DE2706750A1 - Split bushing temperature control - by variable shunting of heater sections according to their temperatures - Google Patents

Abstract

The two parts of a two part heating element supplied in series from a single transformer secondary winding are controlled independently. Each part is connected in parallel with a variable impedance circuit, controlled according to the temp. of one or both parts of the heating element. Used for controlling the temps. on the two sides of a split bushing in glass filament prodn. Simple system provides continuous independent temp. control of two heaters supplied from a single source.

Description

Temperature control device for a two-part heating

element. in particular split fiber spinning furnaces The invention relates to a device for maintaining a certain temperature of a first and a second part of an electrical heating element, in particular a divided one Fiberglass spinning furnace.

In the manufacture of glass fibers, molten glass is made from openings or drawn nozzle nipples of a spinning furnace, which are attached to its underside are. Originally, the number of nozzle nipples was usually no more than 200.

However, because of the increasing need for fiberglass, the spinning ovens were getting bigger and now have 800 to 2000 or even more female nipples. This resulted for the use of split spinning ovens, which can, for example, have two sides, both of which contain up to 1000 nozzle nipples, making a total of 2000 Nipples yields. The spinning furnace must be heated to keep the glass melted, before it exits through the nozzle nipple. A temperature control is essential necessary because the formability of glass fibers depends directly on the viscosity of the Glass depends, which in turn is directly dependent on the glass temperature. With the With the advent of the split spinning furnace, the problem arose as did the temperature Each side of the spinning furnace can be regulated individually without having two separate ones Power supply systems, which cause considerable costs, become necessary. the The present invention relates to a suitable circuit for this purpose.

In US-PS 33 08 270 is a circuit for controlling the temperature two separate spinning ovens described, in which a main power transformer is used. However, this system has certain disadvantages, in particular that one Bias current (bias current) maintained in the system must be that the grinding arm must be adjusted by hand and that two secondary transformers are necessary in the system.

In US-PS 38 03 385 the supply of two or more heaters described from a main power supply.

The temperature control in this case consists only in that the power supply to a particular heater is only completely switched on or off will.

In US-PS 32 91 969 the supply of various parts is one individual heating element, but a variety of power supplies are used used.

With the device according to the invention, many will be familiar with the state technical systems related problems avoided and, through the Use of semiconductor-equipped circuits, a simplified system of control Supplied by two or more heating elements powered from a single power source will. In short, two temperature control devices are used in the device according to the invention, which are also referred to as temperature controllers in the following, and two variable ones Full wave variable impedance devices are used, around that of a power transformer to two parts of a heating element, for example of a spinning furnace to regulate the electricity supplied.

Figure 1 is a diagram of a first embodiment of the present invention. In this embodiment, a first temperature controller regulates the power delivered by the power transformer, while the second Temperature control device controls the flow of current through two variable full-wave impedance devices regulates to both sides of the heating element.

Figure 2 is a diagram of a second embodiment of the invention in which each full-wave variable impedance device comprises a part of the heating element and each of a separate temperature controller so it is regulated that it supplies current to the relevant part of the heating element gives away. The power transformer is operated with a fixed voltage.

In Figure 1 is a power transformer with a primary coil or winding 13 and a secondary coil or winding 14 shown with a first part 18 and a second part 19 of a heating element 24 connected in parallel is. This heating element can be any heating in which an individual Temperature control of both sides is desired. In practice, however, it represents represent the two sides of a split fiberglass spinning furnace. With the first side 18 of the heating element or spinneret 24, a temperature sensor 17 is connected, for example a thermocouple that receives temperature information from this page of the heating element 24 to a first temperature controller 12, which via the electrical Lines 25 and 26 are supplied with power. This temperature controller 12 was previously to a predetermined fixed target temperature of the first side 18 of the spinning furnace or Heating element 24 set.

This temperature control device regulates according to the received Temperature information the power supply to the primary winding of the power transformer 13. This in turn regulates the total power that the heating element 24 from the secondary winding 14 of the power transformer is available.

With the other side 19 of the heating element is a second temperature sensitive Element 16 connected, which can also be a thermocouple. This element is connected to a second temperature controller 1 via lines 10 and 11. This control device receives its operating current over the lines 60 and 61. This temperature controller was also set to a certain temperature, which is desired for the second half of the heating element 24.

Enlarged or according to the temperature information received the controller 1 reduces the current flowing through each of the two variable full-wave impedance devices 62 and 63 can flow. The full wave variable impedance device 62 preferably includes two half wave variable impedance devices for example thyristors 6 and 7. Similarly, the variable includes full wave impedance means 63 two thyristors 8 and 9. The thyristors 6 and 7 or 8 and 9 are internally parallel switched. The devices 62 and 63 are on the lines 20 and 21 with the Heating element 24 connected in parallel, through lines 22 and 23 they are connected to one another connected in series, and the neutral line 15 forms a connection with a zero point between both sides of the heating element 24. The second temperature controller makes either device 62 or device 63 so largely conductive, as is necessary to allow sufficient bypass flow around the side of the heating element less electricity can flow to maintain the desired temperature needs.

For example, if in practice the page 19 is 100 amps more than the temperature controller makes the page 18 needs to maintain its setpoint 1 the variable impedance device 63 non-conductive while connected to the device 62 supplies such a control signal that a current of 100 amperes around the side 18 can flow around. Obviously, it is cheap to use one as a second temperature controller to use those whose control signal enables continuous control of the facilities 62 and 63, namely from the conductive state in 62 and non-conductive in 63 to full in 63 and non-conductive in 62.1 in the case of use of thyristors this would be a continuously variable ignition signal.

