DE19729747C2 - Device for distributing a liquid heat transfer medium - Google Patents

Description

The invention relates to a device for distribution len of a liquid heat transfer medium of a building tion and / or cooling system between one or more Heat sources and several with falling temperature levels subordinate heat consumers with one each Flow and a return for the heat transfer medium, the all on a structurally uniform distribution unit can be connected.

For heating or cooling systems where only one heating or Refrigerator and only some consumers connected are the distribution of the heat transfer medium unproblema table. Different valve types are used for this puts. Shut-off valves are used, which are the heat or Shut off or open cold flow in one direction. Such Shutoff valves can also be used in a manifold Valve group can be arranged as you would with a sub Distribution of several heating circuits, for example with egg  underfloor heating. Here you have a first one Distribution strip with a common inflow to all Ab shut-off valves, each with a specific heating circle is supplied. Via a second distributor follows the reflux of the heat transfer medium, which also is influenced by shut-off valves. With these systems the inflow and the backflow valves can not accommodate a common distribution rail because would mix cold and warm energy flows here. On can put simple shut-off valves in the known Distribution systems also more complex three-way valves or Four-way valves are provided to advance on to be able to branch different customers or two streams of the heat transfer medium in two different directions to steer.

With a device of the generic type you have it to do with a distribution system in which the at least one ne heat source and the heat consumers a different Show temperature level, which is why the appropriate Auf switching the heat transfer medium to one or more other heat sources on the one hand and on the heat consumers on the other hand is associated with considerable effort, because above all a very high number of individual valves is required. The problems existing here are still difficult because some heat consumers at the same time can take over the function of a heat source. So can a heating solar system a boiler, a hot water Serbereiter, at least a radiator and a Fußbo heating, a heat accumulator and another heater Have generators in the form of a heat pump. About the heater  The boiler or the solar collector are the heat consumers supplies, possibly in particular also the heat storage cher charged, which on the other hand in the absence of Sun. Larwärme expands the thermal energy stored in it have to give up their heat consumer again. Here, a Heat pumps can be used at lower temperatures temperature level still available thermal energy through temperature transformation at a higher temperature level to the Dissipate heat consumers. In this way, the Heat stores remove the residual heat that is still present on the other hand you can use it to operate the solar collectors even at a lower temperature level Then the heat consumers, such as wise radiator or underfloor heating still with warmth energy at a sufficiently high temperature level be worried. You have it with all these facilities Flow of the heat transfer medium at different temperatures temperature level, and these heat flows must not be allowed to be mixed up. It is correspondingly complicated with the conventional means of building a distributor direction, which - as already mentioned above - a lot number of individual valves required.

To solve the problem shown, EP 0 711 958 A1 a device for supplying consumers with Thermal energy known to the collector and distributor housing points, which are connected to channels. In this case sen are distribution discs with in the circumferential direction behind arranged through holes through which each according to their rotary positions different circles for the um run of the heat transfer medium can be controlled. Al  However, this can only be used to control the number of each erte consumers can be varied, each one Series connection of the consumers shows why an individual ner consumer not for themselves on or off can be tet. Additional valves must be provided for this to provide the individual consumer with bypass. Also the division into from independent circles is with the well-known Vorrich not arbitrarily possible, a so-called sub-distribution can only exist at a certain interface be taken. The known distribution device is very complex, it has a complex construction and can only be regulated with a PC control. An adjustment on heating or cooling systems with different requirements Changes are not possible in the known device you can neither reduce it for smaller plants nor for expand larger plants. If there is a disturbance in the Distribution device, the entire system is functional efficient.

The invention is based on the object, a distribution To create device of the generic type that simple and clear structure, expandable as required and is easy to control.

This task is carried out in a generic distribution Direction according to the invention solved in that the distribution a series arrangement of three-way valves or cocks, each having an input connection, a Have branch connection and a through connection from de NEN the input port either with the pass-through  end or with the branch connection or from those of the Ab branch connection is connectable to the through connection.

It is essential for the invention that the three used Directional valves or taps in a single, compact design Chen unit allow a cascade arrangement, the particular which is simple and clear. At the beginning of one Cascade, the supply of the heat transfer medium is high Temperature level and at the end of the cascade the return flow low temperature level, whereby the tempera level on the cascade drops from valve to valve and accordingly, a heat consumer, a heat over each of the valves memory or another heat source on the ent speaking temperature level can be switched on. The Cascade of three-way valves or taps can be any extend and therefore easily to the number of available Heat sources and storage as well as the supply to be supplied set.

