DE3418480A1 - Controller for heating a hot-water reservoir - Google Patents

Abstract

During the heating of a hot-water reservoir, partial quantities of total volume can be brought to a desired temperature. For reasons of economy, re-heating during a re-charging low-tariff time is intended to take place only when the residual quantity of hot water is less than a quantity which is normally adequate until the next low-tariff time. If necessary, it is intended to re-heat only that partial quantity which is normally adequate until the next low-tariff time. For this purpose, the number of quantity switching contacts is equal to the number of low-tariff times per cycle. A time switching mechanism closes a dedicated time switching contact during each low-tariff time. The first quantity switching contact, for the largest quantity, is allocated to the time switching contact for the longest low-tariff time. The quantity switching contact for the lowest partial quantity is allocated to the time switching contact for the low-tariff time occurring before the longest low-tariff time. <IMAGE>

Description

Control of the heating of a hot water storage tank

The invention relates to the control of the heating of a thermally insulated Hot water tank, through which also at least a portion of the total water volume the hot water tank can be brought to a target temperature, including at least two parallel quantity switching contacts are provided, via which an electrical Radiator is switched and depending on the target temperature in one switch to a certain level of the hot water storage tank.

Such a control is described in DE-OS 29 50 328. Of the The radiator is arranged in a pipe space, the top and bottom with the hot water tank communicates. This causes the hot water to flow into the water heater from above layered. The temperature sensor extends essentially over the entire Height of the water heater and gathers the different temperatures the water stratification according to their partial heights. He turns off the radiator if in a partial height of the storage tank height set via a selector switch the Target temperature is reached. A selector switch is provided to set the temperature Set the desired amount of hot water to be heated. The user has the Possibility to supply in advance the amount of hot water that corresponds to the expected demand Select. This avoids losses that arise when there is more water than is heated up in itself necessary. A connection with off-peak times is in DE-OS 29 50 328 not shown.

In DE-PS 29 47 969 a control of hot water heaters is using a microprocessor. In addition to the Water temperature also entered the amount of water according to a given need. This should on the one hand avoid loss of rest and on the other hand waiting times.

Here, too, the heating is not provided by the electricity supply company fixed off-peak times.

In DE-OS 15 40 869 a device for remote control of electric heat storage stoves described.

The heating takes place during the nightly low tariff period in Reverse control, depending on the outside temperature. A timer with three Switching contacts are provided, which can be used during a third of the low tariff period or two thirds of the off-peak period or

are closed during the entire low tariff period.

To take advantage of low-tariff recharging times provided during the day this facility is not suitable.

The object of the invention is to provide a control of the aforementioned Kind of design in such a way that after-heating occurs during a low-tariff recharging period only takes place when the remaining hot water quantity is below the normal level until the next low tariff period is sufficient, and possibly only a partial amount is reheated, which is usually sufficient until the next low tariff period.

According to the invention, the above object in the case of a control is the one at the outset mentioned type solved in that the number of quantity switching contacts is equal to the Number of off-peak times per cycle is that a timer during each Low tariff time its own time switch contact closes that the first volume switch contact the largest amount is assigned to the time switch contact of the longest, first low tariff period is that the second quantity switching contact of the smallest subset is the timer contact assigned to the low tariff period before the longest, first low tariff period is and that optionally a third quantity switching contact of a larger subset that time switch contact is assigned to a further low tariff period that lies between the first off-peak period and the second off-peak period.

In addition to the nightly, longest off-peak period per day (cycle) often also two shorter periods of the day Low tariff reloading times are available. In this case are with the invention three time switch contacts and three quantity switch contacts are provided. Is only one Given the low tariff time for recharging, there are two correspondingly in the invention Time switch contacts and two quantity switch contacts provided. Should be more than two Reloading low tariff times are given in the invention accordingly more Time switch contacts and quantity switch contacts provided. The reloading is staggered that between the end of the first, longest main low tariff period and the New start of the next low-tariff recharging times the reloading takes place progressively only with smaller and smaller residual amounts of hot water.

During a low tariff reloading period, not the entire storage volume brought to the target temperature, but only a partial amount, which experience has shown until the next low tariff period. During a reloading low tariff period There is no need for reheating at all if the ones still available during the low tariff period Experience has shown that the amount of hot water will last until the next low tariff period.

The invention avoids having more hot water than per se necessary is prepared. In addition, the radiation losses are also reduced, because it is accepted that the amount of hot water kept available in the The course of the day is decreasing. The radiation losses also decrease because by making use of the off-peak times of the hot water storage tank than in cases in which no post-heating takes place.

A simple structure of the control is an embodiment of the invention achieved in that the respective quantity switching contacts with these respectively assigned time switch contacts are electrically in series and these series connections are connected in parallel.

A single contact is preferably used to control the quantity switching contacts Temperature sensor provided, which is essentially over the entire height of the Hot water tank extends. However, it is also possible to level each of the amounts of water to provide its own temperature sensor that is set to the target temperature is.

A single one is preferably used to heat the hot water tank Radiator provided.

