DE3634725A1 - Dosing pump, e.g. for insulin - Google Patents

Abstract

Dosing pump for drugs, e.g. insulin, with a variable-volume storage chamber for the liquid to be dosed, and a control element for determining a desired basal quantity, with a hydraulic system consisting of two chambers connected to each other via a throttle device serving as the control element, and a spring drive being non-positively connected to the storage tank via a second chamber.

Description

Dosing pumps have the task of a certain amount of liquid in the Output time unit. It is often in the medical field in particular required z. B. in diabetes melitus a certain daily To deliver a lot of insulin to the patient.

To avoid inserting a hypodermic syringe several times a day Numerous pumps to be carried externally have already been developed constantly a certain amount of insulin in the body as a "basal rate" inject. This type of even supply of the body with insulin also corresponds much more to the natural function of the pancreas.

Since the human body, however, after each food intake additional If insulin is required, such a metering pump should also be an option offer to inject additional "bolus amounts" as needed.

The pumps developed so far, which have both functions, even with electronic programming, but are prohibitively expensive and prone to failure due to their complicated structure.

The object of the invention is to be as simple and reliable as possible To create dosing pump that can also be operated by any layperson.

Dosing pumps usually consist of a reservoir with a variable one Volume for the liquid to be dosed, e.g. B. in the form of a piston pump or a diaphragm pump, which is driven by a drive z. B. an electric motor via a control element z. B. a reduction gear is driven.

According to the invention, a system consisting of two chambers ( 6 and 7 ) is provided as the control element ( 4 ), the chambers ( 6 and 7 ) being connected to one another via a throttle device ( 5 ). The drive ( 3 ) is one or more drive springs ( 8 ) which are non-positively and / or positively connected to one of the chambers, the "drive chamber" ( 7 ). The throttle device ( 5 ) can consist of one or more very fine bores in a most specialized manner.

Since the hydraulic fluid ( 11 ) from the drive chamber ( 6 ) is pressed into the second chamber ( 7 ) through the bores (throttle device 5 ) during the dosing process, the reservoir ( 1 ) must be refilled or emptied after emptying full be replaced. The hydraulic fluid ( 11 ) must also get back into the drive chamber. According to the invention, it is proposed to combine the two chambers ( 6 and 7 ) with the throttle device ( 5 ) to form a symmetrically arranged assembly which, conversely, with exchanged functions, is reinserted into the housing ( 12 ).

This eliminates the need to push the hydraulic fluid ( 11 ) back into the drive chamber ( 6 ), which is normally only possible via a bypass valve for reasons of time. This point is of the greatest importance, since a bypass valve arranged between the chambers ( 6 and 7 ) in the event of a failure would lead to a sudden injection of a much larger amount of insulin. This could result in the patient's death.

A simplification according to the invention consists in designing the two chambers ( 6 and 7 ) as flat, circular membrane boxes and arranging them on both sides on a central plate ( 13 ). The middle plate ( 13 ) also carries the connecting bore as a throttle device ( 5 ).

According to the invention, a particularly simple method for delivering additional bolus amounts is to support the storage container ( 1 ) on an adjustable counter bearing ( 9 ). It is also recommended to make the counter bearing ( 9 ) adjustable, e.g. B. by means of a jack drive.

Due to the gradual adjustment of the counter-bearing ( 9 ), an additional amount of the storage container ( 1 ) is pressed out of the storage container ( 1 ) in accordance with the size and number of steps, regardless of the time dosage of the insulin.

Fig. 1 and Fig. 2 show an example embodiment of a dosing pump according to the Invention, in which case a particularly flat design is important. Fig. 1 shows the pump at the beginning of its function. Fig. 2 shows the pump after about a third of its operating time.

The housing ( 12 ) has a lower screw cover ( 14 ) and an upper screw cover ( 15 ). When the screw cap ( 14 ) is open, the control element ( 4 ), in this case a membrane-shaped chamber ( 6 and 7 ) and the central plate ( 13 ), which has a bore ( 5 ), can be inserted into the housing ( 12 ). The chambers ( 6 and 7 ) have stable pressure plates ( 17 ), which ensure a uniform transmission of the resulting actuation pressures. The spring ( 8 ), which is supported on the screw cap ( 14 ), acts on the pressure plate ( 17 ) of the drive chamber ( 6 ).

After removing the upper cover ( 15 ), the storage container ( 1 ) can be inserted from the upper side. It is filled with the liquid ( 2 ) to be metered, which emerges from the capillary ( 16 ) when the storage container ( 1 ) is squeezed under the pressure of the pressure plate ( 17 ) of the chamber ( 7 ).

In Fig. 2 it can be clearly seen that the chamber ( 7 ) is already about a third full, and the reservoir ( 1 ) squeezed together and the corresponding amount of the liquid to be metered ( 2 ) injected through the capillary ( 16 ) has been.

