DE940068C - Resistance thermometer with low display inertia - Google Patents

Description

Resistance thermometer with low display inertia A version of the for temperature measurements in pressurized media such as steam and feed water used resistance thermometer is constructed in such a way that the temperature-sensitive Thermometerwicklu.ng is embedded in suitable insulators and these of durable Protective tubes are surrounded, which take the entire mechanical stress of the thermometer have to take over. This design is because of the large heat capacity of the thermometer with the protective tube and the resulting relatively long display delay very inconvenient.

Resistance thermometers are already included to reduce the display delay have been built whose temperature-sensitive winding in the form of thin wires or Tape is directly exposed to the medium to be measured. It is also known to provide a meandering sheet metal strip made of nickel with incisions and these To expose the arrangement to the temperature to be measured immediately. With another known design is an insulating layer on the bottom of a metallic plug applied and vaporized a gold layer in the form of a spiral. The gold layer is galvanically brought to a thickness of about 1% 100o mm and forms the temperature sensitive resistor. It's also already a resistance thermometer became known whose temperature-sensitive resistance is low, if Substances are measured should that one. certain conductivity for the electric current, so measurement errors due to the shunt can be avoided by the substance to be measured. To this resistance thermometer a transducer close to the sensor is type-closed; its primary coil has a low one Impedance, and its secondary coil has one to match the measuring instrument high impedance.

The resistance thermometers described last are then, not to use when the temperature is in liquids or gases. of high flow velocity is to be determined and the medium to be measured carries impurities with it. The smallest solids such as dirt, dust and the like settle on the thermometer off and close daduroh: the space between adjacent turns of the ribbon-shaped Spiral or the meander-shaped incisions short, which increases the resistance of the thermometer . changed in an uncontrollable manner and the measurement is falsified. aside from that the thin metal layer of the resistance thermometer is covered by fast-flowing Media as a result of wear and tear and erosion over time, destroyed over time and also as a result the resistance of the thermometer changes.

The difficulties mentioned are eliminated according to the invention by that the temperature-dependent resistance coating on: the bolt in the form of a layered closed envelope is applied. -The resistance value of the sleeve is there of the order of a few milliohms and is so small that all conceivable On the other hand, there are no shunts even with measurements in highly conductive electrolytes Role-play. Also the conductivity of the, which is already noticeable at higher temperatures ceramic insulating materials- is several orders of magnitude lower than the resistance of the thdrmometer. The very small resistance is expediently made by means of a transformer translated. The use of such a transformer for temperature measurement is known per se. The surface of the .temperature-sensitive resistor forming sleeve can. with a mechanically and chemically particularly resistant metallic protective layer, e.g. B. a Hartchromschscht be coated. Wear and tear by fast flowing media make themselves as a result of the opposite to the known thermometers with vapor-deposited layers relatively large thickness of the conductive layer and the hard surface practically not noticeable even after a very long operating time. As a result of the design of the thermometer in the form of a sleeve, a very large one surface that is in contact with the medium to be measured and thus a rapid one Heat transfer achieved.

It is naturally important that the thermometer layer is mechanical and is impeccable with regard to corrosion. Here has a hard chrome plating in both ways Particularly proven in respect. The chromium is very much a resistance material in this respect valuable as it: has a very high temperature coefficient or conductivity. Rhodium plating of the outer temperature-sensitive layer is also recommended.

Naturally, with the smallness of the resistance value for the thermometer Great care is taken to ensure that the leads between the power source and thermometer or relatively low resistance between thermometer and measuring device and no incorrect measurements result due to temperature changes. Therefore, the one in the thermometer branch of the bridge or compensation circuit lying lead resistance made as small as humanly possible and an im Comparative branch lying resistor of the same size arranged in such a way that they both must have the same temperature profile over their length.

In Fig. Z an embodiment of the circuit is drawn. i is the temperature-dependent, very low-eared measuring resistor, which is connected by supply lines 2 and 3 of very strong cross-section with the secondary winding q. of a transformer: 5 is connected. A single transformer 6 with the secondary winding 7 feeds over that Supply lines 3 and &, the comparison branch, which contains the temperature-dependent resistance band 9. He's going to be functional. laid a place of low temperature. The primary windings 6 ', 5' of the two transformers 6 and 5 are used as adjacent branches of a Wheatstone bridge with the other resistors io and ii connected to a suitable alternating voltage be placed. In the diagonal branch of this bridge you can, through, the double coil device with the movable coil z2 and the field coil 13 .eine only on the temperature the pointer deflection dependent on the resistance i.

