DE1065024B - Circuit arrangement for regulating the temperature of components - Google Patents

Description

The invention is concerned with the task of determining the temperature of a component in a circuit arrangement to regulate the electrical communications technology and this preferably within a predetermined to maintain the permissible range of change if the ambient temperature fluctuates significantly having. A circuit arrangement has already been proposed in which of the known Principle use is made, the temperature of at least one component, for example a piezoelectric crystal, automatically controlled by means of a temperature-sensitive organ to regulate electrical heating (German patent specification 969 833). In contrast to previously known Arrangements in which either a heating element is used for each individual body to be kept temperature-stable and associated with a special temperature-sensitive organ that is in thermal contact with this body became or several such bodies together with a single temperature-sensitive organ were arranged in a common thermostat and with good thermal contact with each other, should according to the idea of the earlier proposal mentioned, the components in separate from each other Socket body to be inserted from each other adjusted thermal behavior, which in series or Parallel connection included heating resistors connected to one another by the control unit switched on and off heating circuit are fed. The heating resistors in the sockets these components can then be connected to the common by a single temperature-sensitive organ Heating current source can be switched on and off from it, without the individual control of each component required effort is necessary and without the difficulties encountered in Samm el thermostats occur when replacing a single component.

The invention relates to an improvement of the arrangement specified in the older proposal, in which a special heating resistor is assigned to each of the socket bodies which are separate from one another. While in the mentioned older proposal mainly an embodiment of the specified arrangement is dealt with, in which the temperature-sensitive organ like one of the components to be controlled is housed in a special socket body, the invention relates to another embodiment in which the special socket body for the temperature-sensitive organ is omitted. To this end, the invention is based on the circuit arrangement of electrical communications engineering dealt with in the older proposal with at least two components, for example piezoelectric crystals, circuit arrangement for regulation
the temperature of components

Applicant:
Telefunken GmbH,
Berlin NW 87, Sickingenstr. 71

Dipl.-Ing. Rudolf Engel, Berlin-Frohnau,
has been named as the inventor

whose temperature is controlled by means of a control device responding to temperature changes electrical heating is regulated and which in separate socket bodies from each other adjusted thermal behavior are inserted, which are connected in series or in parallel Contain heating resistors from a heating circuit that is switched on and off by the control unit be fed. According to the invention, the control device should respond to the temperature-related change in resistance a group of interconnected heating resistors address at least two components. - In this arrangement, the resulting resistance is a group of interconnected Heating of the individual components made the initial value of the control, to which the control element responds. A thermal contact between the socket bodies is necessary for the adjustment to the same Steady-state temperatures not required; expediently, such contact is even avoided, to inequalities in the thermal behavior of the to switch off individual socket bodies among each other.

There are several possibilities for deriving the control of the regulating element from the resulting resistance of a heater group. For example, the arrangement can be made so that the group of temperature-dependent heating resistors is traversed by the current of a discharge tube, which - if necessary via intermediate elements - is controlled by the voltage across the resistors, in such a way that when the resistance temperature increases, the Discharge current is reduced. A particularly sensitive control results when the temperature-dependent resistances of the individual socket bodies are interconnected in two groups, the resulting groups

909 627/285

Resistors are arranged in two opposite branches of a bridge circuit, of one diagonal of which the electrical variable used to control the heating is taken. To the The heating resistor can balance the electrical work carried out on a single socket body a parallel or series resistor must be connected.

It should be noted that it is known from U.S. Patent 2,429,453, the heating resistor of an electric heating pad from two parts with different temperature coefficients and the resistance parts in the adjacent branches one in the one diagonal to arrange with alternating current fed resistor bridge, from the other diagonal that for the control the control variable serving to switch the heating current on and off is taken. The two Resistance parts are in intimate thermal contact with each other and with the enveloping one Pillow body, so that this patent specification could not be taken from the suggestion, several To accommodate components in separate socket bodies and by interconnection their temperature-dependent heating resistors one of the resistance value of the interconnection to create outgoing regulation of the heating current flowing through the same interconnection.

It is also assumed to be known in the case of a circuit arrangement for temperature control temperature-dependent measuring resistors in the same direction in two opposite branches of one To arrange bridge circuit, of which one diagonal is the electrical one used to control the heating Size is decreased. An example of such an arrangement is given in the United States patent 2,572,293, but only in the case of heating control for an apartment depending on one the inside temperature and a measuring resistor exposed to the outside temperature, these resistors do not represent heating resistors at the same time.

