DE1813907A1 - Remote adjustable temperature controller - Google Patents

Description

"Remote adjustable temperature regulatorl 'The invention relates to a remotely adjustable temperature controller, its setpoint adjustment via a control line is adjustable with the help of a control voltage or a control current.

Such a remotely adjustable temperature controller is, for example used in the automatic La control for electrical heat storage heating. In the known controller, an electrically heated one is used to adjust the setpoint Bimetal used. Such a bimetal is relatively inexpensive, it has However, the disadvantage is that the control unit still has a certain, relatively large heating output can hardly be undercut.

The invention aims to reduce the control power and the reliability of the controller.

According to the invention this is achieved in that a regulator contact is used Inert gas contact is used, which is either one of the control voltage or the Control current dependent electromagnetic field as well as one on the temperature dependent magnetic field. The temperature-dependent magnetic field can be generated by a permanent magnet, the spatial by a temperature sensor is movable.

But it can also be fed by a thermocouple with the help of a Coil surrounding the inert gas contact can be generated. The magnetic influence of the spatially adjustable permanent magnet on the protective gas contact is activated by suitable Shaping of pole pieces of the permanent magnet on the required relationship to the Adjusted the temperature of the filling tube. As a control voltage, if a galvanic Isolation is desired, an alternating voltage can be used, with rectifiers The conversion into the required DC voltage takes place at å each temperature controller.

The invention is based on two exemplary embodiments with the aid of the drawing explained in more detail.

Fig. 1 shows a temperature regulator with a temperature-dependent displaceable Permanent magnetic field, while in Fig. 2 a controller operating with a thermocouple is shown is.

In the arrangement according to FIG. 1, a protective gas contact 1 is in series with a charging contactor 2, which the charging circuit of a storage furnace, not shown switches. The shielding gas contact is closed in the rest position. Inert gas contact and charging contactor are connected to a voltage source (not shown). The inert gas contact can be operated via a relay winding 3 or a rotary magnet 4. the However, actuation can also be achieved through the interaction of the field winding and the rotary magnet take place. In this case the two effects must be additive. The rotary magnet is mounted on an axis 7 and can be adjusted with the help of a thermal sensor. The thermal sensor is pushed into the storage heater and consists of a filling pipe 9 with a relatively high coefficient of thermal expansion and a temperature-independent Transmission wire 10 which engages a lever 8 firmly connected to the axis 7. On the other arm of the lever 8, a tension spring 11 acts as a return spring serves. The rotary magnet 4 is provided with pole pieces 5 and 6 at its pole ends, which have such a shape that one of the rotation of the magnet is proportional magnetic effect on the inert gas contact is achieved.

The relay winding 3 is connected to a control line 12 which is connected to a voltage proportional to the outside temperature is applied. The relay winding 3 is practically not excited at low outside temperatures. At higher outside temperatures However, the excitation can become so strong that contact 1 is opened.

In the position shown, the protective gas contact 1 is closed that is, the heat storage furnace (not shown) is heated. That in the heat storage heater inserted filling tube 9 expands, so that the shift of the right The end of the pipe causes the lever 8 to pivot in the direction of the arrow shown. The rotary magnet 4 is adjusted accordingly and leaves one more after adjustment or less large magnetic components are effective on the inert gas contact.

The effects of the relay coil 3 and the magnet 4 add up and the magnetic field generated by the relay coil and magnet 4 opens at a certain level Size of the inert gas contact. When the heat storage heater cools down, the magnet becomes turned back by the tension spring 11.

Fig. 2 shows an embodiment without moving parts. In place of the Sensing tube is a thermocouple with a hot contact point 13 and a cold contact point 14 stepped. The point of contact 13 with the feed rods is pushed into the storage heater, not shown. The thermal current flows Via a winding 12 that surrounds the protective gas contact and generates a core temperature magnetic field proportional to the furnace. The magnetic excitation of the inert gas contact is composed of the effects of winding 12 and winding 13.

The temperature controller according to the invention is particularly advantageous because the required control power can be reduced, the application of Inert gas contacts increases the reliability of the temperature controller. The influencing the protective gas contact by a magnet can also be done in any other way take place. The magnet can, for example, be more or less the protective gas contact to be approached.

5 pages description 6 patent claims 2 sheets of drawings with 2 Fig.

Claims (6)

Claims 1. Remote adjustable temperature controller, its setpoint adjustment via a control line with the aid of a control voltage or a control current is adjustable, characterized by a protective gas contact (1) as a regulator contact, the one dependent on the control voltage or the control current electromagnetic Field as well as a temperature-dependent magnetic field. 2. Remotely adjustable temperature controller according to claim 1, characterized in that that the temperature-dependent magnetic field is generated by a permanent magnet (4) which is displaceable by a temperature sensor (9, 1Q). 3. Remote adjustable temperature controller according to claim 1, characterized in that that the temperature-dependent magnetic field in one of a thermocouple fed coil is generated. 4. Remote adjustable temperature controller according to claim 1 and 2, characterized characterized in that the magnetic influence of the spatially adjustable permanent magnet (4) on the inert gas contact (1) by appropriately shaping pole pieces (5, 6) adjusted to the required relationship to the temperature of the sensor tube (9) will. 5. Remote adjustable temperature controller according to claim 1 and 3, characterized characterized in that the coil connected to the thermocouple has the protective gas contact surrounds. 6. Remote adjustable temperature controller according to claim 1 and 2, characterized characterized in that an alternating voltage is used as the control voltage and with Rectifiers on each temperature controller convert the voltage into the required DC voltage he follows.