DE3340371A1 - Monitoring system for heating devices - Google Patents

Abstract

The invention relates to monitoring systems for the serviceability of heating systems, especially for electrical, self-regulating heating strips. According to the invention, the problem is solved by measuring electrical inductance or capacitance at the end of the heating circuit, with a connection to an alarm device, or by the connection of an ammeter with an electronic circuit for determining current changes, having a connection to an alarm device. A further solution is represented by the connection of a transmitter to the end of a heating circuit, which transmitter superimposes a high frequency on the heating current, the interruption of which high frequency in the event of a failure of the heating current is recorded in the supply part in the receiver. The problem is furthermore solved by guiding an optical fibre having temperature-dependent transmission properties along the heated object, said optical fibre being coupled to an alarm device.

Description

Monitoring systems for heating devices

The subject of the present application is a system for monitoring the usability of heating devices, especially in connection with the Function monitoring of self-regulating electrical heating cables.

The heating of extensive bodies, for example pipelines for which heating tapes are increasingly being used for the supply of thermal energy, such as they are described, for example, in DE-OS 27 55 076, raises the problem of functional control on.

In particular with heating tapes that are laid outdoors, must be included mechanical damage to the lead wires or the contacts will. In such malfunctions, part of the heating tape system no longer works; the system to be heated (pipeline, boiler) loses its set temperature; by the cooling can cause major damage (mechanical pipe wall destruction by freezing the water, transport problems by solidifying the liquid Pipe content in lines or similar).

The sometimes considerable linear expansion of the above-mentioned heating devices it brings with it that the conventional approaches to heating system monitoring do not represent a satisfactory solution. Usual temperature sensors (such as resistance thermometers, Thermocouples only respond with an alarm signal when they are at the measuring point even a predetermined target temperature is fallen below, so that with a larger Distance between the damaged area and the sensor only after a considerable delay If the damage event occurs, the alarm reaction takes place. Depending on the location of the damaged area relative to the measuring point, part of the heated system has already cooled down a long way advanced before a conventional temperature sensor reacts.

Increasing the number of measuring points increases the reliability To bring about the notification of damage is unsatisfactory for reasons of cost and makes complicates the overall system by increasing the number of sensors and their connections and therefore more vulnerable.

In addition, there is no direct information in the conventional way by locating the damaged area.

Another disadvantage of conventional monitoring components for heating systems consists in the fact that only when the system is fully heated a picture of the functionality the Heating elements is to be obtained. During the idle time, for example during the summer Switch-off time of anti-icing heating, it is not possible without a large Energy and time expenditure to provide information about possible heating defects and initiate the corresponding repairs.

The object of the present invention was therefore to provide a monitoring system to provide the function monitoring of electrical heating devices that it enables the existence of function-impairing damage with as little as possible Determine effort and minimal delay.

This object is achieved in that in the electrical Heating system, at the end of each heating circuit a capacitor with a measuring device for the ohm-capacitive current and the electrical phase angle an analog circuit to determine the capacitive current and a comparison element to form the difference between capacitive current and a target current with connection to a signal switch connected.

The capacitors to be used according to the invention preferably have a capacity of 1 ßF to 20 ßF. First there is the resulting ohm-capacitive Total current and the electrical phase angle '9' measured.

An analog circuit determines from this in accordance with the equation Ic = I 1 sin 9 is the capacitive current.

If one of the capacitors is above the power supply rails of the heating elements, preferably the self-regulating heating tape, no longer under tension1 the capacitive current falls below a specified target value. Setpoint and actual value of the capacitive current are given to a switch which in the event of a deviation between target and actual current an optical or acoustic alarm signal triggers.

This monitoring device according to the invention speaks in the event of failure of a heating element without noticeable delay, thus allowing countermeasures to be taken before the cooling down of the system can cause major damage. One Monitoring with the system according to the invention is both for umspcnnenen and possible with bare heating tapes. The surveillance system according to the invention are particularly characterized by the fact that even during the idle time of a heating system The operational readiness of the System can be checked.

The object of the invention is also achieved in that in Each heating circuit has an operational amplifier connected to a signal switch connected.

The actual current of a heating strip or, if a 3-phase system is available, the 3 heating strips, measured and the measured value on an operational amplifier given.

An electronic unit compares the instantaneous value of I with that value measured immediately before. A rapid change in current d I / dp is registered because a wire is broken, for example, a circuit is triggered and a Relay activated, which in conjunction with an optical or acoustic alarm device stands.

The alarm device is only activated with large values dI / dt, i.e. with fast Current changes as they occur with short circuits and interruptions are activated. The monitoring system is insensitive to the relatively minor changes which occurs through the self-regulating mechanism of the heating tapes.

Advantages of this monitoring device according to the invention are - Universal applicability for both covered and uncovered Heating tapes - the possibility of doing without additional installations - the possibility of the To install a monitoring device in the control panel, compared to conventional This solution according to the invention is characterized by fast heating monitoring systems Responding to damage in the utility lines.

