DE2456906A1 - Thermostatically controlled temperature control unit - uses no auxiliary energy and has a safety thermostat and sensor - Google Patents

Abstract

When certain limit temperatures are exceeded or not attained, or in case of any other disturbance in the control system, the thermostat moves the control element into a safety position and holds it there. The safety device has a safety thermostat (25) operating independently from the main thermostat (21) normally operating the control element. Its sensitive element (29) releases a safety device in its on-the-ready position in case of any of the disturbances, and in case of pressure drop or pressure medium loss in the safety thermostat (25) and its sensor (29).

Description

Therrnostatically controlled regulator, in particular temperature regulator without auxiliary energy The invention relates to a thermostatically controlled regulator, in particular a temperature controller without auxiliary energy, with an actuator of the controller when certain limit temperatures are exceeded or not reached or when other malfunctions of the control system in a safety position or holding safety device.

The thermostatic system of such regulators works in general without auxiliary energy according to the principle of liquid expansion or according to steam pressure or -tension principle. This becomes the expansion fluid space or the tension space one of the temperature sensors influenced by the temperature to be controlled mostly by a Capillary tube connected to the interior of a working body, which by means of a Working pin or other working organ, the actuator of a control valve or the like, overcoming at least one counterforce, in particular the force of a valve spring operated. In the case of a rise in the nature of the tar that exceeds a certain level, this should be the case Control valve can generally be throttled or closed while at one If the temperature drops, the valve spring or other counterforce re-energizes the valve. more opens.

If, for example, a break in the capillary tube or a Damage to the thermostat disrupts the normal operation of the controller or stops, the actuator can often assume an undesired position, the For dangerous situations in the connected systems, see B. if it remains open Valve can lead to overheating or destruction of equipment and apparatus can. In order to eliminate this risk, there are known safety devices use, whose thermostats usually work within an internal pressure range of is not identical to the surrounding atmospheric pressure. Only when the pressure is in Inside the thermostat as a result of a defect in the thermostat system the atmospheric Pressure has reached, the safety device responds and triggers a signal, which is used to move the actuator into the desired safety position to bring, i.e. usually to close the control valve. This function can but can often be detrimental in terms of backup delay.

If, for example, the leak on the thermostat is relatively very small, the regulated temperature can slowly rise to the highest value, before the safety device responds and the actuator in the safety position brings. But then it can often be too late to prevent damage.

It is therefore desirable to be certain that certain limit temperatures not be exceeded, also increase. It is known per se, two in parallel to use working thermostats, which act on two working bodies, so that If one thermostat fails, the other thermostat gnaws, e.g. to prevent the Control valve when the set target temperature is exceeded with the same level of security close.

Both thermostats work in exactly the same way, i.e. respond to the same temperatures. Furthermore, it is already known to arrange a safety thermostat next to the actual control thermostat, which is set a few temperature degrees higher than the normally operating thermostat. This safety thermostat activates a mechanism when the controller thermostat says it and when its set temperature is exceeded, which immediately closes the valve. In this device, although the safety position of the actuator is inevitably brought about when the actual controller thermostat before Safety thermostat fails. If, on the other hand, the safety thermostat fails first, this may not be noticed at all, and a dangerous state can occur if the control thermostat also fails after the safety thermostat. Apart from this, there is no security against the dangers caused by defects in the thermosatic system or by leaks and fluid losses with these control devices. For this purpose, special, additional devices would have to be provided, which would make the controller considerably more complicated and expensive.

The invention is based on the object of a thermostatically controlled To create regulator, in particular a temperature regulator, its thermostatic Safety device offers a higher level of security against all types of danger than the actual controller or main thermostat. In doing so, this effect should be as possible easy way to be achieved.

According to the invention, this object is achieved in that the safety device independent of a main thermostat normally controlling the actuator of the regulator has working safety thermostat, the working body of which is in standby position held safety device both when exceeding or falling below certain Limit temperatures as well as a pressure drop below a certain value or loss of pressure medium in the thermostatic system of the safety thermostat and whose working body triggers.

This ensures that the likelihood of going unnoticed Failure of the safety device is much lower than when the normal working main thermostats. All security functions are provided by a single safety thermostat or its working element exercised, which is not only available when the temperature is too high or too high.

-If you fall below the limit, but also address the loss of F fluid can, with the pressure in the thermostat system only dropping to zero when a certain amount of filling liquid has escaped from the system.