With the series arrangement of the three-way valves or taps can in particular each individual consumer with the flow and return of the heat source in question get connected. Depending on the version, you need a or two valves of the valve cascade, depending on whether the Return of the consumer is controlled via a valve or not. It is particularly useful, at least in the beginning closing area of the heat consumers at the branch connection of the the individual heat control valve whose front connect run and its return between the through port connection of the valve connected to its flow and the input port of the subsequent valve or un  feed in indirectly at one of these two connections, because there is basically no need for a separate Ab blocking the return flow of the heat consumer. Here will then to the input terminal of the in-line array most valve and to the through connection of the in the Rei arrangement of the last valve, the flow and the return connected to the at least one heat source.

The entire, cascade-like distribution unit can be used in two or more rows of one after the other arranged groups with one row arrangement of the three-way Divide valves or taps and form these groups either individually or in series with at least another group of circuits for heat transfer media different temperature levels. With that, the Circulations of the heat transfer medium on different Separate the temperature level from each other, although in itself the Distribution unit in its overall structural arrangement with the in a row of three-way valves spatially remains unchanged.

To shut off the groups of valve rows in the distributor Each unit is at least at the beginning and / or three-way valves arranged at the end of a group or taps the branch connection with the through connection connectable and at the same time lock the input connection. If the input connection is blocked, the on then interchanges Gangsanschluß and the branch connection their function, so the flow of the heat transfer medium via the branch connection in the relevant row arrangement of such a group  can be introduced. Such a group consists of at least two arranged one behind the other Valves, where the inflow of the heat transfer medium starts the branch connection of the first valve in this group is closed, the input connection of which is blocked, and the return of the heat transfer medium with the branch pipe the last valve of this group is connected, whose through connection is blocked. Is accordingly for this last valve in the group, the inlet connection connected to the branch connection.

With the new distribution system, a variety of scarf tion variations can be realized. So instead of Heat source in its function as a heat consumer in egg ne heat source of convertible customers, such as a heat store, via a valve group to customers with a lower temperature temperature level can be activated. Can also have at least one Valve group the circuit of a heat source with a he most heat transfer medium to another heat source and / or on a temperature transformer, such as heat pump, and the associated secondary circuit with a second heat transfer medium at a different temperature veau ge via another valve group on heat consumers be switched.

The structural unit of the distributor according to the invention direction can be realized particularly well if the row arrangement of the three-way valves or taps in egg common for these valves or taps, such as or rail-shaped housing is arranged. The length this housing can easily be added to the number of each adjust required valves. The closure or tax  body of the three-way valves or the valve cones or - Chicks of the three-way cocks can easily be matched the holes in the respective housing strip or rail accommodate, the connections in the form of channels are integrated in the housing.

In the case of the use of three-way cocks, a common one Tap cone can be used, which complements to a T-shape zende bores, then on the housing of the taps Input connector, branch connector and pass-through connector accordingly arranged offset by 90 ° to each other are. In a particularly advantageous further development of the Erfin The tap cone of the three-way taps has one passage bore, the two openings of different widths ha ben. The connections on the tap housing are arranged in this way net that the smaller opening in two rotational positions of the tap cone the through hole either with the through hole end or aligned with the branch connection and in this the two opening positions of the tap cone the larger opening of the Through opening of the tap cone over the input connection covers. Intermediate positions of the tap cone are also in the This version possible to work with the smaller opening of the Through hole of the tap cone and the through connection the branch connection at least partially at the same time cover up. This allows the flow of the heat transfer medium to divide and also control so that pressure strikes in the entire pipe system for the heat transfer medium medium does not result.

The invention is described below with reference to the drawing management examples explained in more detail. Show:  

Fig. 1 shows a schematic arrangement of a dis cascade for a liquid heat carrier medium of a building heating system in a first circuit,

Fig. 2 shows the distribution cascade of FIG. 1 th in a two-circuit,

Fig. 3, the distribution cascade of FIGS. 1 and 2, in an enlarged circuit arrangement

Fig. 4 is a schematic representation of two three-way cocks for a distributor cascade of the type in question with special training of the tap cone and

Fig. 5 is a representation corresponding to FIG. 4, but in a different switching position of the tap cones.

