DE29506500U1 - Measuring device for determining urine flow for urological examinations - Google Patents

Description

Measuring device for determining urine flow for urological examinations

The invention is used to record the characteristics of urine flow in urological diagnostics. The methods commonly used for this are the flow measurement method and the weighing method.

Flow systems can be installed directly in a toilet bowl, as they do not require a collecting tank. Dynamic pressure, torque, angular velocity, angular acceleration, braking deceleration or similar physical quantities are generated and converted mechanically or into the electrical quantities voltage, current or power and fed to a corresponding evaluation system as measured quantities.

According to DE-OS 35 41 649, a urine flow measuring device for urological examinations is known which has an inlet funnel that can be hung in a toilet bowl, below whose outlet opening there is a rotating centrifuge element with driver elements arranged on the upward-facing surface in the form of ribs, grooves or the like. The centrifuge element is coupled to an electric motor via a drive shaft and rotates at high speed during the measurement. As a result, the urine flow hitting the centrifuge element axially is accelerated tangentially up to the rotational speed of the electric motor until it leaves the centrifuge element radially. Due to the proportionality between the mass flow of urine and the power to be provided by the motor at a constant speed, the current absorbed by the motor can be recorded as a measurement variable for the torque acting on the drive shaft. Using suitable devices such as printers, writers or plotters, the current urine flow values, the average values per unit of time and the integrated current urine flow values characterizing the total urine volume are made available to the doctor as evaluable data. The known solution can be used in basic medical care due to its relative simplicity, especially since it allows measurements to be taken on both male and female patients and helps to avoid psychogenic measurement distortions due to its location of application, i.e. directly in the toilet.

The disadvantage of the known solution is the application of the flow measurement principle, since measurement inaccuracies can occur due to flow conditions that cannot be calibrated in advance. Another disadvantage of the known

The disadvantage of a urine flow meter is the technical and aesthetic-hygienic effort required to supply power to the motor in the toilet bowl during the measurement and to connect it to the evaluation device, as well as the necessary seals and cleaning of the device. The reasons for this are the need to remove and clean the entire measuring device by hand after each measurement, as contact between the electrical components and the urine flow is possible or can only be avoided with increased effort. Therefore, the patient frequency is limited or the examination costs are increased, as either a complete cleaning of the device after each patient requires a corresponding break or a second device.

Another known device for measuring the urine flow of a patient is shown in DE-OS 39 33 025 and the associated DE-OS 41 09 974. This also involves the application of the flow principle, but the dynamic pressure generated by the urine flow in a specially shaped measuring head with several cavities is recorded as the measured variable and evaluated electronically. The specially shaped measuring head, in particular the design of a sharp edge on a boundary wall surrounding the pressure measuring chamber, makes the flow conditions controllable, so that measurement inaccuracies are limited. Otherwise, however, the disadvantages already shown for the solution according to DE-OS 35 41 649 remain due to the same causes.

To avoid the disadvantages of the flow principle, the weighing principle is used to determine the urine flow. The weight increase is measured per unit of time. By using digital evaluation devices, any practically evaluable measurement accuracy can be achieved without changing the effort. However, the disadvantages of using the weighing principle are the need for a collection container that has to be emptied manually after the measurement and the fact that the urine flow hits the inside of the collection container at different angles and in different places, which can lead to an uncalibrable time response of the measuring system.

The invention is based on the problem of increasing the possible patient frequency when recording the characteristics of the urine flow in urological diagnostics

and to improve the handling of the measuring device while ensuring maximum measurement accuracy.

The problem is solved according to the invention in that a measuring device for determining the flow of urine for urological examinations has a funnel-shaped urine collection container which, at its lowest point, merges into a cylindrical pipe socket with a vertical longitudinal axis, and the measuring device is connected to an electronic control and evaluation device, whereby the funnel-shaped urine collection container is suspended in a flat horizontal ring which represents the free end of a balance beam, the balance beam is connected to a scale which is connected to the electronic control and evaluation device via a measured value output, a flexible hose is attached to the tubular socket, continuing its vertical course, and a squeezing device which closes the hose is arranged below the tubular socket.

