HU180351B - Urological testing instrument - Google Patents

Abstract

The invention relates to a urological examination apparatus, primarily for determining the velocity of micturition and the micturition volume. It is expediently combined with a cystometer. The aim of the invention is to improve the measurement accuracy of such devices without increasing the technical complexity. The invention is based on the recognition that an increased accuracy is achievable if, instead of an immediate speed measurement, a volume measurement is initially carried out and the voiding rate is determined indirectly from the volume by forming the differential quotient after the time. According to the invention, the apparatus includes a volume signal generator unit (4) with strain gauge bridge (11), a flow measuring unit (1) with a differentiating unit (15), which is a switching stage (14) for the operating mode, which is part of a signal processing unit (3) , a filter (21) and a matching circuit (22) to a controlled by a control stage (25) Schreibgeraet (24) acted upon. In the volume signal generator unit is a urine measuring container, which is coupled via a spring arrangement with the strain gauges. The mechanical design of the device is specified in detail in the description and in the claim.

Description

Urological examination device

FIELD OF THE INVENTION The present invention relates to a urological test device, which is primarily used to determine the flow rate and volume of urine, and which is preferably incorporated into a cystometer.

During urological examinations, accurate recording of urine velocity and urinary volume is of great diagnostic value. A known solution for the direct measurement of urine rate / urine flow rate per unit time is the DF EIEKTR0NIK, a 14F42 type uroflow meter transducer. In this solution, a light, flanged disk is mounted on a shaft of a DC motor running at a constant speed, wherein the flanged disk forms a relatively small volume of storage space. Urine is led to the center of this space, which accelerates to circumferential velocity through the rim. Acceleration draws mechanical power from the DC motor proportional to the flow rate of the urine, and thus draws current j directly from the desired parameter! dependent. This solution achieves an accuracy of + 2% relative to a final value of 50 ml / sec j.

Another known solution is the 2018 uroflow cystometer of the W0LF company in the Federal Republic of Germany. Flow measurement is done by forming a pressure signal from the urine rate and then processing the pressure signal through an electrical post. The urine is led into a closed container and the pressure of the air above the liquid surface is proportional to the volume of the urine. This pressure is converted into an electrical measuring signal · The speed signal is produced by time differentiation. For this instrument, measurement accuracy is a measure of flow rate

-1180.351 genes are ± 4%, and +2% in volume.

For this instrument, the cysteometer converts the pressure signal from the catheter to the membrane inductive transducer voltage signal. The measurement accuracy is ^ 2%. I

SUMMARY OF THE INVENTION The object of the present invention is to provide a urological tester which can provide a higher measurement accuracy than the known solutions of the type mentioned, with a simple construction and easy operation.

The object of the present invention has been solved by the realization that instead of direct flow rate measurement, a more accurate result can be obtained by providing high accuracy volume measurement. The flow rate in this case is given by the time difference j of the volume measuring signal.

According to the present invention, there is provided a urological probe having a flow measurement unit and a signal processing unit connected to an output thereof having a differential unit for generating a velocity measurement signal and a volume transducer connected to the input of the flow measurement unit, and according to is characterized in that the strain built up in volume is beacon stamps measuring bridge and measuring the urine collecting container ¹ stallion, which is suspended by means of an intermediary organization I hand to the cantilevered leaf spring clamped, which is connected with the strain gauges. The tongue extends into the central opening of the leaf spring from the opposite side of the clamp, the end of which is connected via a hanging strap to the holder supporting the measuring container.

The suspended mechanical system is supported entirely by the cantilever clamped leaf spring and its deformation is converted into an electrical signal by means of strain gauges.

For proper guiding of the intermediate structure, the fixed spring tube holding the leaf spring holds a bracket that surrounds the lower parts of the suspension structure externally and has bracing plates connected to a plate connecting the lower legs of the bracket, limiting the movement of the movable bracket and a cylindrical guide pin extending through and extending from the lower connecting plate of the suspension structure.

The suspension structure is guided at the top by another central guide pin extending from the lower part of the horizontal support plate of the bracket and guiding the bracket plate attached to the bracket tube.

fits into the back.

In the urological probe of the present invention, the measuring bridge is preferably connected to a volume zero potentiometer and the output of the differentiation unit is connected via a separator amplifier to the signal input of the signal processing unit. The signal processing unit comprises a series of switching stages, filters, adapters, and line clamps connected in series, which are set by the appropriate control stage according to the measurement needs.

The urological test device of the present invention is preferably provided with an oystometer comprising a piezoelectric pressure transducer.

The accuracy of the urological test device made according to the invention is much better than known solutions of the same complexity, but it is much simpler to handle and purify.

-2180.351

The invention will now be described in more detail with reference to a specific embodiment, based on the drawing. In the drawing ^, Figure 1 is a general block diagram of the urological test device according to the invention, a

Figure 2 is a sectional side elevational view of the volume transducer, a

Figure 3 is a front view of the structure shown in Figure 2, a

Figure 4 is a front view of the transducer leaf spring, and

Figure 5 is a top view of a leaf spring.