In particular, FIG. 1 shows a transfer unit 1, the egg ne structural unit with a housing 24 in the form of a rail or rail represents. The distributor line 1 has a plurality or a plurality of three-way valves or taps 2 ₁ to 2 _n , these valves 2 being arranged in a row one behind the other. Each valve 2 has an input connection 3 , a branch circuit 4 and a through connection 5 , which are integrated in the form of channels in the housing 24 . As a rule, the input connection 3 can either be connected to the branch circuit 4 or to the through connection 5 , the through connection 5 being blocked in the connection between the input connection 3 and the branch connection 4 . In a special case, as is the case with the valve 2 ₁ in Fig. 1, the input port 3 can also be blocked, in which case the branch port 4 is then connected to the through port 5 , which is advantageous in the arrangement of the valves 2 is if you want to make the connection on the same side of the distribution unit 1 at the first valve 2 _{1 of} the valve series, on which the inlets and outlets of the other valves 2 lie ₂ to 2 _n .

The mechanical structure of the three-way valves or taps 2 can be very simple, for example by arranging a so-called tap cone, which is also referred to as a plug, in a bore in the housing 2 ₄ , which has a T-shaped bore through Twisting the tap cone produces the desired connection between the input connection 3 and the branch connection 4 or the input connection 3 and the through connection 5 or the branch connection 4 and the through connection 5 . So only two of these connections are connected to each other, while the third connection is blocked.

The heat transfer medium is gradually distributed over the valves 2 arranged in series to heat consumers 6 , 7 and 8 according to the exemplary embodiment of FIG. 1, of which the heat consumer 6 has the higher temperature level, the heat consumer 7 a lower temperature level and the heat consumer 8 have an even lower temperature level. The heat transfer medium gradually passes through the heat consumers 6 to 8 , and it is in this scarf processing example via the input connection 3 of the first Ven valve 2 _{3 of} the series arrangement of the valves 2 ₃ , 2 ₄ and 2 ₅ leads. In the case of the valve 2 ₃ , the inlet connection 3 is connected to the branch connection 4 , and the passage connection 5 of the valve 2 ₃ is accordingly blocked. With the branch connection 4 of the valve 2 ₃ , the flow 9 of the first consumer 6 is connected, the return 10 via a return connection 29 opens into the channel that connects the through connection 5 with the input connection 4 of the subsequent valve 2 ₄ . The return 10 of the consumer 6 can also be connected directly on the output side to the through connection 5 of the valve 2 ₃ or on the input side to the input connection of the valve 2 ₄ , which depends on the design of the valve cascade and the distance between the individual valves 2 . About the following valve 2 ₄ , the return 10 of the first consumer 6 is switched to the flow 11 of the second consumer 7 , because here too the valve 2 _{4 of} the input connection 3 is connected to the branch connection 4 . In an analogous manner, the return line 12 of the two th consumer 7 is connected to the forward line 13 of the third consumer 8 via the valve 2 ₅ , and the return line 14 of the last heat consumer 8 forms the return line of the heat consumer arrangement 6 to 8 . Due to the switching positions of the relevant valves 2 and the respective connection of the return lines, a parallel connection of the heat consumers 6 to 8 is avoided, rather the heat consumers 6 to 8 are in series connection, so that they gradually from the heat transfer medium to their respective falling temperature level be run through.

As Fig. 1 further illustrates, the supply of consumers or heat consumers 6 to 8 via a heat source 16 , which is primarily a Sonnenkol lector. The flow 15 of the heat source 16 is connected to the branch connection 4 of the first valve 2 ₁ in the cascade, here - as already mentioned above - the branch connection 4 only functions because of the laterally uniform connection options of all valves 2 as an input connection. Via the switched to passage valve 2 ₂ , the branch connection 4 is shut off accordingly, the heat transfer medium reaches via the valves 2 ₃ , 2 ₄ and 2 ₅ as already described, through the heat consumers 6 to 8 and through the correspondingly switched valves 2 ₆ to 2 _n to the return 17 of the heat source 16 .

Fig. 2 makes a circuit of the valve cascade significantly, which is then selected if the heat source 16 is not able to provide heat energy, which is the case with a recess formed as a solar collector heat source 16, when a sunlight is missing. Here, the first heat consumer 6 acts as a heat source, which can be realized when the heat consumer 6 is designed as a heat accumulator. The series arrangement of the valves 2 ₄ , 2 ₅ and 2 ₆ forms a group D, via which the circuit of the heat transfer medium from here acts as a heat source, the consumer 6 closes via the further heat consumers 7 and 8 , the return 10 of the heat absorber closing here 6 reverses in a flow, which is connected to the input terminal 3 of the first valve 2 ₄ of group D. At the branch connection 4 of the last valve 2 ₆ of group D is connected via a line 20, the now acting as a return flow supply 9 of the first customer 6 .