Such a controller can preferably be equipped with a safety device work that can be locked in a tensioned state in a manner known per se Has energy storage, the locking by one of the working body of the Safety thermostat actuatable trigger element can be canceled and its stored Force acts after its release on the actuator of the controller and the same in the Brings safety position. The energy storage device can expediently consist of a mechanical one Energy storage springs exist, the movable spring support bearing of which is controlled by a locking element, e.g. a latch held by the working pin of the working body of the safety thermostat is triggered, namely with a movement of the working pin both in one direction and the other. For example, the Move the working pin particularly far up if a limit temperature is exceeded, while he is in the event of a loss of fill fluid or, if necessary, also with a very particularly sharp drop in temperature at the thermostat moved far down. In both cases, the energy store is released and the actuator brought into its safety position, e.g. the control valve closed.

The dual function of the safety thermostat is of great importance Meaning. About 90 to 95 ß of all thermostat failure causes are failures through loss of filling liquid. The rest is spread across other causes such as constipation or kinking of the capillary tube so that no more filling liquid is transferred is, spring break, clamps or the like. The likelihood that the safety thermostat fails without a signal is therefore 1 - 0.9 = 0.1 times smaller than that of a normal Thermostats. If a normal thermostat has a probability of 10 3 fails per year, then a safety thermostat according to the invention with a Probability of 10 4 ... fail per year. With 10,000 thermostats considered So once a year the safety thermostat before the main thermostat and ten times the main thermostat fails before the safety thermostat. This shows, that the overall safety of a thermostatic RgS controller through the invention is greatly increased.

Further features are explained in more detail below.

In the drawing, the invention is in one embodiment for example illustrated.

The only figure in the drawing shows a temperature controller in longitudinal section with a main thermostat, a safety thermostat and one with the working body the main thermostat and an energy storage device connected, on the left in the open position and the control valve shown on the right in the closed position.

The actuator of the temperature controller is according to the embodiment designed as a single-seat valve.

This consists of a valve housing 1 with an inlet nozzle 2, an outlet stub 5 and a valve passage opening 4, which is from a valve plate or cone 5 blocked or more or less released. The valve disc 5 is carried by a valve rod 6, which is connected to a valve housing 1 The spring housing 7 protrudes and is connected to a spring plate 8 at its lower end is. Between the upper end wall of the spring housing 7 and the spring plate 8 a valve spring 9 is clamped in, which strives to move the valve disk 5 opposite the adjusting force acting from below on the spring plate 8 into its open position bring to.

The spring housing 7 is by means of a union nut 10 with a Energy storage housing 11 connected through which an axially displaceable actuating rod 12 is performed. The upper end of the actuating rod 12 rests against the spring plate 8, while its lower end strikes against the upper end of a working pin 13, which is connected to the bellows base 14 of a working bellows 15. The working bellows 15 dips from above into the interior 16 of a working body 17, which by means of a union nut 13 is connected to the lower part of the energy storage device housing 11 is.

The interior 16 of the working body 17 stands through a capillary tube 19 with the expansion fluid space 20 of a main thermostat 21 in connection. The main thermostat 21 is in a known manner with a setpoint setting device, which consists of a screw spindle 22 and a spring tube plunger connected to the latter 25, and equipped with a pressure reducer 24.

The main thermostat 21 operates the control valve during normal Operation in the usual way. if the temperature at the liquid container of the main thermostat 21 rises above the set value, the expands Liquid in the space 20 and presses the working piston via the capillary tube 19 14 of the working bellows 15 upwards from its lower position shown on the left up to its upper position drawn on the right. The working pin 17 lifts the actuating rod 12, which in turn over the valve rod 6 the valve plate 5 of the control valve against the action of the valve spring 9 in its drawn on the right Moved closed position. If the temperature at the main thermostat 21 drops, then it pulls the expansion liquid together, and the valve spring 9 brings the valve disc 5 back to its open position drawn on the left.

In addition to the main thermostat en 21, there is a safety thermostat 25 provided, the expansion fluid space 26 through a capillary tube 27 with the interior 28 of a second working body 29 is in communication. In the liquid space 26 emerges from above from a spring tube 30 and a piston-like bellows base 51 existing bellows. The force of a spring 32 acts against the bellows base 51, which strives to move the bellows 50, 51 as far as possible into the liquid space 26, so that the liquid pressure in space 26 within of the intended work areas always remains above zero. The desired safety temperature is set with the aid of a screw spindle D3.

