DE1288831C2 - Equipment for the finish control in swimming competitions - Google Patents

Description

The invention relates to a device for checking the finish line in swimming competitions with a switching device to be operated by the float lying in a circuit for a timer, which is attached to the end of the swimming lane and submerged in the water, plate-shaped electrode with good conductivity, as well as one at a short distance from the plate-shaped electrode, in the direction of movement of the float, the electrode is arranged to be elastically movable there is also good conductivity, so that by pressing the movable electrode against the fixed electrode a switching process to stop the timer is triggered.

In a known device of this type (Swiss patent 371285), the release device also consists of a fixed and a movable electrode, which, however, is in series with a relay, a potentiometer and a DC voltage source of 6 volts ao that feeds the relay. With the potentiometer, the resistance of the two electrodes hanging in the water is adjusted to about 250 ohms. Modern comb relays with a normally open or normally closed contact have a direct current resistance of 200 to 300 ohms for this operating voltage. The total resistance between the two electrodes is therefore around 500 ohms. With a 6 volt DC voltage source, a current of about 12 mA flows. At this current strength, electrolysis with gas development, deposition or dissolution of metals occurs to a not inconsiderable extent, which can ultimately make a constant change of the adjustment potentiometer necessary. Furthermore, one must not ignore the effect of the voltage peak resulting from switching off the relay on the two electrodes hanging in the water. This could have unpleasant consequences for the swimmers with the above-mentioned known device, if one considers that at 6 volts DC the cut-off voltage peak can reach the 30-volt limit, and even exceed it considerably, depending on the inductance and excitation current.

In a similar known device in which the trip device is a type of pneumatic contact represents, the effort is too great. Above all, this pneumatic switch must be perfect be waterproof in order to remain fully functional.

The known devices for checking the finish line are therefore either very complex in construction or offer inadequate safety for swimmers.

The object of the invention is therefore to provide a device with which a timepiece is essentially can be stopped more easily and safely.

This object is achieved according to the invention in that the two electrodes are made of electrical Conductors of different materials form an existing galvanic element.

If a swimmer touches the switching device with any part of his body, one of them will be later The electrode described is pressed onto the electrode behind it, and thereby the two electrodes short-circuited, whereby the one originally present between the two electrodes, by electrolytic The voltage generated by polarization is canceled and the timer is stopped will.

In addition to the low technical effort and high operational reliability, this facility offers nor the considerable advantage that the voltage for controlling the timer comes directly from the switching device is won.

An advantageous embodiment of the device according to the invention is characterized in that the switching device is connected to the timer via a transistor amplifier. In this way timepieces with low sensitivity can also be used.

This device can still be improved if the output stage of the amplifier is direct is switched into the shutdown circuit of the timer. This way, a particularly fast shutdown is achieved of the timer.

Further details of the invention emerge from the description with reference to the figures. It shows

F i g. 1 shows the front view of the electrode arrangement with the circuit diagram of the transistor amplifier Timepiece,

F i g. 2 side view of the electrode arrangement in section,

F i g. 3 Circuit diagram of the transistor amplifier (output stage in the switch-off circuit of the timer),

4 shows several combined electrode arrangements to form a unit,

Fig. 5 Electrode arrangement in a metal grid design.

The in F i g. 1 shown contact plate is from the front, the contact plate shown in Fig. 2 is drawn in cross section and consists of an approximately 250X160 cm large and approximately 2 to 3 cm thick base plate 1 made of commercially available plastic. A metal foil or graphite layer 2 approximately 230 × 140 cm in size is applied to this base plate. In front of this metal foil or graphite layer 2, bare metal wires 3 are stretched at a distance of a maximum of 10 mm, the mutual distance between them being approximately 5 mm. These individual metal wires 3 are each tensioned by a spring 4 in such a way that a pressure of at least 50 g in the arrow direction according to FIG. 2 at any point on the metal wires 3 presses them onto the metal foil or graphite layer 2. By pressing one or more metal wires 3 against it, a galvanic connection is established with the metal foil or the graphite layer 2. As a result, the voltage difference originally present between the metal foil or the graphite layer 2 and the metal wires is canceled. When using a metal foil 2, make sure that the metal wires:> consist of a material or are provided with a surface that is at least 0.5 volts more negative than the metal foil or graphite layer 2 in accordance with the voltaic voltage series.