From US Pat. No. 2,524,886 it is also known per se, in the case of electrically separated, but in Heat connection with each other located heating and measuring resistors the measuring resistor in the To lay the cathode circuit of a grid-controlled discharge tube, thereby reducing the discharge current as a function influenced by the respective temperature. However, there are also none from this publication Suggestions for the solution of the problem can be taken, the temperature of a plurality of mutually separated To regulate socket body for electrical components.

In the drawing, FIGS. 1 to 3 show, in the form of circuit diagrams, arrangements according to the invention Fig. 4 shows a piezoelectric component with a temperature-sensitive heating coil for an arrangement according to the invention.

In Fig. 1, 1 is the resistance formed by the interconnection of a group of temperature-dependent heating resistors, it being assumed that each individual heating resistor is in good thermal connection with the associated body which is to be kept temperature-stable. In order to obtain the lowest possible heat gradient between the resistance wire and the body mass, it is advisable to embed the resistor, for example, in the socket material and to distribute the winding so that as much of the heat-emitting surface of the body as possible is heated. It is also advisable to use relatively large cross-sections

to work so that one can manage with low excess temperatures of the heater. It is of course not achievable that the temperature of the heater is equal to the temperature of the heated body. But this is also not necessary, since the intention is not to measure the temperature, but rather to regulate it; there can be a certain amount of space between the heater and the body interior, which is to be kept temperature-stable Temperature difference are allowed.

The resulting resistor 1 is traversed in the arrangement according to Fig. 1 of the current of a grid controlled discharge tube 2, which is controlled by the voltage across the resistor, in such a sense that, with an increase of the resistance temperature of the discharge current is reduced if for the source 3 a constant voltage and for the resistor 1 a sufficiently large positive temperature coefficient of the resistor is assumed. It can be seen that a smaller current is established for an increased resistance 1 , so that the effect is in the right direction. Even if the limits of the temperature control cannot be kept very narrow with the circuit according to Fig. 1, an effect in the desired direction is sufficient for some purposes. The voltage occurring across the resistor 1 can be amplified in one or more amplifier stages to increase the control effect before it controls the discharge tube located in the heating circuit.

In Fig. 2, the temperature-dependent resistor 1, which can be formed, for example, by the resulting resistance of a parallel or series connection of the individual heating resistors, is in a branch of a bridge arrangement, on one diagonal of which the heating current is supplied from the source 3 and from the other Diagonal the electrical size used to control the heating is removed. For this purpose, the relay 4 is used, which bridges the resistor 8 in the heating circuit through its normally closed contact 9. This changes the heating current between two values. It is assumed that the resulting resistor 1 has a positive temperature coefficient and that at its lower limit temperature the bridge formed from the resistors 1, 5, 6, 7 is almost balanced, so that the relay armature is in the rest position and the contact 9 closed is. The larger value of the heating current then flows, so that the temperature of the body connected to 1 increases. The bridge equilibrium is thereby increasingly disturbed, but the relay 4 does not attract its armature immediately, but only in the event of such an equilibrium disturbance, which causes a current of the magnitude of the so-called pick-up current to flow through the relay. When the armature is tightened, the contact 9 is opened, so that the resistor 8 now acts as a series resistor and the heating current is reduced to its smaller AVert. The current in the bridge diagonal in which the relay winding 4 is located is correspondingly reduced. Since the current value at which the relay armature drops again can be much smaller than the pick-up current if the relay is designed accordingly, this lower heating current value can be dimensioned sufficiently large by selecting the resistance value of 8 to ensure that the relay armature drops again immediately after pick-up ( the so-called rattling). After some time, the temperature of the individual

nen parts of 1 connected body so far that the resistance bridge approaches its balance again. The relay armature drops out again, as a result of which the initial state is restored, and the period of the higher heating current value begins again. Since the times of switching in one direction and the other are only determined by the temperature of the body to be kept temperature-stable, this circuit is suitable for keeping the temperature of these bodies between two limit values that are independent of the ambient temperature.

