FR2608929A1 - Very-long-life time infusion apparatus - Google Patents

Abstract

Infusion apparatus, with electromagnetical operation, and with very low electrical power consumption, diagrammatically represented herein below and characterised in that the kinematic assembly 1 which requires non-negligible power, is actuated by a mechanism 2 which is manually reset, and whose operation is programmed by an electronic unit 3 with very low power consumption, allowing a very long length of usage without replacement of the electrical power source 4.

Description

 Certain medical treatments require the administration of products by intravenous route, or similar, using devices usually called infusers, or syringe pumps, which the patient must be able to carry with him when traveling, when can be active despite their affection. This type of device requires a generally electrical source of energy, supplied either by an electric battery, or by a rechargeable accumulator, or in another form, and whatever the form of this energy, the patient is obliged to replace it or to recharge it periodically and if it is unable to do so, there may be serious inconveniences for his state of health.

 The device, object of the present invention, consists of an assembly of the "syringe pump" type, the energy of which is supplied to the kinematic part by a mechanical device, the "recharging" of which is manual, and the operating characteristics of which are controlled by an electronic assembly with very low consumption, itself supplied by a source of electrical energy suitable for a very long period of use; taking into account the low consumption of the electronic assembly, this source of electrical energy is of small dimensions and weight.

 This device, initially designed for outpatient treatment, has a particularly advantageous operating regime for its use in places where the supply of electrical energy sources is random.

 Figure 1 shows schematically the operating principle of the device object of the present invention: the pusher 1 for moving the piston of the injection syringe is pushed by a spring 2 which provides it with the energy necessary for this movement. This pusher 1 carries a rack 3 which ensures the rotation of a pinion 4, during the displacement of the pusher 1. The pinion 4 is the first gear of a train symbolized by 5, and terminated by the exhaust assembly 6, itself - even subject to the control system 7. The speed of advance of the syringe piston, therefore the flow rate of the product to be injected, is thus directly dependent on the information received by the device 7. The electronic assembly symbolized at 8 comprises: a electric power source 9 which donates for a very long period of its operating energy to this set, a "clock" 10 which defines a time base for the whole system, a programmer 11 which makes it possible to program the operation of the mechanical part according to the requirements of medical treatment; this programmer can advantageously be constituted by a microprocessor assembly, and may be able to include in the program, external parameters. The interface 12 transmits the orders from the pregrammateur to the device 7 for controlling the speed of the pusher 1. FIG. 2 schematically represents the mechanical assembly seen in the plane perpendicular to that of FIG. 1.

 Figure 3 shows schematically one of the preferred embodiments of the system described above, in which the spring does not act directly on the pusher 1: in fact, in the first system described, the force with which this spring acts, depends on its length; this force decreases as the pusher 1 advances. In the embodiment shown diagrammatically in FIG. 3, the pusher is driven by the rack 3, itself driven by the rotation of the onion 4 on the axis of which is placed a capstan 13 with increasing radius on which is wound a traction cable 14 whose end 15 is fixed to the spring 2. The variation of the diameter of this capstan is such that the torque exerted on the axis 19 of the pinion 4 is constant when the length of the spring 2 varies. This pusher drive system 1 has the disadvantage of exerting on the rack and pinion 3 / pinion 4 torque, an effort which makes it necessary to dimension these elements properly, and therefore to make the apparatus heavier.

 Figure 4 shows schematically a variant in which the pusher 1 is driven by a cable 16 passing over idler pulleys 17 and 18, and wound and fixed on a cylindrical capstan 20 integral with the conical capstan 13, via the axis 21. This device also makes it possible to eliminate from the movement of the pusher, the effects of the mechanical play of the rack. The capstans 13 and 20 are not necessarily conical and cylindrical respectively, but of profiles such that the torque exerted on their common axis by the pull of the cable 14 which transmits the force of the spring 2, is constant as a function of the length variations of In the case where the capstan 20 has a conicity, it must consist of two complementary elements so that the cable 16 retains a constant tension, without it being necessary to resort to a connecting spring.

 In a variant, the spring 2 can work in compression, as indicated by way of nonlimiting example, by the diagram in FIG. 5.

 Another variant shown diagrammatically in FIG. 6 consists in replacing the crumallière 3 / pinion 4 assembly with a cable device. A simple solution is to confuse axes 19 and 21.

 In the principle shown diagrammatically in FIGS. 1 and 2, the speed of movement of the pusher 1 is imposed by the exhaust device 6. This method is not limiting and can be advantageously replaced by a system with imposed angular positioning, such as a motor. "step by step" or a disk with magnetic sectors, or any other similar system, provided that in the absence of energy, the holding torque is sufficient to stop the advance of the pusher 1, the angular advance being ensured by the low energy supplied by the electronic programming unit.

 The gear train 5 must have a multiplication ratio adapted to the precision and the fineness of positioning required for the advance of the pusher 1, according to the system chosen for the device 7 and the frequency adopted to carry out this command.

 The "recharge" in mechanical energy consists in putting the spring 2 under restraint, (compression or extension), according to the mode of work chosen. This operation can be carried out, for example without this constituting limiting solutions, by rotating in the appropriate direction, either the axis 19 or the axis 21, or the common axis (Fig. 6) So that the pusher 1 is returned to its starting position without driving the gear assembly 5, a unidirectional coupler 22 is interposed between the pusher drive mechanism and the gear train 5 (fig. 2).

 In a variant shown diagrammatically in FIG. 7, the spring 2 is replaced by a barrel spring 23 driving, directly or not, the axis 19 or the common axis of FIG. 6, the traction capstan 20 being unique and consisting of two elements complementary conics as described above, to allow the traction cable to keep a constant tension without the intervention of a length adjustment system.

 Most syringe pumps have a pusher drive device, consisting of a screw. The principle of the device which is the subject of the present invention applies to this type of kinematics, as it applies to all the drive devices used, by the simple substitution of the existing motor assembly and of a consumption in excessive energy, by a mechanical winding assembly, the advancement speed of the pusher being programmed by an electronic assembly as described above. One of the preferred embodiments for this type of screw device is shown diagrammatically in FIG. 8 in which the assembly 24 represents the manual winding drive mechanism which ensures the rotation of the screw 25 driving the pusher 1, by the intermediary of a torque conversion device 26 constituted, by way of nonlimiting example, by a cable wound on two complementary cynical capstans. The rotation of the screw is controlled by an assembly which is not shown, similar to that described above.

Claims (5)

1- Device intended for infusion or injection, characterized by the fact that the mechanical part 1 which actuates the piston of the injection syringe receives the energy necessary for its movement, from a spring 2 manually put under contention, and that this movement is controlled and programmed by an electronic assembly 8. 2- Apparatus according to claim 1 characterized in that the speed of movement of the mechanism 1 is imposed by an exhaust device 6, itself controlled by the programmer 8, through the control system 7.  3- Apparatus according to claim 2 characterized in that the speed of movement of the mechanism 1 is imposed by an angular positioning system, itself controlled by the programmer 8. 4- Apparatus according to claims 1, 2 and 3 characterized in that the elements constituting the electronic assembly 8 include a microprocessor and are capable of taking into account external parameters. 5- Apparatus according to claims 1 to 4 characterized in that the spring 2 providing mechanical energy, is coupled to the mechanism 1 via a device which provides this mechanism, a constant force whatever the state spring containment 2.