On the approximately 400 metal wires 3 there is a close-meshed plastic grid 5, which is intended to prevent individual metal wires 3 from being deliberately tensioned and thereby the associated springs 4 from being stretched excessively. From the metal foil or the graphite layer 2, a line 8 leads from the metal rail 6, through which all metal wires 3 are galvanically connected to one another, a line 7 / .. B. to a transistor amplifier connected downstream.

The contact plate according to FIGS. 1 and 2 hangs about

Claims (7)

two thirds in the water, so there is, due to the electrolytic polarization, between the metal foil or the graphite layer 2 and the metal wires 3, a voltage that is completely sufficient to, for. B. to supply the necessary base current of a transistor Ts 1 for the through-control. If the transistor Ts 1 is conductive, then according to FIG. 1 the transistor Ti 2 is blocked and the relay in its collector branch cannot pick up. When relay A has dropped out, a control lamp Lp 1 lights up, which indicates whether the contact plate hanging in the water is working properly and whether there is no short circuit between the electrodes. If a swimmer hits the contact plate with any part of his body, the negative bias of the transistor Tsl is canceled. The transistor Ts 1 blocks, the transistor Ts 2 conducts, and the relay A picks up. The signal lamp Lp 2 lights up while the control lamp Lp 1 is de-energized. At the same time, another contact of relay A switches off timing system Z. The amplifier consisting of the transistors Tsl and Ts 2 can also be designed as a monostable or bistable multivibrator, the circuits of which are assumed to be known and are therefore not explained in more detail. Furthermore, the transistor Ts2 according to FIG. 1 with its emitter-collector path with a possible series interconnection of relay A directly in the circuit of an electrical timing system, if the switching time (5 ms) of relay A is to be excluded. The diode D connected in parallel to the relay A in the reverse direction limits the voltage peak that occurs when the relay is switched off due to its inductance, in order to protect the transistor from possible destruction. Of course, the approximately 230X140 cm large metal foil 2 can be replaced by several horizontally attached metal foil strips, the width of which can be selected individually and which are galvanically connected to one another. Under certain circumstances, this represents a simplified manufacturing process, while when graphite is used, the material is applied by various known methods. Furthermore, it is also contemplated that the approximately 250 cm wide base plate 1 according to FIG. 3 in several different widths, handy, composable individual panels 1 a ... 1 / to be executed, which fully meet the intended purpose as an interconnected unit. The necessary plastic grid 5 is after 5η the assembly of the individual contact plates la. . . 1 / so attached in front of the complete unit that the close-meshed plastic grille 5 rests directly on the metal wires 3. All contact plates la ... l / are fixed in a correspondingly composable holding frame 9 so that the individual mutual spacings of the metal wires 3 are guaranteed. With this design variant, contact plates of any width can be obtained as required, which is a great advantage for the different swimming pools and, above all, eases the transport problem. This embodiment variant even offers the possibility of connecting the metal wires 3 through a close-meshed metal grid 3 a according to FIG. 4, which is firmly fixed to the lower edge of the base plate 1 and is fastened at the other end to a metal rail 10, which in turn is galvanically connected to the contact rail 6 by several tension springs 4. This makes the aforementioned plastic grille 5 superfluous. Patent claims: 1. Device for the finish control in swimming competitions with by the float to be actuated, lying in a circuit switching device for a timepiece, the fortified from an end of the floating rail and good in the water-dipped, plate-shaped electrode conductivity, and one of the small distance in front plate-shaped electrode, in the direction of movement of the float, the electrode also has good conductivity, so that a switching process to stop the timer is triggered by pressing the movable electrode against the fixed electrode, characterized in that the two electrodes are made up of electrical conductors (2, 3) form galvanic element made of different material. 2. Device according to claim 1, characterized in that the fixed electrode (1, 2) is divided into several individual plates of different widths which can be assembled (1 a ... 1 f) . 3. Device according to claim 2, characterized in that the movable electrode is designed as a close-meshed metal grid (3) in front of each individual plate, the dimensions of which correspond to the individual plate. 4. Device according to claim 1, characterized in that the switching device is connected to the timer via a transistor amplifier (Iii, Ts2). 5. Device according to claim 2, characterized in that the output stage of the amplifier is connected directly to the switch-off circuit of the timer. · 6. Device according to claim 2, characterized in that the amplifier as a monostable or bistable multivibrator is carried out. 7. Device according to claim 2 or 4, characterized in that the amplifier controls an additional relay (A) whose changeover contact connects one of two different display elements to the power source of the timer. For this purpose 2 sheets of drawings