DE19755200C2 - Control arrangement for at least two thermostatically operated valves - Google Patents

Description

The invention relates to a control arrangement for at least two thermostatically operated valves, with one activation unit for each valve and one common setting device that has a single capillary tube connection with the workrooms of all Activation units is connected.

In a known control arrangement of this type (DE 26 20 640 B2) acts as a common setting device device that also serves as a temperature sensor three heating valves, the flow through each Affect radiators. So that the workrooms of three activation units over a single capil larrohr connection can be supplied, it must Branch capillary tube. Such branches are external extremely problematic. For one, it is difficult and expensive, three capillary tube ends for example via a T- Piece together. On the other hand, this is Connection sensitive to tensile forces.  

These branch problems can be solved according to DE 26 19 413 C3 thereby preventing everyone from going to the work rooms the capillary tubes leading to the activation units start the adjustment device. But this leads to a doubling or multiplication of the capillary Pipe connections on the adjusting device, being too take into account that often another capillary pipe leading to a remote sensor is to be connected. You also need in this parallel connection in in most cases a longer length of the used Capillary tube. This increases the system sensitivity speed that can cause a certain incorrect regulation, because there is a risk that the filling medium of the system is heated due to the temperature of the pipe environment and this uncertainty is proportional to the pipe length affects.

DE 195 34 181 A1 includes an activation unit known an expandable work space that is outdoors End is completed by a cup-shaped element. A capillary tube coming from a remote sensor is included its end approximately radially through the cylindrical wall of the Pot-shaped element and there in the usual white se attached, so soldered or welded.

The invention is based, with a Re gel arrangement of the type described at the outset to avoid the branch points.

This object is achieved in that a first capillary tube from the capillary tube connection a first work space and a second capillary tube from the first work space to a second work space leads.  

There are therefore no longer any separate branches. Rather, it is sufficient to have two capillary tube ends over one To connect the work area with each other. This makes it easier and cheaper to manufacture. In addition, one without existing component used for connection, the has a fixed place on the associated valve, whereby reduced sensitivity to tensile forces becomes. You can also usually use the new shape the total length of the capillary tubes is considerably reduced ner hold up as with the parallel arrangement DE 19 413 C3, what the sensitivity to un desired influences reduced.

In a further embodiment, it is ensured that mind At least one more capillary tube from one to the one setting device connected to a workspace leads to further work space. This way three and more valves can be adjusted at the same time.

It is recommended that the adjustment device only a second capillary tube connection for one Has remote sensor. This applies if the setting pres not designed as a temperature sensor is.

It is constructively favorable that at least the first Working space at least two capillary tube ends a zy Push through the cylindrical wall approximately radially. On a sol Chen cylindrical wall can be easily Connect two or more capillary tube ends.  

It has the particular advantage that two capillary tubes which are offset from each other by 180 °. Tractive forces that for example when mounting on a capillary tube end act rectilinearly on the second capillary tube broadcast at the end.

It is advantageous that the to the work area closing sections of the capillary tubes through casing parts are supported. This will make the sweat place additional between capillary tube and work space protected against bending.

Furthermore, it is recommended that the work rooms removable from the activation unit and independent of the valve type are equal to each other. The fitter can therefore freely choose which valve type it which type assigned to the room. Since at least the adjacent parts the activation unit must be of the same design, can be many components in different com use combinations so that the storage ge small can be held.

It is particularly favorable that a heating valve and a refrigeration valve from the common adjustment device are operable. With this rule arrangement you can egg Operate an air conditioning system at which the temperature increases the heating valve closes and the cooling valve opens.

The second capillary tube is preferably a multiple ches longer than the first capillary tube. So under different lengths have proven themselves in practice. The first capillary tube leads to a valve that closer the adjuster is attached as the second Valve. The second capillary tube extends up to that  second valve, even if this is a greater distance from the adjustment device.

The invention is based on one in the Preferred embodiment shown in the drawing described in more detail. Show it:

Fig. 1 shows schematically an embodiment of a control arrangement OF INVENTION to the invention,

Fig. 2 is an activation unit for a refrigeration valve with developed working space,

Fig. 3 shows an activation unit for a Heizungsven valve with a work space and

Fig. 4 shows a section through the activation unit for a heating valve.

