CS200738B1 - Circuits connection of accelerated paper run-out of registering instruments - Google Patents

Description

It is an object of the present invention to provide an accelerated deceleration circuit of a recording apparatus with automatic maximization of the recording paper feed rate, in particular of a multi-channel electrocardiography apparatus with automatic lead sequence switching.

The current microchannel electrocardiography instruments are equipped with an automatic lead sequence selector, which, when triggered, triggers the paper feed motor, generates service signals, generates lead sequence switching signals, and stops the paper feed motor when the cycle is complete and resets all automatic cycle control circuits.

A number of parameters can be programmed for the automatic cycle before the cycle start, among other things, the paper feed speed in a relatively wide range.

The machine stores the programmed paper speed and respects it throughout the cycle. At the end of the cycle, the feed rate memory status remains unchanged, that is, unless the operator selects a different speed, the device respects the original programmed speed in subsequent cycles.

In terms of paper feed in automatic operation, the new series electrocardiography devices can operate in two modes. In the first mode, the paper feed stops immediately after the end of the last automatic cycle lead sequence. This mode is likely to be used for mass electrocardiographic examinations, where records are stacked one after another. The advantage is saving paper.

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In the second mode ee the paper feed does not stop immediately after the end of the last cycle lead sequence, but only after the time interval required for the paper to travel in the machine from the writing edge to the tearing edge e. β complete recording of the whole cycle. This so-called paper overrun interval is given not less than the paper feed speed and machine design, that is, the actual paper length between the crease and the tear edge.

For electrocardiographic devices of the new series, the minimum paper feed speed at 10 mm / a and the paper length 4 between the writing and tearing edges are about 250 mm. Then the paper deceleration time interval is: _{L (na)} t (s) »in (mm) (a) that is about 25 s, which is a considerable value. 1 for the standard speed v = 25 mm / s, the deceleration time interval (about 10 s) is too large.

The shortcomings of the present invention are based on the fact that the output of the preselection memory connected to the decoupling circuits is connected with both the low speed and high speed switching circuits, and the inputs of the low speed and the highest speed switch circuit inputs are coupled to the motor deceleration flip-flop output to the inputs of the automatic electronic leakage sequence switch circuits, with the non-contact motor speed switch circuits connected to the lower speed circuit outputs and the highest speed switch circuit outputs .

The solution according to the invention reduces the motor deceleration interval to the lowest possible value while respecting the existing paper feed motor control solution by automatically generating a control signal at the motor deceleration interval which increases the motor speed to a maximum, i.e. 130 mm / s.

AND

This gives a minimum motor deceleration interval of about 2.5 seconds. This is constant for all preset speeds. In summary, the advantages of the solution according to the invention can be seen in the fact that the total time of the electrocardiographic examination is considerably shortened and, therefore, energy saving.

Furthermore, the paper feed motor is not overloaded, since it respects the current wiring of the sorbent loop of its control. It does not complicate the operation of the device, since it does not introduce any new control, on the contrary, everything is done automatically. In doing so, it respects the preset speed in the machine's memory, that is, even if the paper feed speed increases during the deceleration interval, the next cycle can run at the originally selected paper feed rate, ie the operator only activates the start button to start the next automatic cycle.

The solution of the circuit according to the invention is based on simplicity, which is also evident from the relatively small number of components that realize the solution.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will be further elucidated by a non-limiting example of a preferred embodiment thereof, which is described with reference to the accompanying drawings, in which:

200 730 in Fig. 1 is a block diagram of the circuitry of the invention and Fig. 2 is a circuit diagram of a particular embodiment of the invention.

The circuitry function of the invention shown in the accompanying drawings is as follows: after manual speed preselection on the control panel, it activates the speed preselection memory 9 together with the selected operating speed indication 2 and passes through the contactless switching circuits 5 via the isolation circuits 1 and engine speed. The motor therefore rotates at the selected speed. If you select automatic mode on the front panel, the function is similar after the cycle is started. The motor starts at the selected speed. The preselection memory 9 is blocked during the automatic cycle by the circuit signal H of the automatic electronic switch 8 of the lead sequences, i.e. the feed rate cannot be changed during the cycle.

Upon completion of the last lead sequence, the motor deceleration circuit 6 receives a trigger signal from the automatic electronic switch 8 lead sequence, flips to the active state, and activates the low speed blocking circuits 3 via the summation member 7 and the high speed switching circuits 4.

The start signal locks the preset speed and applies a maximum speed of 100 mm / s to the motor 5 proximity switching circuit.

After a defined interval in the circuits of the automatic electronic leakage sequence switch 8, these generate the motor stop-stop signal, that is, the motor stop flip-flop 6 returns to its initial position and at the input of the non-contact motor speed switching circuits. The summation element 7 makes it possible to activate the circuits 4 for switching the highest speed manually by the signal R for accelerated paper feed.

Fig. 2 shows a particular embodiment of the circuit according to the invention. Here, the speed preselection signal from the control panel is routed through the inventor to a quadruple flip-flop D, on which the signal B from the electronic circuit breaker 8 leakage circuit circuits is simultaneously routed, which blocks the possibility of flip-flop D status.

From the Q outputs, activation signals for LEDs are led as indication elements.

The Q outputs are routed via decoupling resistors 39, 40, 41, 42, based on the switching transistors 16, 17, 18, 19, and from there to the inputs of the contactless switching circuits of the motor speed 5.

If the -start signal comes from the circuits of the automatic electronic switch 8 of the lead sequences, the flip-flop 13, 14 is flipped over, opening the transistor 21, which, via diodes 36,

37, 38 and resistor 34 connect the bases of the switching transistors 16, 17, 18 to the ground potential. Simultaneously with the opening of the transistor 21, the transistor 20 closes, thereby activating a speed of 100 mm / s in the contactless speed switching circuits of the motor. Upon completion of the deceleration interval, the circuits of the automatic electronic switch 8 lead sequences generate a -stop- signal. The signal toggles the flip-flop 13, 14 to close the transistor 21 and to open the transistor 20, i.e., the preselected speed is again on the non-contact motor speed switching circuits.

The switch 22 applies a positive voltage to the resistor 33 via a resistor 32, thereby allowing for a 100 mm / s connection to the input of the b contactless circuit of the motor for the duration of activation.

Claims (1)

SUBJECT OF THE INVENTION Circuit paper acceleration deceleration of the recording apparatus and automatic maximization of the recording paper feed rate, in particular of multiple channel electrocardiography devices, and automatic switching of lead sequences, characterized by the fact that the output of the preselection memory (9) connected to the decoupling circuits (1) (3) a low speed lockout and, on the other hand, the high speed switch circuitry (4), wherein the low speed blocking inputs (3) and the high speed switch circuit input (4) are coupled to the motor deceleration flip-flop (6) output connected the outputs of the automatic electronic switch (8) leakage sequence circuits, with <5Ϊ contactless motor speed switching circuits connected to the outputs of the low speed blocking circuits (3) and to the highest speed switching circuits (4) outputs management.