CS259518B2 - Checking device for liquid presence finding - Google Patents

Description

The invention relates to a monitoring device for detecting the presence of liquid in a heated reservoir, the inputs of which are connected to a measuring probe or an auxiliary probe, and which are provided with active and passive electrical elements.

Numerous technological processes can be characterized in that an increase in any of the process parameters above a specified value can cause an operational failure, an accident, or even damage or destruction of the equipment or other technological equipment connected thereto.

Such a change of parameters must be unequivocally excluded from the point of view of both life and reliability, and appropriate control and control equipment must be taken into account to avoid harmful effects due to parameter changes. In the case of devices of this kind, particular attention must be paid to reliability and adequate service life. Therefore, in contrast to the existing measuring and control devices, these control and control devices must be of such construction and characteristics that they perceive only the selected characteristic and when the sub-units and components themselves are damaged in the event of failure of external operating conditions, e.g. emits a warning signal as if the parameter itself deviated from the specified value.

Such devices, cited above, classified as increasingly dangerous, are, for example, various devices for heating water and generating steam, boilers in which the temperature of the heating surface is maintained at a predetermined level by the water surrounding the surface. If, as a result of the decreasing water level, the heating surface enters partially or completely into the stand, where the heating element is overheated without water, the heating element is damaged and, in extreme cases, an explosion of steam can occur if the water enters the furnace. In order to prevent such cases, the indication and control of the water level must be continuously ensured.

With known devices, the task of continuously checking the water level is assigned to the operator. This! devices are also often provided with a device which automatically indicates a lack of water. Since the continuity of control is not ensured even in well-organized companies, even the supplementary device can be damaged, operating failures associated with great damage often occur in companies of this type.

The action of the known devices consists in arranging two probes in the reservoir, i.e. a measuring probe and an auxiliary probe. Both probes are well insulated from each other and from the reservoir. The absence or drop of water below a specified limit is measured so that an electric current flows between the probe isolated from the metal reservoir and the electrically conductive wall and into the reservoir wall due to the electrical voltage. Now that the water level falls below the set value, i.e. there is no contact between the water and the probe, the electric current is interrupted. The use of the probe itself does not satisfy the safety requirements because if the probe insulation breaks down or water vapor condenses on the probe surface, a signal appears as if there is water in the tank. The role of the auxiliary probe is precisely that it does not submerge in ¹ water under operating conditions, that is, that no electric current flows between the auxiliary probe and the reservoir wall. However, if a leakage occurs as a result of damage to the probe or the condensation of steam, electrical current will also flow between the auxiliary probe and the reservoir wall.

In known devices, the signals of two probes are basically processed by a bridge connection. This jumper is designed to emit an evaluable output signal only when the measuring probe reaches the water and the auxiliary probe does not send any signal. The bridge output signal is passed through a comparator to control the electromagnetic relay. For safety reasons, two parallel-wired connections are generally used instead of one, so that if one of the wires is damaged, the functionality of the other is maintained.

The disadvantage of this known solution is that if the auxiliary probe is damaged, for example in the case of a broken line, no error signal is sent, therefore it may happen that the system is overfilled with water or water is supplied instead of steam. Another drawback is that when the steam; there is a short circuit between the probes and the tank wall between the auxiliary probe and the measuring probe so that there is an electrically conductive connection between them. In the absence of water, the device indicates the presence of the required amount of water, so that the boiler can also explode in the worst case.

These drawbacks are eliminated in the control device according to the invention, the principle being that the measuring probe is connected to the first input of the pulse resistor, the second input is connected to an auxiliary probe, the first output of the pulse resistor is connected to the phase detector input, the output of the nia pulse converter is coupled to the first input of the supervisor circuit, the second supervisor circuit input is connected to the auxiliary probe, and the phase detector and supervisor circuit outputs are connected to the evaluation unit inputs and the evaluation unit output is connected to at least one power amplifier switch.

An advantage of the invention is that, on the one hand, damage to the auxiliary probe is indicated, and if a probe is damaged, the device according to the invention disconnects the heating system.

An exemplary embodiment of a control device according to the invention is described and illustrated in the drawings in which: FIG.

Fig. 2 is a cross-sectional view of a probe connected

25951В

3 shows the various measuring positions of the probe connected to the monitoring devices according to the invention.

