) in a cylindrical heat shield (67) is included, which also prevents radial displacement of the energy source. 10. Generator according to one of the preceding claims, with a radioactive capsule as an energy source and an elongated thermopile, one end face of which faces the capsule, characterized in that the heat-conducting parts of the embedding medium between the capsule (75) and the thermopile (63) and are formed between this and the outer container (A-3) serving as a heat sink as disks (211, 215) made of rubber-elastic material. 11. Generator according to claim 1o, characterized by a an elastic disc (215) acting against each other the spring (235) supporting the container (65) of the radioactive capsule and the thermopile 12. Generator according to claim 1o or 11, characterized in that the rubber-elastic disc (215) is surrounded by a slotted bing (219) whose slot width is a measure of the hydrostatic pressure under which the embedding medium is. 4 09885/1089 13. Pacemaker with a thermoelectric generator according to the preceding claims enclosed in an electrically conductive container thereby marked that the container (if3) except for one small limited area (51) with electrically insulating Material (5o) is coated. Lj-. Generator according to one of the preceding claims radioactive energy source, characterized in that the energy source (71) in a capsule (75) made of high-strength Material is enclosed, which in turn is enclosed by a second capsule (91) made of corrosion-resistant material and that there is a diffusion barrier (97) between the two capsules to prevent an alloy of the two capsule materials. 15. Generator according to claim IZf, characterized in that the inner capsule (75) consists of the alloy WC-222 of tantalum, tungsten and hafnium, that the outer one Capsule (91) consists of a platinum-rhodium alloy and that the diffusion barrier consists of aluminum oxide. 16. Generator according to claim 15, characterized in that the second capsule (91) is in a third container ("Ιοί, 1o3, 1o9), which is pressure-tight against access 4098 85/1089 from outside gases to the second capsule is closed. 17. Generator according to claim 16, characterized in that the third container is made of tantalum. 18. Generator according to claim 13, characterized in that the exposed part (51) of the outer container (k3) is designed as a projection relative to the rest of the container * 19. Generator according to claim 18, characterized in that the insulating coating (5o) of the rest of the container part smoothly into the surface of the exposed projection (51) transforms. 20. Generator according to claim 19 »characterized in that the container (A-3) is approximately ellipsoidal and that the exposed metal part (51) »which is in contact with a non-muscular part of the wearer of the pacemaker should come, has approximately oval shape. 409885/1 089