For this purpose, a directional torque proportional to the operating voltage is required producing short-circuit coil 1q. short-circuited across the capacitor 15 or a choke.

In place of this arrangement with two transformers that are exactly the same Must have incorrect angles, you can also, as shown in Fig. 2, a bridge apply, which contains the low-ear thermometer i and the comparison resistor 9. A current transformer with windings 16 and 17 is located in its diagonal branch are used to produce a high measuring voltage, which is applied to the diagonal a rectifier 18 connected galvanometer i9 acts. In this case 'the Comparative resistances of bridges io and i i: through the secondary coil of a transformer 2o, which is tapped in the middle to connect the diagonal branch. For the purpose of Establishing a relationship between temperature and angle of deflection that is as proportional as possible of the instrument i9, the transformer 2o is designed as a current transformer and over a comparatively large resistor 2 1 connected to the network.

There are, of course, other combinations of circuits and display devices conceivable. The sense of the application of the mentioned circuit is always the high one Transform currents in the thermometer circuit into currents of small magnitude, the the high-resistance windings of the display devices are better adapted and by the Lead resistance between the transformer connected to the thermometer and the display device are not affected.

The resistance thermometer is given a structure which is shown in FIG. 3, for example. A shaft 22 made of steel, thickened at its end, has on its surface an approximately 0.5 ... 2 mm thick insulating layer 23, for example a glaze, with which the resistance layer r is firmly connected, made of iron, nickel or other metals temperature-dependent resistance can exist. This conductor layer is conductively connected on the one hand to the shaft 22 and on the other hand to the screw-in head 2q and, since it completely encloses the shaft, represents an extremely resistant structure. To prevent corrosion or other attacks, it can be protected with a particularly resistant metal layer, e.g. . B. by hard chrome plating, rhodium plating, silver plating. Non-metallic protective layers, silver-chloride, oxide or phosphate layers may only be arranged in a very thin layer, because otherwise they increase the display delay and reduce the current carrying capacity. The supply lines between the transformer and resistance thermometer, denoted by 2 and ä in FIGS. R and 2, which compensate each other in the circuit, are expediently arranged in the form of thick rods or concentric tubes that connect the screw-in head 24 of the thermometer with the connection head 25 arranged in the connection head Connect transformer 2o. They are designed in such a way that they always have a matching cross-section within the temperature gradient which arises between the screw-in head and the connection head, so that their total resistances are always the same regardless of the temperature distribution. The lengths of these compact lines are chosen to be so large that at the highest temperature of the connection head the transformer does not become excessively hot due to the resulting heat gradient.

Two of the supply lines can also reach the lowest end of the temperature-sensitive Ladder to be brought down. The supporting shaft of the thermometer is then made formed a bolt and a tube surrounding it, which at the lower end with is welded to him, but for the rest of the length, for example by potting is insulated against him with a glaze.

When using glazes for insulating the conductors against each other you can take advantage of their extraordinarily high compressive strength. The den temperature-sensitive resistance bearing bolt 22 is thereby in the screw-in head 2.4 of the thermometer by means of a threaded ring 26 against being pushed out through the high tension, medium secured. With the correct arrangement and selection of the metallic Building materials manage to seal the glaze when it colds under all-round compressive stress to put. As a result of the absence of tensile stresses it turns out to be such Arrangement has an extremely high mechanical strength.

Another method of fastening the mutually insulated Layers of the thermometer consists in placing the tubes or bolts on their surface, which should be thermally or electrically insulated, to phosphate them and then together to deform to a press fit, which can be done, for example, by turning.

A particularly simple process for making the thermometer consists in glazing the bolt carrying the thermometer layer on the To apply a layer of glaze in a known manner, for example a very thin layer of platinum and electrolytically deposit a hard chrome layer on this. In the application the electrolytic chrome plating of the temperature-sensitive layer can be one to produce a certain resistance by the resulting resistance: within .Measures the chrome plating bath continuously and when it reaches the temperature corresponding to the bath temperature Resistance stops the electrolysis.