When preparing the dosing pump, after inserting the storage container ( 1 ), the upper cover ( 15 ) is screwed into the housing ( 12 ) until the first drops emerge from the capillary ( 16 ). The pump is now ready for use.

If an additional bolus amount is to be injected after a certain time, the upper cover ( 15 ), which is a counter bearing ( 9 ) with respect to the storage container ( 1 ), is screwed further into the housing ( 12 ) via the ratchet drive ( 10 ). As a result, the storage container ( 1 ) is compressed by a certain height and, accordingly, a bolus quantity is injected via the capillary ( 16 ). The ratchet drive ( 10 ) engages with a ratchet tooth ( 18 ) in a circumferential toothing ( 19 ) in the upper cover ( 15 ).

The angular movement of the ratchet drive ( 10 ) is limited by corresponding savings in the housing ( 12 ). A detent spring ( 20 ) allows the ratchet tooth ( 18 ) to snap into the next tooth when the ratchet drive is returned. Fig. 5 shows such a ratchet drive ( 10 ). The actuating webs ( 28 ) protrude from the housing ( 12 ) and can be easily pivoted by hand.

Fig. 3 illustrates another variation in the shape of a long, narrow cylinder is. Corresponding parts of this second variant are shown in Fig. 1 and Fig with the same numbers. 2 designates.

In this case, the storage container ( 1 ), which is filled with the liquid ( 2 ) to be metered, is shown in the form of a small bottle which is closed at the open end by a piston ( 21 ). The control element ( 4 ) is also designed as a tube in which the drive piston ( 24 ) and the actuating piston ( 23 ) slide. The spring ( 8 ) presses constantly on the drive piston ( 24 ), which supplies the hydraulic fluid speed ( 11 ) through the bore ( 5 ) to the chamber ( 7 ). The actuating piston ( 23 ) presses the piston ( 21 ) into the reservoir ( 1 ) via the intermediate piece ( 22 ) and causes the outflow z. B. insulin. Of importance are the contact surfaces ( 25 ) in the housing ( 12 ) on which the entire control element ( 4 ) is supported.

Also in the construction according to Fig. 3, the control member (4) is designed as a symmetrically constructed unit, so that after overflow of the liquid (11) from the chamber (6) into the chamber (7) by removing and inverted insertion of the control element, the Dosing pump is ready for operation again. In this embodiment too, an additional amount of insulin can be pressed out of the reservoir as a bolus amount by screwing in the counter bearing ( 9 ) with the fine thread ( 27 ).

FIG. 4 shows a further variant of the embodiment in FIG. 3. In this case, to reduce the overall length, the chambers ( 6 and 7 ) are U-shaped as a symmetrical part. After removing the cover ( 14 ), the function of the chambers ( 6 and 7 ) can also be reversed in this case by interchanging them in the housing ( 12 ). All other functions are as described in Fig. 3.

The two exemplary embodiments described clearly show the extreme Simplification and operational safety of such an insulin pump. The great danger of an overdose is completely excluded. Self if one of the pressure chambers were to leak, it would only happen leakage of the harmless hydraulic fluid.

The interposition of a separate control element ( 4 ) with a hy draulic liquid ( 11 ) z. B. distilled water or a similar liquid with defined, unchangeable properties, brings additional operational safety, which is not given with a direct throttling of the insulin in capillaries.

Of course, the exemplary embodiments are in no way limiting. They only serve to explain the inventive concept, but give also includes further details according to the invention.

Claims (5)

1. dosing pump, e.g. B. for insulin, consisting of a reservoir ( 1 ) with variable volume for the liquid to be metered ( 2 ), a drive ( 3 ) for operating the metering pump and a control element ( 4 ) for determining a desired amount of basal, characterized in that as Control element ( 4 ) is a hydraulic system consisting of two chambers ( 6 and 7 ) connected to each other via a throttle device ( 5 ), the driven chamber ( 6 ) of which has one or more drive springs ( 8 ) acting as a drive ( 3 ) serve, is non-positively connected and the second chamber ( 7 ) is non-positively connected to the reservoir ( 1 ). 2. Dosing pump according to claim 1, characterized in that the chambers ( 6 and 7 ) with the throttle device ( 5 ) are combined to form a symmetrically arranged assembly and are interchangeable in their function. 3. Dosing pump according to claim 2, characterized in that the chambers ( 6 and 7 ) are designed as membrane boxes and are arranged on both sides of a rigid central plate ( 13 ) which also contains bores serving as a throttle device ( 5 ). 4. Dosing pump according to claim 1, characterized in that the reservoir ( 1 ) is supported by an adjustable counter bearing ( 9 ). 5. Dosing pump according to claim 4, characterized in that the counter bearing ( 9 ) in stages, for. B. is adjustable by means of a ratchet drive ( 10 ).