The characteristics of the urine flow are recorded when the urine flow released by the patient into the urine collection container acts as a change in weight on the balance beam and its deflection is transformed by the scale into an electronic measurement signal and fed to the control and evaluation device. The electronic measurement signal is represented as a voltage or current curve as a function of time with subsequent digitization in the control and evaluation device or as a bit pattern sequence if the digitization is carried out by the scale. In both analog and digital transmission of the measurement signal, the control and evaluation device provides the current flow rate, the final value as a total amount and the average flow rate by averaging to the doctor for evaluation. The scale is calibrated using the ham collection container inserted into the balance beam and the flexible hose attached to its tubular socket, whereby the zero adjustment of the scale can also be carried out using software in the control and evaluation device.

The funnel-shaped urine collection container and the flexible tube attached to it can be removed after the measurement and the opening of the squeeze device, which is automatically triggered by a control signal emitted by the control and evaluation device, whereby the collected urine is drained into a suitable container or a

The urine that drains from the toilet bowl can be removed from the balance beam or cleaned by simply flushing it, thus achieving a high patient frequency and improving the hygienic and aesthetic conditions by avoiding manual handling of the urine collection container when it is full.

The inventive features claimed in subclaims 2 to 4 represent advantageous embodiments of the invention in terms of their handling and the improvement of the measurement accuracy. The vertical displacement of the measuring device enables simple adaptation to physiological conditions and the selection of the examination location according to the patient's psychogenic state by the attachment to a preferably mobile support device. In particular, the vertical displacement of the measuring device firstly prevents the urine stream from hitting the wall of the urine collection container at an unusual angle and secondly enables the use of a suitable seat so that both female and male patients can be examined.

Subclaims 5 to 9 characterize advantageous embodiments of the squeezing device.

The invention is explained in more detail below in the form of advantageous embodiments with reference to the drawing. The drawing shows in

Fig. 1 is a schematic representation of a first embodiment of the measuring device according to the invention during a measurement;

Fig. 2 is a schematic representation of a second embodiment of the measuring device according to the invention after a measurement and

Fig. 3 is a view of the measuring device according to the invention.

The embodiment of the invention according to Fig. 1 consists of a scale 1, which has a balance beam 2 with an annular free end 21. A fixed abutment 513 and a servo motor 511 are firmly connected to the balance beam 2. A funnel-shaped urine collection container 3, the lowest point of which merges into a cylindrical pipe socket 31, is located in the annular free end 21 of the balance beam 2. A flexible hose 4 is attached to the cylindrical pipe socket 31.

which is squeezed below the pipe socket 31 by a stamp 512 against the fixed abutment 513 and is thus closed. The movement of the stamp 512 takes place by means of the servo motor 511, during which the funnel 3 with the attached hose 4 is suspended in the ring-shaped part 21 of the balance beam 2. After the hose 4 is squeezed, the scale 1 is automatically calibrated.

The urine flow released by a patient into the funnel 3 causes a deflection of the balance beam 2, which is transformed by the scale 1 into an electronic measurement signal. Deflection of the balance beam 2 also means a direct electrical recording of the weight change caused by the incoming urine flow, for example by means of strain gauges, a bimetallic strip, oscillating circuit detuning, coordinate recording analogous to a PC mouse or the like. The electronic measurement signal is sent from the scale 1 to a control and evaluation device 6, which advantageously has a keyboard and a display and can be connected to other output units such as printers or the like or makes the determined data available in a suitable manner for further processing in the practice PC, e.g. stored on a diskette. Of course, the control and evaluation device 6 also has suitable connections to be able to carry out data transfer to a PC without intermediate storage on a diskette. The signal proportional to the change in weight is differentiated so that during micturition the current flow rate of the urine stream is output as the measurement result at any time. The total weight of the urine collected in the funnel 3, which can be read after micturition has ended, and the average flow rate calculated by averaging are other data available.