Such delay-free and heavy-duty resistance thermometers have, for example, been used to regulate any temperature without oscillation particularly proven in thermal engineering systems. The great energy consumption of the thermometer enables pneumatic or hydraulic regulators to be controlled without amplification directly from the moving coil-of the bridge- influenced by the thermometer or compensation arrangement. For example, a baffle plate is placed on it expediently in such a way that they each have a nozzle through which the control medium flows more or less covered after the position of the movable coil. Preferably the direction of movement of the baffle is perpendicular to the direction of the nozzle leaving flow of the control medium arranged so that no disturbing torque the moving coil is exercised. In this way the known ones are connected Advantages of electrical control, its lack of delay in measurement and remote transmission the measured values, the simple wiring, the unlimitedness with regard to the distances that can be bridged with the simplicity of assigning the actuators, z. B. the valve positions to the position of the control members, which by means of pneumatic Power amplifier can be implemented reliably with relatively little effort permit; in particular, however, one achieves through the use of those constructed according to the invention Resistance thermometer in this combination the practically instantaneous and Sufficient energy-rich determination of measured values for continuous control.

Also for the direct control of power gates for electric ovens the thermometer can be used without further ado. The voltage transformed in current transformers in the equalizing circuit of the bridge circuit can uri amplified on the Control grid the power gate or gates are given.

Claims (7)

PATENT CLAIMS: i. Resistance thermometer with a temperature-dependent Resistance coating on a bolt-shaped support, the measuring current of which passes through a transducer is transformed, characterized in that the temperature-dependent resistance coating is applied to the bolt in the form of a layered, closed shell. 2. Resistance thermometer according to claim i; characterized in that the thermometer and its converter are in a bridge circuit in which the influence of the converter winding and the connections between transducer and thermometer by symmetrical design is compensated. 3. Resistance thermometer according to Claim 2, characterized in that that the leads to the temperature-sensitive layer-shaped resistor there are three bolts that connect the connection head with the screw-in thread head, of which at least two are arranged symmetrically and have such a cross section have that their resistances are not included in the temperature measurement, independently the temperature drop between the thermometer and the connection head. q .. Resistance thermometer according to claim i, characterized in that the insulation of the tubular resistor against the concentric support by enamelling or pouring with glass rivers is carried out. 5. Resistance thermometer according to Claim 4, characterized by such a large layer thickness of the enamel that the resistance value of the outer shell is Temperature variation over time independent of the temperature of the metallic support is. 6. Resistance thermometer according to claim i, characterized in that it is in a bridge or compensation circuit is used in which the. won Compensating current is fed unamplified to an electromagnetic measuring system, which directly the moving part of a pneumatic. or hydraulic regulator controls. 7. Resistance thermometer according to claim i, characterized by the application in a bridge or compensation circuit whose compensation voltage is not amplified forms the ignition voltage of a current gate circuit. B. Resistance thermometer according to claim i, characterized in that a thin-walled, preferably made of iron Tube is used as a conductor, which is covered by a preferably metallic protective layer is made mechanically and chemically resistant. G. Resistance thermometer according to claim i, characterized in that the temperature-sensitive surface layer or their outer surface, which is exposed to the medium, is made of chrome. ok procedure for producing a resistance thermometer according to claim i, characterized in that, that a ceramic, preferably consisting of a glaze insulating layer through Deposition of a thin metal coating is given a conductive surface on which electrolytically preferably a hard chrome layer as a temperature-dependent conductor is applied. i i. Method for manufacturing resistance thermometers according to Claims g and io to a specific resistance value, characterized in that that - in the electrolytic application of the conductive layer the correct one Layer thickness resulting in resistance value by measuring the resistance value within of the chrome plating bath is determined. Attached publications: »Archive for technical measurement «, V2167-i; German Patent No. 322357; “Temperature, its measurement and control in science and industry «, 19q.1, - p. 1009; G. K e i n a t h, "Electrical temperature measuring devices", 1923, pp. 8o and 81 ..