Fig. 3 shows a more complex circuit arrangement, in which from the in the housing 24 of the distributor unit 1 cursed arranged in series valves 2 three groups A. B and C are formed, each group of which has a series arrangement of the valves or taps 2 . The heat source 16 is also primarily a solar collector, the flow 15 of which is controlled by group B, here by the two valves 2 ₈ and 2 ₉ . The one input connection of the valve 2 ₈ is blocked, so that there is no hydraulic connection with the valves 2 ₁ to 2 ₇ arranged in front of it in the cascade. In the branch connection of the valve 2 ₈ , the flow 15 of the heat source 16 is introduced and is introduced via the passage connection of the valve 2 ₈ into the subsequent valve 2 ₉ , the input connection of which is connected to the passage connection of the previous valve 2 ₈ . The through connection of the valve 2 ₉ is blocked, here too there is no hydraulic connection with the valves 2 ₁₀ and 2 ₁₁ following in the cascade. The branch connection of the valve 2 ₉ is connected to a flow 18 ei ner heat pump 23 , the return 19 of which is connected to the return 17 of the heat source 16 via the group C formed by the two valves 2 ₁₀ and 2 ₁₁ . Here you have to do with the so-called primary circuit of the heat transfer medium, which closes via the heat source 16 and the primary side of the heat pump 23 . Here is a complete separation of the primary circuit of the heat pump 23 from the secondary circuit, because the heat transfer medium in the primary circuit is at a lower temperature level.

The secondary circuit of the heat transfer medium, which is guided over the secondary side of the heat pump 23 , is located at a correspondingly higher temperature level. The series arrangement of the valves 2 ₂ to 2 ₇ , which form the group A, serves to control this secondary circuit. Before the run 21 of the secondary circuit of the heat pump 23 is fed into the group A via the valve 2 ₂ , there in the manner described above via the valves 2 ₃ to 2 ₅ via the heat consumers 6 to 8 with a falling temperature level, after which the Valves 2 ₆ and 2 _{7 establish} the connection to the return 22 of the heat pump 23 .

FIGS. 4 and 5 illustrate particular Ausgestal obligations of Hahnkonussen 25 for which, especially off of ordered three-way valves, to which the arrangement of the Ka ducts which form the input terminal 3, the branch terminal 4 and the passage terminal 5 in the valve housing 24. The tap cone 25 has an expanding through bore 26 which is arranged substantially diametrically. Consequently, the widening through hole 26 has a smaller opening 27 at one end and a larger opening 28 at the other end. The smaller opening 27 of the through bore 26 of the valve cone 25 can, as shown in FIG. 4, be aligned either with the through connection 5 or with the branch connection 4 , the further opening 28 of the through bore 26 covering the input connection 3 in both rotational positions of the valve cone 25 , which can accordingly be optionally switched to branch connection 4 or to through connection 5 .

Fig. 5 makes it clear that intermediate positions of the tap cone 25 are possible, as can be seen there from the presen- tation left. Here, the smaller opening 27 of the through hole 26 of the tap cone 25 partly covers both the through connection 5 and the branch circuit 4 , so that the incoming flow of the heat transfer medium can be divided via the input connection 3 . In Fig. 5 right is one of the locking positions of the tap cone 25 as given in which both the input connection 3 , the branch connection 4 and the through connection 5 are blocked abge.

Can further be seen in Figs. 4 and 5 or each egg NEN return port 29, which in the connecting channel Zvi rule the passage terminal 5 of the discharges of the next in the cascade valve or faucet in the cascade vorheri gen valve or tap and the input terminal 3.