The lower end of the screw spindle 55 is not fixed to the Bellows bottom 51 connected, but it only acts as a stop to limit the stroke of the bellows base or the bellows 50, 51 upwards. Furthermore, a Overpressure spring 54 may be provided.

A protective cap D5 is over the upper end of the screw spindle D3 arranged to prevent unauthorized or accidental adjustment of the screw spindle and thus the safety temperature to prevent.

In the liquid space 28 of the working body 29 dips from above forth one consisting of a spring tube 56 and a piston-like bellows bottom 57 Working bellows. A working pin 78 is attached to the bellows base D7 and has a shoulder 39 has. Against the paragraph 59 lies under the action of a spring 40 of the Plate flange 41 one of the upper, thinner part 42 of the working pin at axial slidably surrounding sleeve 45.

The plate flange 41 can move when the sleeve is shifted downwards Finally place 43 against a stop surface 44 of the working body 29. Another The spring surrounding the working pin 59 presses against the bellows bottom 57 from the inside and seeks to move the working bellows 56, D7 together with the working pin 58 downwards.

At the upper end of the part 42 of the working pin 58 is a roller 46 stored, which in large upward and downward movements of the working pin 38 against cam-like inclined surfaces 47 and 48 of a control member 49 abut and the latter can push against the action of a spring 50 to the left. The control member 49 is connected to the left end of a slidably mounted bolt 51, whose right end can snap into a step 52 of a sleeve 53. The sleeve 55 is in the energy storage housing 11 is mounted axially displaceably and loosely surrounds the actuating rod 12. A pretensioned force storage spring 54 presses against the sleeve 53 from below. The upper annular surface 55 of the sleeve 53 can with an upward movement of the same against a collar 56 of the actuating rod 12 push. Finally, the sleeve 53 is with an annular groove 57 into which a pawl 59 mounted on a lever 58 engages can, which through a longitudinal slot 60 of the energy storage housing 11 in the latter intervenes.

The main thermostat 21 and the safety thermostat 25 like below the same temperature influence. If the main thermostat 21 is e.g. If the capillary tube 19 fails to leak, it can exceed when the temperature rises the setpoint no longer close the valve. But this must happen if one certain Fuse temperature is also exceeded. Therefor the safety thermostat provides 25. As long as this safety temperature is not yet is reached, the springs 40 and 45 press the working pin 58 down until the Tellerflansoh 41 abuts against the stop surface 44. The force of the springs 40 and 45 and the spring tube 36 initially overcome the force of the spring 52 and the spring tube 30, so that the bellows base 31 is gradually the lower stop end of the screw spindle 3) approaches and finally hits this stop.

From now on, the pressure in the liquid space 26 rises rapidly above the bis then given by the spring 32 value. Because of the increase in temperature The increase in pressure caused acts in the liquid space 28 of the working body 29 and pushes the working pin 58 upwards. Eventually the roller 46 abuts against the upper inclined surface 47 of the control member 49 and presses the latter against it the action of the spring 50 to the left. The control member 49 pulls the right one End of the bolt 51 from the latching stage 52 of the sleeve 55 and releases the same. so the force storage spring 54 presses the sleeve 55 upwards, the upper annular surface 55 abuts against the collar 56 of the actuating rod 12 and takes it upwards. The upper end of the actuating rod 12 abuts against the spring plate 8 and lifts the Valve rod 6 against the action of the spring 9 upwards, whereby the valve disk 5 closes the valve passage opening.

This safety effect of the safety thermostat 25 can be absent if the liquid system .B. by breaking or damaging the capillary tube 27 there is a leak and fluid is lost. Then the pressure in the liquid spaces 26 and 28 drops more or less rapidly. The working pin 38 moves downward under the action of the springs 40 and 45 until the flange plate 41 is at first comes to rest on the stop surface 44 of the working body 29. Then, however, the spring 45 presses the bellows base 37 and thus the work top 78 even further down, because the back pressure in space 38 decreases more and more as a result of the further loss of fluid. Finally, the roller 46 pushes against the lower inclined surface 48 of the control member 49 and presses the latter against the action of the spring 50 to the left. As a result, the bolt 51 is in turn released from the latching step 52 and the sleeve S1 is released, which is pushed up by the force storage spring 54 and takes the actuating rod 12 upwards via the collar 56. This then causes the valve to close via the valve rod 6. A corresponding effect can also occur if the temperature at the safety thermostat 26 25 drops extremely low. Then, for example, a control valve could be opened to increase the heat supply.