Giant. 1 is a block diagram of a preferred embodiment of a control device according to the invention. Both probes, i.e. measuring probe 1 and auxiliary probe 2, are connected to the inputs of the pulse resistance converter 3, which generates phase-shifted pulses. The phase deviation of the output pulse from the reference pulse phase depends on whether the measuring probe 1 or the auxiliary probe 2 is in contact with the liquid 14. Accordingly, either the output pulse phase corresponds to the reference pulse phase or the phase difference is 180 °. The first output of the pulse resistance converter 3, on which the reference pulse and the output pulse is present, is connected to the input of the first phase detector 4a and the input of the second phase detector 4b. Depending on the phase position, the first phase detector 4a and the second phase detector 4b will either release a pulse for the first input of the first evaluation unit 6a and the second evaluation unit 6b, or no pulse will be given. The second inputs of the first evaluation unit 6a and the second evaluation unit 6b are connected to the second output of the pulse resistance converter 3 via the first supervision circuit 5a and the second supervision circuit 5b, the second input of the first supervision circuit 5a and the second supervision circuit 5b connected to the second auxiliary output probes 2.

The first monitoring circuit 5a and the second monitoring circuit 5b play the most important role in the monitoring device according to the invention, since they monitor the integrity, short circuit or interruption. The first evaluation unit 6a and the second evaluation unit 6b only send an inhibit signal to the first power amplifier 7a and the second power amplifier 7b, whose first switch 8a and second switch 8b turn the heating system on and off when the probe 1 does not reach into liquid 14, e.g. water, or when the auxiliary probe 2 is short-circuited, or when the line leading to the measuring probe 1 or the auxiliary probe 2 is broken. By means of the inhibitory signal, for example, the first power amplifier 7a and the second power amplifier 7b disconnect the boiler heating. The output of the first power amplifier 7a is connected to the first switch 8a, the output of the second power amplifier 7b is connected to the second switch 8b, whose in-series working contacts form the output of the device. Unit duplication is used to allow the device to self-inspect.

Giant. 2 shows a cross-section of a measuring probe 1 used for a monitoring device according to the invention. The measuring probe 1 can be arranged, for example, in the boiler wall 13. In the wall 13 is a bore into which the electrically insulating first gasket 11 is inserted, to which an electrically conductive auxiliary probe 2 adjoins, which is separated from the measuring probe 1 by an electrically insulating second gasket 12.

Giant. 3 shows the arrangement of the measuring probe 1 and the auxiliary probe 2 in the interior of the boiler in their first position in which operation is in order. The measuring probe 1 contacts the liquid 14, the resistance of the auxiliary probe 2 to the resistance of the measuring probe 1 is quite high, i.e. there is no electrical connection between the two.

Giant. 4 shows a second position in which there is still contact between the measuring probe 1 and the liquid 14, but the wiring of the auxiliary probe 2 is broken so that the working contacts of the first switch 8a or second switch 8b connected in series forming the output of the device .

Giant. 5 shows a third position where, for example, as a result of the condensed steam, the monitoring device detects that the resistance γ between the measuring probe 1 and the auxiliary probe 2 lies below the permissible value. Even now the boiler heater is disconnected.

Giant. 6 shows the following position, in which the auxiliary probe 2 of the liquid 14 also touches as a result of the boiler overfilling with the liquid 14. Even now the boiler heating is switched off because of a system fault.

Giant. 7 shows the last case in which a breakage occurred in the measuring probe 1, the state of the liquid 14 in the boiler has dropped so far that the measuring probe 1 does not reach into it. The monitoring device also disconnects the boiler heating.

Light indicators 15 provide the appropriate information about the status of the first switch 8a and the second switch 8b.

For systems where the circuits do not self-test, the circuits must be duplicated within the meaning of the safety regulations. For this reason, the phase detector 4, the monitoring circuit 5, the evaluation unit 6 and the power amplifier 7 are designed in duplicate.

The operating contacts of the relays are connected in series, which means that if one of the two channels is faulty, the signal giving the obvoid is switched off and the boiler heating is stopped as a result.

Claims (4)

Monitoring device for detecting the presence of liquid in a heated reservoir, the inputs of which are connected to a measuring probe, and having active and passive electrical elements, characterized in that the measuring soindium (1) is connected to the first input of the pulse resistance converter (3) whose second input is connected to the auxiliary probe ( 2), first inverter output ( 3) the pulse resistance is connected to the input of the phase detector (4a, 4b), the second output of the pulse resistor converter (3) is connected to the first input of the monitoring circuit (5a, 5b), the second input of the monitoring circuit (5a, 5b) being connected to the auxiliary probe (2) and the phase detector outputs (4a, 4b) and the supervision circuit (5a, 5b) are connected to the inputs of the evaluation unit (6a, 6b) and the output of the evaluation unit (6a, 6b) is connected to at least one switch (8a, 8b) via at least one power amplifier (7a, 7b) ).