DE2643716C2 - Storage device consisting of individual cells for a fluid medium to be heated - Google Patents

Description

The invention relates to a memory consisting of individual cells according to the preamble of Main claim.

A preferred field of application of such storage is the service water supply; on the other hand it does not matter whether water is heated as the medium or whether it is another fluid Medium acts. Such a system could just as easily be used as storage central heating.

It is known to ensure a domestic water supply of a house via cell storage, wherein the individual storage cells are provided with thermostatic valves and the water supply from the individual memory cells takes place one after the other, so that in each case from a cell that is currently in operation is switched to the next when the cell is discharged. So the cells become individual here discharged one after the other and also charged equally. This circuit has the individual memory cells the disadvantage that when switching from cell to cell, the maximum tap water flow to the discharge capacity the individual memory cell is limited, or because a series connection of the individual cells of the Through resistance becomes too great.

It is also known to charge or discharge several cells in parallel. However, this is not the case ensures that all storage tanks are charged and discharged equally. For this it is necessary and known the connection accessories to match resistance to each other, which requires that all connecting parts from Must be supplied by the manufacturer. This also has the disadvantage that with different numbers of cells different accessories have to be offered and kept ready.

The invention is based on the object of the maximum fluid flow that can be drawn off from the storage cells without increasing the storage capacity itself and without a variety of accessories to have to keep ready.

The solution to this problem lies in the characteristic Features of the main claim.

The advantage that can be achieved with the invention lies in the uniform loading and unloading of all storage cells, with which also a favorable utilization of capacity

ίο is guaranteed.

Further refinements and advantageous developments of the invention emerge from subclaims 2 and 3 emerge.

In the following description, an exemplary embodiment is shown using the circuit diagram shown in the drawing explained in more detail.

From a heat source, not shown, feed lines 1 and 2 come, of which the line 1 the Flow line, the line 2 represents the return line. From the feed line 1 branch off Junction points 5 from cell feed lines 3 which lead to individual storage cells 4. The supply lines 1 and 3 all have the same diameter. To the individual cell flow lines 3 is inside the Storage cells 4 each have a heat exchanger tube 6 connected to them via a cell return line 7 Confluence points 8 are connected to the feed return line 2. The feed return line 2 also has consistently the same diameter. In the area of the individual cell return lines 7 is at the output of respective storage cell a thermostatic valve 9 is provided, the sensor 10 of the temperature of the through the Line 7 senses flowing fluids. The thermostatic valves 9 are switched so that they increase with Temperature narrow the outlet cross-section and thus increase the pressure loss. The thermostatic valve does not seal the outlet, however, so that even if a maximum temperature value is exceeded, am Sensor ensures that there is always a low flow of fluid and the sensor also when it is closed Valve TetTiperatur changes of the pending fluid can register.

The cell storage also has dispensing lines 11 and 12 adf, the line 11 coming from a water source (not shown), the line 12 being a Represents the dispensing feed line to a plurality of dispensing valves. The dispensing line 11 is via cell dispensing lines 13 connected at branch points 15 to interiors 14 of the individual storage cells 4.

The inner spaces 14 of the individual storage cells 4 are connected at their upper ends via a cell feed line 16 to the tap feed line 12 at confluence points 17.
Thermostatic valves 18 are provided in the cell supply lines 16 at the outputs of the individual storage cells, the sensors 19 of which sense the temperature of the storage water leaving the individual storage cells. The thermostatic valves 9 and 18 are of dissimilar design. The feelers are the same. The thermostatic valves 18 are switched so that they close when the temperature falls, or increase the pressure loss (ensuring that the hot water line is not closed).

The storage system described has the following function:

Assuming that all cells are discharging, i. H. are filled with cold fluid, so are the Thermostatic valves 9 open, the thermostatic valves 18

closed. If the storage tank is now to be loaded by the heat source via the feed lines 1 and 2 are charged, this results in a uniform flow of warm fluid through the feed line 1 and thus through the coils 6 of all storage cells. Due to unavoidable tolerances, possibly intentional differences in size of the storage cells or the supply lines or the coils are now also one cell can be charged faster than another. This means that the temperature at the exit of this cell, d. H. in the corresponding cell return line 7, increases. The temperature sensor 10 measures this fact and causes the associated thermostatic valve 9 for throttling. This means that this cell is less charged and the available heat flow is distributed correspondingly to the other cells. If this cell is fully charged, the thermostatic valve 9 closes, but only in this way far that the sensor remains functional. This is how the individual cells become one after the other, but the rest of the cells are charged substantially evenly, throttled when the individual Thermostatveiitile 9 close. Via a signaling device, not shown, which, for example, controls the differential pressure between the feed lines 1 and 2, the heat source can send a corresponding signal when the storage tank is fully charged be notified that there is no longer any heat request.

This signal can, however, also come from a thermostat, which controls the increased return or flow rate. Flow temperature registered.

If the memory is now activated by actuating one or more nozzles in the course of the delivery line 12 discharged, the medium presses in the dispensing line 11 fluid medium through the individual cells in parallel. Since the memory cells are charged, have the sensor 19 of the thermostatic valve 18 detects this state, the associated valves 18 are open. Consequently all cells are discharged equally, a certain unevenness results from unavoidable

ic component tolerances. So it will happen that a cell is discharged faster than the other, so that a corresponding closing command via the sensor 19 to a thermostatic valve 18 thus this row is blocked, and the discharge of the other cells screams steadily. In any case, it is avoided that cold fluid medium from the Dispensing line 11 noticeably lowers the temperature of the outflowing medium in the dispensing feed line 12. After all thermostatic valves 18 have been shut off, there is no or only a very small amount of dispensing medium possible.

It should be mentioned that loading and unloading of the memory are completely independent of each other, i. H. even can take place at the same time, since the discharging of the individual storage cells causes a decrease in the temperature measured by the sensor 10 measured temperature has the consequence, after which by opening the associated thermostatic valve 9 a L current can take place via feed lines 1 and 2.

1 sheet of drawings

Claims (3)

Patent claims: 1. Storage unit consisting of individual cells for a fluid medium to be heated, which is shared by all Cells of the memory is supplied and discharged via dispensing lines, in which the individual cells have with a heat source connected feed lines charged with a fluid heat transfer medium are, characterized in that the tap (11, 12) and feed lines (1, 2) to and from the cells (4) are connected in parallel to each other and that in the delivery lines (16) of the individual storage cells (4) and in the cell feed return lines (7) each a thermostatic valve (18, 9) is arranged 2. Memory according to claim 1, characterized in that the sensor (10) in the cell feed return lines (7) arranged thermostatic valves (9) in the cell feed return lines (7) are arranged directly on the valve and that the Thermostatic valves have a non-closable bypass section. 3. Memory according to claim 1 or 2, characterized in that the sensor (19) in the Cell flow lines (16) arranged thermostatic valves (18) in the upper area of the interior (14) of the individual storage cells (4) are arranged.