After micturition has ended, the funnel 3 is emptied into a toilet bowl or into a suitable container by starting a control signal via the control and evaluation device 6 to the servo motor 511, whereupon the plunger 512 is removed from the fixed abutment 513 and the tube 4 is opened in this way and the urine in the funnel 3 flows out. Manual emptying of the funnel 3 is therefore no longer necessary.

The embodiment of the invention according to Fig. 2 has a basically identical structure and a basically identical mode of operation as the embodiment according to Fig. 1. Only the drive of the plunger 512 consists of a compression spring 524, which in the state shown, after which the hose 4 is opened, is actuated by a plunger 522

is pulled together by the electromagnet 521 which keeps the hopper 3 away from the fixed abutment 524 and overcomes the spring force of the compression spring 524. The state shown occurs as soon as the automatic emptying of the hopper 3 takes place after receiving the control signal from the control and evaluation device 6 by pulling the electromagnet 521 on the plunger 522 or after inserting the hopper 3 into the ring-shaped part 21 of the balance beam 2, before the adjustment of the scale 1 is carried out.

Fig. 3 shows a view of a measuring device according to the invention. A housing 7 containing the scale is movably attached to a support device 8, which is preferably designed as a tripod, by means of a known clamping device (not shown). The balance beam 2 consists of a part that optically continues the housing 7 and the ring-shaped free end 21 designed as a bracket, into which the funnel-shaped urine collection container 3 is inserted. The funnel 3 merges at its lowest point into the cylindrical pipe socket 31, onto which the flexible hose 4 is attached. The part of the balance beam 2 that optically continues the housing 7 forms the fixed abutment for the plunger, which squeezes the hose 4 against the fixed abutment during the measurement. The drive of the plunger is attached to the part of the balance beam 2 that optically continues the housing 7 in its interior. A flexible sleeve 10 is arranged between the housing 7 and the part of the balance beam 2 that optically continues it. This sleeve is preferably designed as a bellows and seals the interior of the measuring device on the one hand and on the other hand ensures the deflection of the balance beam 2 with respect to the housing 7 or the scale that is firmly connected to it. The rest of the mode of operation corresponds to that described with regard to the illustrations in Figures 1 and 2.

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Claims (9)

• · Protection claims 1. Measuring device for determining the flow of urine for urological examinations with a funnel-shaped urine collection container which at its lowest point turns into a cylindrical pipe socket with a vertical longitudinal axis and which is connected to an electronic control and evaluation device, characterized in that the funnel-shaped urine collection container (3) is suspended in a flat horizontal ring (21) which represents the free end of a balance beam (2), the balance beam (2) is connected to a scale (1) which is connected to the electronic control and evaluation device (6) via a measured value output, a flexible hose (4) is attached to the tubular socket (31) continuing its vertical course, and a squeezing device (5) which closes the hose (4) is arranged below the tubular socket (31). 2. Measuring device according to claim 1, characterized in that the measuring device is arranged so as to be vertically displaceable. 3. Measuring device according to claim 1 or 2, characterized in that the measuring device is attached to a separate carrier device (8). 4. Measuring device according to claim 1, 2 or 3, characterized in that the measuring device, the control and evaluation device (6) and a power supply device are attached to a common carrier device (8). 5. Measuring device according to claim 1, 2, 3 or 4, characterized in that the squeezing device (5) has a control input which is connected to the control and evaluation device (6). 6. Measuring device according to one of claims 1 to 5, characterized in that the squeezing device (5) consists of a displaceable stamp (512; 522) and an abutment (513; 523). 7. Measuring device according to claim 6, characterized in that the displaceable plunger (512; 522) is acted upon by a drive (511; 521, 524). 8. Measuring device according to claim 7, characterized in that the drive (511; 521, 524) is a servo motor (511), 9. Measuring device according to claim 7, characterized in that the drive (511; 521, 524) consists of a compression spring (524) acting on the plunger (522) and an electromagnet (521) overcoming the spring force.