The block diagram of the electrical units of the urological test device according to the invention is shown in Figure 1. The main parts of the instrument are filled with dashed lines in the drawing. The instrument consists of a flow measurement unit 1, a cystometer 2 and a signal processing unit 3 which processes their output signals. A 4-volume encoder is connected to the inlet of the flowmeter 1. The instrument is powered by a power supply 5 connected to each component. The volume transducer 4 comprises a urine measuring container 10 which is mechanically connected to the measuring bridge 11 formed as a pressure-voltage transducer. In the measuring bridge 11 are located four uniformly shaped strain gauges 11a _f 11b, 11c and lld. and the DC side of the metric bridge 11 is connected to the appropriate output of the power supply 5. Between these two outputs of the power supply unit 5 is a 12-volume reset potentiometer. The output of the measuring bridge 11 is connected to the differential amplifier 13 of the flow measurement unit 1 and its output is connected to the switching stage 14 of the signal processing unit 3 and to the input of the differentiation unit 15. The differentiating unit 15 generates a time differential of the volume signal applied to its input and transmits this signal to the other input of the switching stage 14 via a separating amplifier 16.

The main part of the cystometer 2 is a piezoelectric pressure transducer 17, the inlet of which is connected to the catheter tube 18 connected to the volume to be measured. The piezoelectric pressure transducer 17 consists of a piezoelectric resistance known in the art, and the setting required to reset the bridge is performed only by the potentiometer 19 shown schematically. The output of the oelectric pressure converter 17 is connected to the third input of the switching stage 14 of the signal processing unit * - θ 3 at a measuring amplifier 20. Selection inputs 20a and 20b of switching stages 14 are controlled depending on the operating mode in which the tester is to be operated. In the signal processing unit 3, the output of the switching stage 14, at which the analogue measuring signal corresponding to the selected mode can be measured, is connected to the input of the interface circuit 22 via a low-pass filter 21. The input of the adapter circuit 22 is connected to a zero position sensor 23 and its output is connected to a ruler 24. The liner 24 may be single or multi-channel training and provide a register of analog signals fed to its input. The liner 24 is controlled by a control stage 25 having three inputs for controlling start, stop, and paper speed selection.

In order to understand the operation of the urological test device of the present invention, a more detailed description of the 4-volume transducer is required.

As shown in Figure 2, the vertical axis of the measuring container 10 is shown

-3180.351 hole-top open cylinder with bottom resting on support 30 with cylindrical upper part *. The holder 30 is a lightweight plastic member having a cylindrical shell and a horizontal support plate 31 separating its interior. Feet 32 extend from the lower part of the holder 30. 2, the lower cylindrical portion of the holder 30 has a semicircular aperture through which the clamping device described below can be introduced. THE

Fig. 2 is a sectional view of the holding tube 34 of the clamping device with a slot 35 at its bottom. The legs 32 of the bracket 30 extend beyond the bottom of the bracket 34 and are connected by a plate 36 connecting the ends of the legs. In Fig. 3, it can be seen that the support tube 34 is provided with a U-shaped bracket 37 having a horizontal shaft 38 extending parallel to the wedge plate 36. One side of the bracket 37 extends from each of the abutment plates 39a and 39b, which abut the connecting plate 36 upwards. The total weight of the measuring system formed from the measuring container 10 and the holder 30 is held by a hanging strip 40 connected to the center of the connecting plate 36. The end of the hanging strip 40 is engaged by a hanging bracket 41 and the connecting plate 36 passes through its central opening. The lower end of the suspension bracket 41 is formed as a guide pin 42 and as shown in Figure 3, it passes through the central opening of the fixed leg 38, which is tapered to provide a low friction. The distance between the connecting plate 36 and the stem 38 varies depending on the volume of liquid placed in the measuring container 10. THE

3, a clamping plate 43 is attached to the center of the holding tube 34 and between the clamping plate 43 and the holding tube 34 is a leaf spring 44 as shown in Figure 4 and 5, which is clamped by the holding plate 43 to the holding tube 34. A fixed plate 45 over the clamping plate 43 bridges the structure. The bridging plate 45 has a tapered bore in the center line of the structure and is guided through a guide pin 46 secured to the support plate 31 of the support 30. The guide pins 42 and 46, while allowing vertical displacement, prevent lateral displacement of the structure. The leaf spring 44 is a 4th and 4th

Fig. 5 / made of a thin spring plate, rectangular and having an opening 47 in its center, into which the tongue 48 separated from the spring material by a cut-out extends. The upper end of the suspension strap 40 is secured to the 49 points of the tongue 48. Figure 4 illustrates the clamping section to the left of the B line. On the leaf spring 44, the strain gauges 11a, 11b, 11c and lld are located on the lower and upper faces of the two spring arms defining the opening 47.

In Fig. 3, it can be seen that the spring force 44 is exerted by the force exerted by the suspension band 40 so that the displacement of the point 49 lies in the vertical axis, suitably dimensioned.

The circuit board 50 is integrated in a common assembly with the support tube 34. comprising wires and direct serving circuits of the Ha, 11b, 11c and lld strain gauge stamps. The electric wires are routed from here via 51 flexible cables. The horizontal position of the support tube 34 relative to the stand not shown in the drawing can be precisely adjusted by means of an adjusting screw 52.