The control arrangement illustrated in FIG. 1 has a setting device 1 , a remote sensor 3 connected to it via a capillary tube 2 , an activation unit 4 for a heating valve that closes when the temperature rises, and an activation unit 5 for a cooling valve that increases with the temperature opens up. The adjusting device 1 is connected via a capillary tube 6 to the working space 7 of the activation unit 4 and this working space 7 via a capillary tube 8 to the working space 9 of the activation unit 5 . The capillary tubes 2 and 6 lead to an adjustment device arranged in an adjustment space 1 , the volume of which can be changed with the help of the rotary knob 10 . The entire system is filled with a liquid that expands with increasing temperature. The remote sensor 3 measures the actual temperature; the set temperature can be changed by changing the volume of the setting room.

The setting device 1 can, for example, have a structure as shown in DE 195 34 184 C2. In many cases, the remote sensor 3 ver dispensed and the adjusting device 1 will be used as a temperature sensor.

The activation units 4 and 5 are different because the refrigeration valve must be reversed, as shown in DE 26 19 413 C3. Nevertheless, the working spaces 7 and 9 are structurally the same, so that the activation units 4 and 5 can be exchanged for one another.

As FIG. 4 shows, the working space 7 is essentially delimited by a corrugated tube 11 and a cup-shaped element 12 with a cylindrical peripheral wall 13 . This is penetrated by the end 14 of the capillary tube 6 and on the opposite side from the end 15 of the capillary tube 8 . The Kapil larrohrabschnitte adjacent to the working space 7 are covered and supported by housing parts 18 , so that no bending forces on the Kapil larrohrenden 14 , 15 can be exerted. Such Ge housing parts are known from DE 195 34 181 A1. On the construction of the working space 9 corresponds to this construction, but one capillary tube end is omitted.

It can therefore be seen that a single capillary tube connection 16 is sufficient to connect the working spaces 7 and 9 of all actuation units 4 and 5 to the adjusting device 1 . And if a remote sensor 3 is present, there is only a second capillary tube connection 17 .

The capillary tube 6 is shorter than the capillary tube 8 . For example, the capillary tube 6 has a length of 4 m and the capillary tube 8 has a length of 11 m. The En the 6 and 8 are soldered or welded to a solid, here cylindrical, wall 13 . This gives a total length of 15 m. The valve that is closest to the adjusting device 1 receives the activation unit 4 . The valve further away receives the activation unit 5 . It is no problem to watch the refrigeration valve as the first valve, since the work rooms are interchangeable. Of course there are also applications in which it is cheaper to choose the first capillary tube longer than the second capillary tube.

The term "work space" does not only include the through movable walls, such as bellows, corrugated pipe or membrane, limited space, but also all in ver binding, the activation unit firmly assigned ordered terminal rooms.

Instead of regulating a refrigeration valve and a heating valve, you can also have several similar valves in similar Control, for example several heating valves, that each control a radiator.

If more than two activation units are used, a further capillary tube can be led from the work space 7 or from the work space 9 to another work space.

The embodiments shown can be varied in many respects without departing from the basic idea of the invention. So the work space can be provided with two fixed nozzles into which the ends of the capillary tube 14 and 15 are inserted. He ste capillary tube 6 can also be made in one piece with the second capillary tube 8 , the section penetrating the working space being provided with an opening.

Claims (6)

1. Control arrangement for at least two thermostatically operated valves, with an activation unit for each valve and a common setting device, which is connected via a single capillary tube connection to the working spaces of all activation units, characterized in that a first capillary tube ( 6 ) from the capillary tube - Connection to a first work space ( 7 ) and a second capillary tube ( 8 ) from the first work space ( 7 ) to a second work space ( 9 ) leads that we at least in the first work space ( 7 ) two capillary tube ends offset by 180 ° ( 14 , 15 ) a cylindrical wall ( 13 ) approximately radially, and that the working spaces ( 7 , 9 ) from the actuation unit ( 4 , 5 ) can be removed and are the same regardless of the valve type. 2. Control arrangement according to claim 1, characterized in that at least one further capillary tube leads from a to the adjusting device ( 1 ) closed work space to a further work space. 3. Control arrangement according to claim 1 or 2, characterized in that the adjusting device ( 1 ) has a second capillary tube connection ( 17 ) for a remote sensor ( 3 ). 4. Control arrangement according to one of claims 1 to 3, characterized in that the sections of the capillary tubes ( 6 , 8 ) adjoining the working space ( 7 , 9 ) are supported by housing parts ( 18 ). 5. Control arrangement according to one of claims 1 to 4, characterized in that a heating valve and a cooling valve from the common setting device ( 1 ) can be actuated. 6. Control arrangement according to one of claims 1 to 5, characterized in that the second capillary tube ( 8 ) is several times longer than the first pillar tube Ka ( 6 ).