DE3720972C2 - - Google Patents

Description

The present invention relates to a temperature control device for electrically heated heating cabinets according to the preamble of claim 1.

Such temperature control devices are common and are used in heating cabinets used, such as in the Heraeus product information PEW-B1 "Heat and T drying cabinets, ST sterilizers, UT convection heating cabinets, 5000 "series (5C 1.86 / VN T & D)). Such temperature controllers, also called mecha African temperature regulators work on the principle of liquid expansion. The temperature controller consists of a sensor that is being tested space is arranged, a capillary tube and a membrane. With warming of the sensor in the test room presses the fluid, which is usually an expansion fluid acts on the membrane of a membrane box which is then operated an on / off switch of the heating of the test room. Each after pre-adjustment of the diaphragm, there is a drop  the temperature in Test room via the membrane box and the switch on the test room heating switched or switched off accordingly when the temperature rises.

Such temperature control devices have proven themselves well in use. they are reliable and require no maintenance. The switch that goes over the Membrane of the membrane box is actuated, however, requires a certain Path between the switch-on point and the switch-off point. On the liquid stock in the sensor, the capillary and the membrane box (which the represents actual temperature sensor element), this means that the Temperature must change by a certain amount (hysteresis) by one To effect switching. The commercially available thermostats have a Hysteresis, also called switchback difference, from about 3 to 10 ° C. Conditionally this hysteresis causes temporal changes in the context of the temperature control Temperature fluctuations in the test room. Because the temperature sensor in the test room does not directly record the temperature in the vicinity of the heating, but the temperature that arises in the interior, the temperature fluctuations lie due to the delayed switching on and off of the heating in the interior higher than the hysteresis of the thermostat. An attempt was made to place the temperature sensor in the To be placed near the heater; this does not, however, result Temperature regulated in the interior of the test room, but immediately the Heating temperature.

DE-AS 10 95 019 describes a liquid-filled spring thermostat described several heat sensors, the sensors in a thermal object are arranged at different points to have one over these individual sensors to obtain the average temperature value of the object. For example, one becomes heating water bath described, with a temperature sensor directly on the Heating of the container is arranged while the other temperature sensor rising heat detected in the region of the side wall of the container.

Another type of temperature controller is specified in DE-AS 10 46 922. It relates to a temperature controller with the control current flowing through it for the control process (thermal feedback) Bimetallic links. These bimetallic links are clamped peripherally and work as a membrane that moves when the current is switched on and a switch switches on or off.

From CH-PS 3 15 153 is a temperature control device with a known fluid-filled expansion thermostat with two sensors, one of which is for thermal recycling with one Auxiliary heating is provided in the form of a heating coil. As a feeler parts of the capillary tube can serve. The auxiliary heater is on applied a ceramic body and can with that of the membrane box of the thermostat operated switch simultaneously with the Main heating can be switched on.

The present invention is based on the object of a structurally simple temperature control device using an expansion thermostat to create the the hysteresis of the thermostat, d. H. the delayed switching on and off of the Switch, suppressed.

This problem is solved with a temperature rule device according to the preamble of claim 1 by the features in the characterizing part. Warmed up by these measures there is a small amount of in the capillary tube located fluids, so that after switching on the heating of the test room Switch and thus the heating of the test room is switched off early, before a noticeable temperature change in the usable space is caused by the neten temperature sensor is registered. This arrangement ensures that System the behavior of a quasi-continuous PD controller, the P behavior through the heating power supplied to the capillary tube and the D behavior the time constant of the capillary tube (its mass) can be changed. With this arrangement, the heating of the test is carried out in shorter time intervals room on or off. Despite the use of the simple off expansion thermostats allow temperature fluctuations in the test room of less than 1 ° C.

Part of the fluid in the capillary is heated, which in any Areas outside the usable space of the heating cabinet through which the capillary from the sensor to the Membrane box leads, is available and can be tapped there. There the capillary is kept very thin, can very much in the area of this capillary small sub-volumes of the fluid, d. H. small compared to the fluid volume of the Usable sensor arranged, are heated.  

It is advantageous to heat the fluid, which is preferably is an expansion fluid, parallel to the heating in the utility room switched. This takes place immediately when the heater is switched on Usable space a heating of the heated fluid volume; accordingly the Heating the fluid volume with switching off the heating in the usable space below broken. As a coupling element between the heating of the fluid and the heating in the Usable space, a transformer has proven to be useful for heating of the fluid switches in parallel to the heating of the work space.

The follows Description of an embodiment of the invention with reference to the drawing schematically a heating cabinet with a temperature control according to the invention furnishing shows.

A heater 2 and a temperature sensor 3 are arranged in the useful space of a heating cabinet, designated by the reference number 1 . The sensor 3 is part of an expansion thermostat 4, which comprises a diaphragm cell 5 adjacent to the sensor 3, which is connected via a capillary 6 to the probe. 3 Outside the heat cabinet 1 near the membrane box 5 , a section 7 of the capillary 6 is wound spirally.

The membrane box 5 has an adjustable membrane 8 , the rising or falling pressure of the fluid - this is an expansion fluid from - a power switch 9 , which interrupts the power supply 10 of the heater 2 or turns on. A heater of the spiral section 7 of the capillary 6 is connected in parallel via a transformer 11 to the power supply 10 and thus to the heater 2 of the heating cabinet 1 . This heater is a resistance heater. For this purpose, the capillary is directly connected to the transformer 11 on both sides of the spiral section 7 , which must consist of electrically conductive material, so that the capillary is heated by direct current passage.

By turning on the heater 2 of the heating cabinet 1 , the spiral section 7 of the capillary 6 is simultaneously heated up via the transformer 11 , as a result of which the pressure in the capillary 6 rises due to expansion of the expansion liquid. As a result, the thermostat switches off the heater 2 of the heating cabinet 1 again after a short time interval via the current switch 9 , although the temperature sensor in the useful space of the heating cabinet 1 has not yet registered a noticeable rise in temperature. This rise in temperature in the usable space occurs only after a delay after the heating has given off sufficient heat to the ambient air and thus also to the temperature sensor 3 . Compared to a conventional expansion thermostat, the heating in the work space is switched on and off in significantly shorter time intervals, which means that temperature fluctuations in the work space, even over longer periods, of less than 1 ° C can be achieved.

Claims (4)

1. Temperature control device for electrically heated heating cabinets, in particular for incubators and drying cabinets, with an expansion thermostat filled with fluid, which has a sensor in the useful space of the heating cabinet, the fluid volume with a membrane of a membrane box, through which a switch for the supply of heating power to the usable space can be actuated, is connected via a capillary, characterized in that outside the usable space a partial volume of the fluid in the capillary ( 6 ), which is small compared to the fluid volume of the sensor ( 3 ), simultaneously with the usable space is heated, the capillary ( 6 ) being made of an electrically conductive material and the heating of the partial volume by direct current passage through the associated section ( 7 ) of the capillary ( 6 ). 2. Temperature control device according to claim 1, characterized in that the heated partial volume of the fluid is the volume of a spirally wound section ( 7 ) of the capillary ( 6 ). 3. Temperature control device according to claim 1 or 2, characterized in that the heating of the partial volume of the fluid is connected in parallel to the heater ( 2 ) in the usable space. 4. Temperature control device according to claim 3, characterized in that the heating of the partial volume of the fluid via a transformer ( 11 ) is connected in parallel to the heater ( 2 ) in the usable space.