In Fig. 3, the heating voltage 13 is fed via the choke coil 14 and the contact 9 to two adjacent bridge corner points, between which the resulting resistor 1 is located. Furthermore, an auxiliary voltage 15 used for the automatic control is supplied to one bridge diagonal and the electrical variable used for control is taken from the other bridge diagonal. In principle, the heating voltage 13 and the auxiliary voltage 15 can be of such different frequency that they can be separated from one another by reactances or by filter elements formed from such. In the circuit according to Fig. 3, one, namely the heating voltage 13 ^, is a direct voltage, while the other, the auxiliary voltage 15, is an alternating voltage. Since the resistor group 1 is heated by a direct current and the electrical control variable is derived by means of an alternating current, the two currents can be separated by capacitors and inductors. The bridge diagonal formed by the AC voltage source 15 is blocked for direct current through the capacitors 16 and 18; Likewise, the parallel path via the bridge resistors 10 and 11 is closed to the direct heating current by the capacitor 17 . The bridge branch opposite in the bridge of the temperature-dependent resistor group 1 is formed by the resistor 10 which can be changed for the purpose of setting the control value of the temperature. The bridge branches adjacent to the temperature-dependent resistor group 1 contain the resistors 11 and 12, which are larger than the resistance I _j and, if possible, in such a ratio that the current driven by the auxiliary voltage 15 through the bridge branches does not significantly heat the heating resistor group 1 contributes. To decrease the control variable, the cathode and control grid of a discharge tube are connected to the corresponding bridge diagonal, with the heating direct voltage 13 forming the required negative grid bias voltage, by means of which the tube is set to an operating point near the lower bend of the grid voltage-anode current characteristic curve, so that it works as an anode rectifier. The alternating voltages occurring on the bridge diagonal in the event of disturbed balancing are rectified by the tube so that a relay located in its anode circuit can be made to respond by the rectified currents.

The circuit according to Fig. 3 has the advantage over the circuit according to Fig. 2 that the activity of the relay 4 controlling the heating is not dependent on the heating current, so that no special requirements for maintaining the control process as in Fig. 2 need to be done. The heating current can therefore be reduced to zero in the switching stage corresponding to its lower value; it can therefore be completely interrupted by the contact 9. The purpose of the throttle 14 is to block the parallel path to the resistor 1 via the heating current source 13 for alternating current.

If it is assumed that the resistance bridge I _j IO _j , II _j 12 is almost balanced for the lower limit temperature of the control range, the armature of the relay 4 is in its rest position and the contact 9 is closed. The resistor group 1 is therefore heated, so that the temperature of the body thermally connected to its partial resistors increases. The balance of the bridge is impaired until the diagonal voltage on the grid of the tube is sufficient to cause the relay 4 to attract its armature via the tube. This opens the contact 9. Resistance group 1 now continues to form the temperature-sensitive organ; their resistance value, which under the influence of the progressive cooling again approximates the value suitable for the bridge adjustment, forms only the starting value for the control in this time segment and has no function as a heating resistor. At a limit value which can be determined by the setting of the resistor 10 , the relay 4 releases its armature again, so that the initial state is restored.

In Fig. 4, a piezoelectric component is shown which, due to its special design, is well suited to be used in an arrangement according to the invention. In the capsule formed from the cup-shaped part 19 and the cover-shaped part 20 , a quartz crystal is located between two electrode plates held under slight pressure by a spring, which is to be kept at as constant a working temperature as possible. For this purpose, the heating resistor 21, designed as a temperature-dependent resistor in the manner described above, is arranged as a partial resistor of the mentioned resistor group 1 in the form of a winding in a recess of the part 19 . The parts 19 and 20 are made of ceramic material, so that it is possible to embed the preferably bifilar winding 21 in the material of the socket body or to connect it thermally to the latter by means of a glaze compound.

If it is ensured that the body is regulated in this way in common in its temperature with regard to the heat exchange with the ambient air and their radiation properties are designed similarly, the same operating temperatures of the individual bodies can be monitored by monitoring can be achieved by means of a single control device. Because the individual bodies are not in thermal Need to be in contact with each other, they can purely according to the special needs of their intended use, be arranged in the devices, for example, in high-frequency circuits according to the requirements of favorable line routing. The regulation takes place with series connection according to an average value of the temperature-dependent resistances, with parallel connection according to a mean value of the conductance. If on one in terms of heat exchange for the individual bodies roughly equivalent arrangement, for example at the same distance from walls and their through openings are respected, a sufficiently consistent temperature profile can be achieved can be achieved in all jointly regulated bodies. If desired, can be in one Bridge arrangement according to the principle of Fig. 3, the temperature-dependent heating resistors in two groups