The invention is not limited to what has been described above and embodiment illustrated in the drawings, but includes all Variants within the scope of the invention features. Furthermore, the invention is optional also generally applicable to temperature regulators, their thermostatic system works according to the tension or gas pressure principle.

Expectations

Claims (1)

P a t e n t a n s p r ü o h e Thermostatically controlled controller, especially temperature. controller without auxiliary energy, with the actuator of the controller at Exceeding or falling below certain limit temperatures or in the event of other malfunctions of the control system n a safety device bringing or holding a safety position, characterized in that the safety device is independent of one the main thermostat (21) normally controlling the regulator's actuator Safety thermostat (25), the working body (29) of which is in the standby position held safety device both when exceeding or falling below certain Limit temperatures as well as a pressure drop below a certain value or pressure loss in the thermostatic system of the safety thermostat (25) and its working body (29) triggers. 2. Regulator according to claim 1, characterized in that the safety device in a manner known per se a lockable energy storage device in the tensioned state has, the locking of which by one of the working body (29) of the safety thermostat (25) actuatable trigger element can be canceled and its stored force according to their release acts on the actuator of the controller and the same in the safety position brings. 5. Regulator according to claim 1 and 2, characterized in that the energy store from one arranged between the actuator (6) and the working element (17) of the regulator mechanical energy storage spring (54), the en movable spring support bearing is held in the tensioned position of the energy storage spring by a locking device, which from the trigger element of the working body (29) of the safety thermostat (25) can be brought into its release position. 4. Regulator according to claim 1 to 5, characterized in that the movable Spring support bearing from a concentrically surrounding an actuating rod (12) of the controller and axially displaceable sleeve (55), the end face (55) of which with a stop collar (56) of the actuating rod (12) cooperates, and that the locking member of one slidably mounted bolt (51) is formed, one end of which in a recess or step (52). the sleeve (53) can be locked and the other end with a control member (49) is connected, which two spaced apart, cam-shaped Has inclined surfaces (47, 48), against which a head piece (46) of the in an upper or lower position shifted working pin tod8) of the working body (29) to disengage the latch (51). 5. Regulator according to claim 4, characterized in that the bolt (51) or its control member (49) is under the action of a locking spring (51). 6. Regulator according to one or more of claims 1 to 5, characterized characterized in that the piston or bellows bottom firmly connected to the working pin () 8) () 7) of the working bellows or the like. of the working body (29) of the safety thermostat (25) is under the action of a spring (45), which the piston or bellows base (57) seeks to push into the liquid space (28) of the working body (29). 7. Regulator according to one or more of claims 1 to 6, characterized characterized in that the working pin (38) of the working body (29) of the safety thermostat has a shoulder (39) against which the plate flange (41) one of the upper, remote part (42) of the working pin (58) axially displaceably surrounding, under the action of a spring (40) standing sleeve (4)) until it is at another Displacement of the working pin (38) on a stop surface (44) of the working body (29) hits. 8. Regulator according to one or more of claims 1 to 7, characterized characterized in that in the liquid system (26, 27, 28) of the safety thermostat (25) and des Liquid normally contained in the working body (29) is kept under a pressure above zero at all times. 9. Regulator according to claim 8, characterized in that the piston or a bellows base (31) in a known manner in the liquid space (26) of the safety thermostat (25) diving bellows (O, 31) or the like. under the action of a spring (D2) or a corresponding self-resilience of the spring tube () 0), which the Constantly seeks to push the piston or bellows into the liquid space (26). 10. Regulator according to claim 9, characterized in that the lower End of a known manner to set the desired safety temperature serving screw spindle (55) of the safety thermostat (25) a stop for the piston or bellows base (31) of the bellows (70, 51) or the like. forms. 11. Control valve according to one or more of claims 2 to 4, characterized characterized in that the safety device is provided with a device for re-tensioning the relaxed energy storage device or the relaxed energy storage device spring (54) is. 12. Control valve according to claim 11, characterized in that for Tensioning of the energy storage mechanism or the energy storage mechanism spring (54) can be operated e.g. by hand Clamping lever (58) is provided with a hinged pawl (59) which is inserted into an annular groove (57) of the sliding sleeve (53) can be latched.