CS240299B1 - Sealer, especially hemodialysers - Google Patents

Abstract

The solution relates to a leak meter, especially for hemodialyzers. It consists in that the amplifier output is connected, firstly, via a first switch, to the input of the first analog memory, and secondly, via a second switch, to the input of the second analog memory, the output of which is connected to the non-inverting input of a differential amplifier, the output of the first analog memory is connected to the inverting input of a differential amplifier, the output of which is connected to a rectifier, the output of which is connected to one pole of a second meter, the other pole of which is grounded, the first and second switches being controlled by a timing circuit. The said meter can be used in other areas of technology without functional modifications in the final inspection of products for which leakiness is a monitored property.

Description

The invention relates to a leak meter, in particular hemodialysers. The tightness of the hemodialyser is an important parameter. It is a property characterized by the flow of gas from the blood space to the dialysate space and the external environment with a non-wetted hemodialyser and a defined pressure difference between the blood and the dialysate space. The tightness is checked at the final inspection at the hemodialyser manufacturer.

The known leak meters are designed to measure the volume of gas that has passed from the blood to the dialysate space at a defined pressure difference between the two spaces. The measurement is carried out in such a way that the blood side of the dialyser is pressurized to a defined pressure and on the dialysate side the volume of gas passed through is measured by burette bubbles or by bubbles escaping from the defined capillary.

Other leak meters measure the pressure drop on the blood side of the hemodialyser. Here, assuming a constant volume of the measuring apparatus and the filling volume, the blood pressure drop over time is proportional to the tightness value

Q = gas flow

Δρ = change, ie pressure drop over time A.t Δ t = time interval when measuring pressure change Δ p f = function expressing the dependence of gas flow Q on pressure drop

When measuring the tightness of dialysers, an important area of tightness is between 0 and 10 ml per minute at 40 kPa. In this area, the function f can be replaced by a constant with a fixed and constant filling volume of the measuring apparatus and a constant filling volume of the dialyser, ie when measuring the same type of dialyser.

The tightness measuring instruments used are designed to measure only individual pressure values over time and to determine the tightness by calculation.

The above drawback is eliminated by the leak meter, which is based on the fact that the input of the first analogue memory is connected to the output of the amplifier and the input of the second analogue memory is connected to the non-investment input of the differential amplifier.

The output of the first analog memory is connected to an inverting input of a differential amplifier, the output of which is connected to a rectifier, the output of which is connected to one pole of the second meter, the other of which is grounded, the first and second switches being controlled by a timing circuit.

The leak meter of the present invention measures the pressure drop over a period of time

Δρ_

Který t which is proportional to the tightness defined by the amount of gas Q passed through the area measured. It is especially suitable for repeated measurements of one type of hemodialyser. It is designed electronically in addition to the sensor, which ensures its accuracy, speed and reliability.

In the drawing, a block diagram of a leak meter according to the invention is shown.

The output of the pressure sensor 1 is connected to the input of the amplifier 2, the output of which is connected both through the first switch 3, the input of the first analogue memory 6, through the second switch 4 the input of the second analogue memory 7. .

The output of the first analogue memory β is connected to the inventory input of the differential amplifier 8. The output of the second analogue memory 7 is connected to the non-inverting input of the differential amplifier 8, the output of which is connected to the rectifier 11. the other pole is grounded.

The first switch 3 and the second switch 4 are controlled by the timing circuit 10. The timing circuit 10 controls the first switch 3 and the second switch 4 so that before the start of the measurement command the first switch 3 and the second switch 4 are closed and the first analogue memory 6 and the second analogue the memory 7 is connected to the output of the amplifier 2. The voltages on the first analogue memory 6 and the second analogue memory 7 are equal and the second meter 9 shows zero deflection. In this phase, the pressure on the pressure sensor 1 can be changed at will.

Upon the arrival of the start command, the first analog memory 6 takes the voltage level corresponding to the pressure at this point in time, the second analog memory 7 goes to the memorize state.

Upon expiry of the determined measurement time Δ t, the second analogue memory 7 takes a voltage sample corresponding to the pressure reading at that time, and the second meter 9 shows a voltage difference that characterizes the pressure drop reading over a given time interval.

After the time Δt has elapsed, the value of the first analogue memory 6 is overwritten with a new value, and after the next time Δt is written to the second analogue memory 7. The second gauge 9 thus shows a new leak-tightness value after each measurement time. This is until the stop command is received, when the first switch 3 and the second switch 4 are closed and the deflection of the second meter 9 drops to zero.

Said meter can be used in other fields of technology during the final inspection of the product, where the tightness is the monitored property, without functional modifications.

Claims (1)

SUBJECT Tightness meter, in particular hemodialysers, comprising a pressure sensor, an amplifier and a first meter, characterized in that the output of the amplifier (2) is connected via the first switch (3) of the input of the first analogue memory (6) and through the second switch (4). ) the input of the second analogue memory (7), the output of which is connected to the non-inverting input of the differential amplifier (8), the output of the first analogue PA of the motherboard (6) is connected to the inverting input of the differential amplifier (8). the output of which is connected to one pole of the second meter (9), the other of which is grounded, the control of the first switch (3) and the second switch (4) being provided by a timing circuit (10).