The object of the invention is also achieved in that on At the end of each heating circuit a high-frequency transmitter and in which the heating tape feeds A corresponding high-frequency receiver is connected to the supply part. the The supply voltage is usually 220 V. The transmitter is in a connection or end termination box housed. The transmitter gives the heating current a high frequency from 1 KHz to 1000 KHz, preferably 50 to 300 KHz superimposed. The recipient who is preferably housed in the control cabinet, now registers whether the impulses of the Transmitter arrive and thus the freedom from interference of the heating tape is guaranteed.

If the heating tape is used for any reason (e.g. mechanical damage) interrupted, the transmitter is no longer supplied with electrical energy so that he is no longer able to send. The recipient cannot now use the Supply lines transmitted superimposed pulses received more. Because the sender is supplied with electricity, there are no more wirelessly transmitted impulses at the recipient.

In any case, however, the transmitter is preferably against wireless emission shielded from high frequency.

The advantage of this embodiment of the invention is that it is universal Can be used for any type of non-braided or braided heating tape, the opportunity to dispense with additional field installations and the quick response to line defects. Again, it is possible during the Service life of heaters without the energy and time required to heat the Entire system the necessary information about the operational readiness or the need for repair of the system.

The object of the invention is also achieved in that at A light guide is guided along the object to be heated, which is covered with a polymer is coated, the degree of crystallinity of which depends on the temperature when the polymer jacket of the light guide changes its. Freezing temperature reached, its refractive index becomes significantly higher than that of the fiber optic core. Through this the attenuation increases so much that the conductor no longer transmits light.

This type of light guide is used to achieve the object of the invention used like an extended temperature sensor. With the described polymer encased It is possible for light guides to create a defect in the heating device due to the temperature drop at this point and the resulting interruption of the light pipe without major Delay to register. Is the temperature at any point along the Pipeline below the target temperature (the glass transition temperature of the polymer jacket of the respective light guide) so no more light is guided at the beginning of the system the alarm is triggered.

The light guide can be equipped with a reflector at one end will. It is also possible to lay the light guide in a loop.

In the event of a defect, the Fault location can be precisely located. In addition to this advantage, the application shows such light guides in the monitoring system according to the invention have the advantage of being reliable Responds to locally limited falls below the target temperature and provides this is a simple and reliable way to measure the temperature of a heated Monitor object in operating condition.

According to the invention for heating monitoring usable, sheathed Light guides are with different, specific transmission interruption temperatures available. For a given monitoring problem, is a function of the target temperature to select the appropriate type of light guide for the heated device.

Exemplary embodiments of the invention are shown in the drawings and are described in more detail below.

Fig. 1 shows the circuit diagram of the monitoring system according to the invention, that uses electrical capacitance or electrical inductance and in which (1) the monitoring device, (2) the control cabinet, (3) the heating cables, (5) the connection or end caps and (4; the reactants: denote.

2 shows the circuit diagram of a monitoring system according to the invention with current control only in the supply part again, whereby (3) the heating bands (2) the The control cabinet and (1) the monitoring device.

Fig. 3 is the circuit diagram of the monitoring system according to the invention with the help of a transmitter (5), which is located at the end of the heating tape (3) in a connection or Final junction box (6) is housed and in which the accordingly Receiver (8) coupled with a signal lamp or other alarm device (7) is housed in the control cabinet (2) '.

4 shows a monitoring system according to the invention in particular for elongated heating devices, in which (3) a heating tape, (-9) the heating tape connection (.14 the fiber optic light guide (11) the light transmitter and receiver and (1 2) a Means to be heated pipeline.

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Claims (10)

Monitoring system for electrical heating systems, thereby characterized in that a measuring device for electrical inductance in the heating circuit or electrical capacitance connected to a signal switch is. 2. Monitoring system for electrical heating systems, characterized in that that at the end of each heating circuit there is a capacitor with a measuring device for the ohm-capacitive Current and the electrical phase angle i, an analog circuit for determining the capacitive current and a comparison element for forming the difference between capacitive Current and a target current with connection to a signal switch is connected. 3. Monitoring system according to claim 2, characterized in that each capacitor has a capacitance of 1 ßF to 20 ßF. 4. Monitoring system for electrical heating systems, characterized in that that in each heating circuit an ammeter via an operational amplifier and a logic circuit is connected to a signal switch. 5. monitoring system for electrical heating systems, characterized in that that at the end of each heating circuit a high-frequency transmitter and in which the heating tape feeding supply part is connected to a corresponding high-frequency receiver is. 6. Monitoring system according to claim 5, characterized in that the Frequency of the transmitter in the range from 1 KHz to 1000 KHz, preferably -50 to 300 KHz is. 7. monitoring system according to claims 5 and 6, characterized in that that the transmitter is shielded. 8. Monitoring system for heating systems, characterized in that a light guide with a polymeric jacket that crystallizes at the set temperature is guided along the heated object and connected to a signal switch is. 9.tJberwachungssystem according to claim 8, characterized in that the light guide is laid in a loop. 10.Uberwachungssystem according to claim 9, characterized in that the light guide is equipped with a reflector at one end.