With the help of this embodiment of the invention is in a typical Operating example of a current flow to both sides of a type 2 / G73 spinning furnace, The Seweils 400 produce controlled glass filaments, using as controlling full-wave impedance devices two thyristor pairs are used, which are connected in parallel as in FIG. For the thyristors, for example, the Westinghouse Type 282 TN Pow-R-Disc TM can be used. These thyristors have a nominal flow current of 850 amperes effectively, the average flow current is 550 amps, and you can use one Forward blocking voltage of between 100 and 1400 Volts.

In addition to the basic bypass loop, additional Resistors can be used to increase the sensitivity, or to limit it to achieve the current flow upwards. There can also be additional improvements be built into the control devices in order to achieve the desired sensitivity in close to zero.

Referring to Figure 2, there is a second embodiment of the present invention shown. In this embodiment there is a transformer with a primary coil or winding 50 and a secondary coil or winding 44 electrically with one first part 49 and a second 29 of a heating element 55, for example one Spinning furnace, connected in parallel. The transformer works with a constant, previously set voltage. With the first side 49 of the heating element is a temperature-sensitive element 57 connected, for example a thermocouple, a temperature signal to a first temperature controller via lines 45 40 supplies. This controller is internally supplied with voltage via line 48. According to the temperature information received, the temperature controller sends, which is set to a temperature determined for the first part of the heating element became, a signal on lines 58 and 59 to a full wave variable impedance device 64, which can be identical to the aforementioned devices 62 and 63. Through this the possible current flow through the first side 49 of the heating element 55 is either increased or decreased.

Similarly, the second side of the heating element 29 is a temperature-sensitive element 39, for example a thermocouple connected. This element transmits temperature information via lines 37 and 38 to a second temperature controller 53, which is set to the desired temperature of the second Part 29 of the heating element is set.

The power supply for this control device is via the line 56. This controller sends in according to the temperature information received Signal on lines 35 and 36 to a second variable full wave impedance device 65, which is similar to device 64 and the current flow through the second half of the heating element 29 controls. The two variable full-wave impedance devices 64 and 65 are connected in parallel with the heating element 55 and are across the lines 51 and 52 in series with one another. They are also connected to a zero point between the two sides of the heating element 55 via the line 31.

In this embodiment, each of the temperature controllers 40 and 53 the associated variable full wave impedance 64 resp.

65 control from fully conductive to non-conductive. In this embodiment Each controller regulates the temperature of the associated side of the heating element separately regardless of the regulation of the other side.

Claims (8)

Temperature control device for a two-part heating element. in particular Split fiberglass spinning ovens Claims: Device for maintaining a certain temperature of a first and a second part of an electrical heating element, in which the two parts from the secondary winding one with a primary winding and a power transformer provided with a secondary winding be d a d u r c h g e - indicates that it includes a first circuit with a first temperature control device (12) and a first temperature-sensitive Element (17) so constructed and arranged that the power transformer according to the temperature signals of the first temperature-sensitive element is regulated, the secondary winding (14) of the transformer with the heating element (24) is connected in parallel to include a second circuit a second temperature control device (1) and a second temperature-sensitive Element (16) and first and second variable full-wave impedance means (62, 63), this circuit being designed so that current through the first variable Full wave impedance (62) and the second variable full wave impedance (63) accordingly the temperature signals of the second temperature-sensitive element (16) so flow can ensure that sufficient current is supplied to the second part of the heating element this to keep at a predetermined temperature and that they a circuit portion (15, 22, 23) through which the first full-wave variable impedance means (62) and the second full-wave variable impedance means (63) having a zero point connected between the first part (18) and the second part (19) of the heating element (24) are, the first and the second temperature control device respectively on a certain temperature are set. 2. Apparatus according to claim 1, d a d u r c h g e k e n n -z e i c h n e t that the first and the second variable full-wave impedance means (62, 63) each include two variable half-wave impedance devices. 3. Apparatus according to claim 2, d a d u r c h g e k e n n -z e i c h n e t that the variable half-wave impedance devices thyristors (6, 7, 8, 9) are. 4. Device according to one of claims 1 to 3, d a d u r c h g It is noted that the heating element (24) is a spinning furnace for drawing Glass filament is made from molten glass. 5. Embodiment of the device according to claim 1, d a -characterized by that it includes a first circuit with a first temperature control device (40), a first temperature-sensitive element (57) and a first variable Full wave impedance means (64) arranged to have a current through the first full wave variable impedance means (64) can flow so that sufficient Current is supplied to the first part of the heating element (49) to set it on a predetermined To maintain temperature that they have a second circuit with a second temperature control device (53), a second temperature-sensitive Element (39) and a second variable full wave impedance means (65) includes, which are arranged and connected in such a way that sufficient current is supplied to the second part of the Heating element (29) is supplied to keep it at a predetermined temperature, wherein the power transformer (44, 50) is electrically in parallel with the heating element (55) is connected, and that it includes circuit parts (31, 51, 52) through which the first and second full-wave variable impedance means (64, 65) having a Zero point between the first part (49) and the second part (29) of the heating element are connected, wherein the first and the second temperature control device (40, 53) Are each set to a predetermined temperature. 6. Apparatus according to claim 5, d a d u r c h g e k e n n -z e i c n e t that the first and the second variable full-wave impedance means (64, 65) each include two variable half-wave impedance devices. 7. Apparatus according to claim 6, d a d u r c h g e k e n n -z e i c n e t that the variable half-wave impedance devices thyristors (33, 34, 42, 43) are. 8. Apparatus according to claim 5, d a d u r c h g e k e n n -z e i c Note that the heating element is a spinning furnace for drawing molten glass Fiberglass is.