The operation of the 4-volume transducer according to the invention is as follows:

Operation is first described in the Urine Flow Rate and Volume Determination mode. At the beginning of the measurement, see Figure 10

-4180.351 is placed on the holder 30, the 4 Volume Transducer is now in its normal state. The spring-loaded stiffeners 11a, 11b, 11c and lld mounted on the leaf spring 44 are in a state corresponding to the structure's own weight, and this gauge bridge II is set using a zero-potentiometer 12 so that the gate output 11 is zero, It provides.

At the beginning of the measurement, the measuring container 10 continuously receives the amount of urine to be measured. In order to prevent the measurement from being influenced by the dynamic forces exerted by the flow, a well-formed, undercut funnel, not shown in the drawing, is used which significantly reduces the flow rate of the liquid (especially its downward component). The output signal of the measuring bridge 11 is proportional to the instantaneous value of the amount of liquid stored in the measuring container 10. The differentiating unit 15 differentiates this time-varying signal and, in a known manner, the volume ratio gives the flow rate.

The output of the separator amplifier 16 therefore provides an analog measuring signal corresponding to the desired flow rate, which is transmitted in the flow rate mode of the switching stage 14 through the filter 21 and the matching circuit 22 to the liner 24 and registers the flow rate. The control stage 25 can be used to authenticate the register.

According to our measurements, the accuracy of the flow meter thus made is better than 1% of the final rate of 50 ml / sec.

If a volume register is made, the output of the differential amplifier 13 is transmitted through the switching stage 14 to the liner 24. In multi-channel design, parallel measurement is also possible. Accuracy is more than 0.5% for volume measurement.

The cystometer 2 of the device according to the invention preferably complements the flow measuring unit 1 and, when used, makes the device capable of performing complete urological examinations. According to cystometric tests, during the test, the pressure to be measured in the catheter tube 18 is converted by the piezoelectric pressure transducer 17 into an electrical signal and this analog electrical signal reaches the switching stage 14 via the measuring amplifier 20. In its cystometric position, the output of the measuring amplifier 20 is connected to the liner 24 through the filter 21 and the matching circuit 22, and this creates a proper register.

Claims (6)

An urological test device having a flow meter unit, a signal processing unit connected to an output thereof and a volume transmitter unit connected to the input of the flow meter unit, wherein the output of the volume transmitter unit is connected to the differential amplifier input associated with the flow unit and the first input of the differential unit. on the other hand, it is connected to the input of a differentiation unit, and the output of the differentiation unit is connected to the second input of the signal processing unit, characterized in that the volume transducer / 4 / from strain gauges / 11a, 11b, 11c, lld -5180.351 consisting of a holding tank / 10 /, wherein the strain gauge stamps / 11a, 11b, 11c. lld / is mounted on either side of the bracket portion of the leaf spring clamped / 44 / mounted on two sides of the bracket portion close to the clamp / 47 / bounded by two spring stems, into the slit I / 44/47 of the leaf spring / 47 tongue facing the clamp formed and suspended by means of a measuring container / 10 / intermediate device on the end of the tongue / 48 / which is a connecting device between the measuring container / 10 / receiving bracket / 31 / in two compartments / 30 / with its legs / 32 / consisting of a plate and a tensioning strip connecting the center points of the connecting plate / 36 / »and the leaf spring / 44 / tongue / 48 / i / 40 / i, 2. The urological test device according to claim 1, characterized in that the leaf spring / 44 / is mounted on a fixed support tube / 34 / to which the support / 30 / legs / 32 / and the connecting plate / 36 / are externally influenced. - clamping bracket (37) is attached, the bracket (37) has movement stop plates (39a, 39b) of the connecting plate (36). Embodiment of the urological examination device according to claim 2, characterized in that the lower end (40) of the suspension band (40) is connected to the connecting plate (36) via a suspension bracket (41) and has a lower end (42) formed through a guided bore through the fixed leg / 37 / horizontal leg / 38 /. An embodiment of the urological tester according to claim 3, characterized in that a support plate (45) extending over the support tube (34) and the leaf spring (44) is provided with a central guide hole. a central guide pin / 46 / extending from the underside of the bracket / 30 / support plate / 31 / through a hole in the central guide bar 45 / The urological tester according to claim 1, characterized in that the measuring bridge / 11 / is connected to a volume reset potentiometer / 12 / and the output of the differentiating unit / 15 / is via a separating amplifier / 16 / to the signal processing unit / 3. / connected to its second input and in the signal processing unit / 3 / switching stage Λ4 /, a filter connected to its output / 21 /, an interface circuit connected to its output / 22 / and a ruler / 24 / connected to it, a controller input is connected to control stage / 25 /. 6. The urological test apparatus of claim 1, further comprising a cystometer / 2 / connected to a third input of the signal processing unit / 3 /, having a catheter tube 18 for receiving the pressure to be measured, a piezoelectric pressure transducer 17 and it has a measuring force connected to its output / 20 /.