Claims (17)

pen are summarized, which are arranged in two opposite bridge branches. In the case of simultaneous series or parallel heating and control of several bodies, it is by no means necessary that these are designed to be completely identical to one another. Bodies of different sizes can also be grouped in this way. If, for example, piezoelectric resonators are given for natural frequencies that are far apart or loads of different magnitudes, which also require correspondingly different socket bodies, then the different heat capacities and heat losses can be taken into account by dimensioning the heating resistors. By means of a connected parallel or series resistor, the electrical work supplied to each individual body in the heating-up intervals can be adjusted so that the temperature limits are practically matched for all bodies, even if the individual bodies are of different sizes. As a result of this adaptability to changing requirements, the invention is particularly suitable for devices in high-frequency communications technology which use a large number of quartz resonators. Claim 1. Circuit arrangement of electrical communications engineering with at least two components, For example, piezoelectric crystals, the temperature of which by means of a temperature change responsive control device automatically controlled electric heating is regulated and which in separate socket bodies of mutually matched thermal behavior are inserted, which in series or parallel connection interconnected heating resistors that are fed by a heating circuit that is switched on and off by the control unit are, characterized in that the control device to the temperature-related change in resistance a group of interconnected heating resistors responds to at least two components. 2. Arrangement according to claim 1, characterized in that a direct thermal contact is avoided between the socket bodies. 3. Arrangement according to claim 1 or 2, characterized in that the temperature-dependent Heating resistors are connected together in two groups, their resulting resistances are arranged in two opposite branches of a bridge circuit, of which The electrical variable used to control the heating is taken from a diagonal. 4. Arrangement according to one of claims 1 to 3, characterized in that for balancing the electrical work supplied to a single socket body the heating resistor a parallel or series resistor is connected. 5. Arrangement according to claim 1, characterized in that the group of temperature-dependent heating resistors (1) is traversed by the current of a discharge tube (2) which - if necessary via intermediate members - is controlled by the voltage at the said resistors, in such a sense that when the resistance temperature increases, the discharge current is decreased. 6. Arrangement according to claim 5, characterized in that the voltage occurring on the group of heating resistors (1) is amplified in one or more stages before it controls the discharge tube located in the heating circuit. 7. Arrangement according to claim 2, characterized in that the group of heating resistors (1) is switched on in the cathode circuit of a grid-controlled discharge tube (2) . 8. Arrangement according to one of claims 1 to 7, characterized in that the heating is controlled by means of a relay (4) which changes the heating current between two values through a contact (9). 9. Arrangement according to claim 8, characterized in that the lower value of the heating current results in the event that the relay armature is tightened. 10. Arrangement according to claim 9, characterized in that the lower heating current value is dimensioned sufficiently large to allow the relay armature to fall off again immediately after tightening (Rattling) to avoid. 11. Arrangement according to claims 1 and 3, characterized in that the heating voltage (13) is fed to two adjacent bridge corner points, between which the group of heating resistors (1) is, and that an auxiliary voltage serving for the control (15) to one Bridge diagonal supplied and the electrical variable used for control is taken from the other bridge diagonal. 12. The arrangement according to claim 11, characterized in that the heating voltage (13) and the auxiliary voltage (15) are of such different frequency that they can be separated from one another by reactances or filter elements formed from such. 13. Arrangement according to claim 11 or 12, characterized in that one voltage is a direct voltage (13) and the other is an alternating voltage (15) . 14. Arrangement according to claim 13, characterized in that the heater by means of direct current, the electrical control variable is derived by means of alternating current. 15. Arrangement according to one of claims 1 to 14, characterized in that the group of temperature-dependent heating resistors (1) opposite bridge branch is formed by a variable for the purpose of setting the control value of the temperature resistor (10) . 16. The arrangement according to claim 15, characterized in that the two of the group of temperature-dependent resistors (1) adjacent bridge branches are formed by resistors (11, 12) which are greater than the temperature-dependent resistance, preferably in such a ratio that that of the Auxiliary voltage (15) current driven through the bridge arms does not contribute significantly to the heating of the heating resistor (1) . 17. The arrangement according to claim 16, characterized in that the cathode and control grid of a discharge tube are connected to the corresponding bridge diagonal to decrease the control variable, the direct heating voltage (13) preferably serving as a negative grid bias.