Claims (11)

1.Device for distributing a liquid Wärmeträgerme medium of a building heating and / or cooling system between one or more heat sources and several subordinate heat consumers with decreasing temperature level, each with a flow and a return for the heat transfer medium, all of which are in a structurally uniform distribution unit can be connected, characterized in that the distributor unit ( 1 ) has a series arrangement of three-way valves or taps ( 2 ), each having an input connection ( 3 ), a branch connection ( 4 ) and a passage connection ( 5 ), of which the input connection ( 3 ) either with the through connection ( 5 ) or with the branch connection ( 4 ) or of which the branch connection ( 4 ) with the through connection ( 5 ) is ver bindable. 2. Device according to claim 1, characterized in that at least in the connection area of the heat consumers ( 6-8 ) at the branch connection ( 4 ) of each valve or tap ( 2 ) a customer ( 6-8 ) with its flow ( 9 , 11 , 13th ) is connected, the return ( 10 , 12 , 14 ) between the passage connection ( 5 ) of the valve ( 2 ) connected to its flow ( 9 , 11 , 13 ) and the input connection ( 3 ) of the subsequent valve ( 2 ) or is directly connected to one of these two connections ( 5 , 3 ), with the input connection ( 3 ) of the first valve in the series arrangement ( 2 ₃ ) and the through-connection ( 5 ) of the last valve in the series arrangement ( 2 ₅ ) the flow ( 15 ) and the return ( 17 ) of the least one heat source ( 16 ) are connected. 3. Apparatus according to claim 1 or 2, characterized in that the distributor unit ( 1 ) has two or more groups (A, B, C, D) of the three-way arrangement of the three-way valves or taps ( 2 ) arranged in series, wherein these groups (A, B, C, D) either individually or in series with at least one further group, separate circuits each via at least one heat source or one heat consumer for heat transfer media at different temperature levels. 4. The device according to claim 3, characterized in that to shut off the groups (A, B, C, D) of valve rows of the distributor unit ( 1 ) from each other at least at the beginning and / or end of a group (A, B, C, D) arranged three-way valves or taps ( 2 ) either the branch connection ( 4 ) connected to the through-connection ( 5 ) and at the same time the input connection ( 3 ) shut off or the input connection ( 3 ) connected to the branch connection ( 4 ) and the Through connection ( 5 ) is blocked. 5. Device according to one of claims 1 to 4, characterized in that instead of the heat source ( 16 ) in its function as a heat consumer in a heat source changeable Abneh mer ( 6 ), such as a heat accumulator, via a valve group (D) The customer ( 7 , 8 ) can be switched on with a lower temperature level. 6. Device according to one of claims 3 to 5, characterized in that via valve groups (B, C) the circuit ( 15 , 17 ) of a heat transfer medium at least one heat source ( 16 ) on the primary circuit of a heat pump ( 23 ) is switchable and the separate secondary circuit of the heat pump ( 23 ) with a heat transfer medium at a different temperature level via a further valve group (A) can be connected to the heat consumers ( 6-8 ). 7. Device according to one of claims 1 to 6, characterized in that the three-way taps ( 2 ) have a tap cone with a T-shape complementary holes and on the housing of the three-way taps ( 2 ) the input connection ( 3 ), the branch connection ( 4 ) and the passage connection ( 5 ) are arranged accordingly at a 90 ° distance from one another. 8. Device according to one of claims 1 to 6, characterized in that the three-way valves ( 2 ) have a valve cone ( 25 ) with a through hole ( 26 ), the two openings ( 27 , 28 ) of different widths, the connections ( 3 , 4 , 5 ) on the valve housing ( 24 ) are arranged so that in two rotational positions of the valve cone ( 25 ) the smaller opening ( 27 ) of the through hole ( 26 ) is aligned either with the through connection ( 5 ) or with the branch connection ( 4 ) and in these two rotational positions of the tap cone ( 25 ) the larger opening ( 28 ) of the through hole ( 26 ) of the tap cone ( 25 ) covers the input connection ( 3 ). 9. The device according to claim 8, characterized in that the through connection ( 5 ) and the branch connection ( 4 ) are arranged side by side on the tap housing ( 24 ) and the width of the smaller opening ( 27 ) of the through hole ( 26 ) of the tap cons ( 25 ) is such a dimension that with this smaller opening ( 27 ) in inter mediate positions of the tap cone ( 25 ) the through connection ( 5 ) and the branch connection ( 4 ) are at least partially covered at least at the same time. 10. Device according to one of claims 1 to 8, characterized in that the row arrangement of the three-way valves or taps ( 2 ) is arranged in a common for this, such as strip or rail-shaped housing ( 24 ). 11. The device according to claim 10, characterized in that the input connection ( 3 ), the branch connection ( 4 ) and the through connection ( 5 ) are integrated in the form of channels in the housing ( 24 ).