Further advantageous refinements of the invention emerge from the following description of an embodiment. In the drawing show: Figure 1 is a circuit diagram of a water heater and Figure 2 is a timing diagram.

A cold water supply line opens into a hot water tank 1 at the bottom 2. A hot water tap 3 is connected to the hot water tank 1 at the top.

In one arranged in the hot water tank 1, open at the top and bottom Pipe section 4, a radiator 5 is arranged, the pipe section 4 ensures that the hot water stratification progresses from top to bottom.

Extends essentially over the entire height of the hot water tank 1 a temperature sensor 6 through which three volume switching contacts 7, 8 and 9 can be actuated are. The temperature sensor 6 is designed in such a way that it controls the quantity switching contact 7 opens when a target temperature of around 800C is reached at level 10. The quantity switching contact 8 is opened by the temperature sensor 6 when the target temperature is reached in level 11 is. The quantity switching contact 9 is opened, albeit at the bottom in the hot water tank 1 the target temperature is reached, so the hot water tank 1 is charged for 100 s is. Level 11 is a partial amount of the total water volume of the hot water tank 1 of about 60%. Level 10 is a smaller subset of around 30.

In series with the quantity switch contact 7 is a time switch contact 12. A time switch contact 13 is connected in series with the quantity switch contact 8. A time switch contact 14 is located in series with the quantity switch contact 9.

The time switch contacts 12, 13 and 14 are each during one Low tariff time from a time switch 15 closed. The time switch contact 14 is closed during the longest, first low tariff period NT1, which is from 22.00 Lasts until 6:00 a.m. The timer contact 12 is during a shorter, second Low tariff time NT2 closed, for example from 6 p.m. to 8 p.m. lasts, i.e. before the low tariff period NT1. The timer contact 13 is during a third off-peak period NT3 closed between the end of the first Low tariff time NT1 and the second low tariff time NT2. The low tariff period For example, NT3 is between 1:00 p.m. and 3:00 p.m.

The series connections of the quantity switching contacts 7, 8 and 9 with the Time switch contacts 12, 13 and 14 are electrically connected in parallel. they lay in front of the radiator 5.

In Figure 2, the percentage filling of the hot water tank 1 is with Water the set temperature of about 800C depending on the time in different Loading or Discharge curves shown.

At the end of the first low tariff period NT1, at 6:00 a.m., the hot water storage tank is open 1 charged to 100%. Is there at least NT3 in the next low tariff period a partial amount of 60 s of hot water at 80 ° C is available, then the amount switching contact is 8 open, so that despite the closed timer contact 13 in the low tariff period NT3 no reheating takes place. For example between 6:00 a.m. and 3:00 p.m. a discharge along line a, then takes place during the low tariff period NT3 no reheating takes place. This also applies to all other unloading lines in the Field A run. Between 6 a.m. and 3 p.m., 40 ß of the hot water can be used can be withdrawn without having to recharge during the low tariff period NT3. It is taken into account that 60 ß hot water as a rule until the low tariff period NT1 are enough.

If the hot water storage tank is discharged between 6 a.m. and 3 p.m. 1 under 60 96, for example along line b, then the quantity switch contact closes 8, as soon as the remaining hot water quantity falls below 60 96. If then to Low tariff time NT3 the timer contact 13 closes, reloading takes place, in the example case along the line c until the quantity switch contact 8 opens again, which is the case when a charge of 60 X is reached.

The steepness of the charging curve c is essentially equal to that Steepness of the characteristic d. This is dimensioned so that the radiator 5 the hot water tank 1, if it is fully discharged at 10:00 p.m., charges to 100 96 by 6:00 a.m. This slope is also the same as the slope of all other charging characteristics.

The characteristic curve e shows that at the end of the low tariff period NT3 still the 60 * charging can be achieved if the hot water tank 1 at the beginning of the low tariff period NT3 is discharged to approx. 35 96. This means that at Exploitation 65 96 of the hot water is taken from the low tariff time NT3 between 6:00 a.m. and 1:00 p.m. and 60 96 hot water will be available again at 3 p.m. This is indicated by field B.

If a discharge takes place after 3 p.m., for example along the characteristic curve f, then the volume switching contact 7 is not opened during the low tariff period NT2.

So there is no reloading. At 8 p.m. there are still 30 96 hot water available, which experience shows is sufficient until the low tariff period NT3. at No recharging is required for characteristics that run in field C. Between 3 p.m. and 8 p.m. 30 96 hot water can be used without recharging during the low tariff period NT2 are consumed. If there is a stronger discharge, for example along the Characteristic curve g, then switch contact 8 is activated when the charge drops below 30 $ closed, so that in the low tariff period NT2 charging along the characteristic curve h takes place. When the 30 * ~ charge is reached, the quantity switch contact opens 8 again.

The characteristic i, which has the same steepness as the characteristic d, shows that at the beginning of the low tariff period NT2 there may be a discharge to 5 96, if at the end of the low tariff period NT2 a charge of 30 s should still be achieved. When reloading, 55 96 hot water can be used between 3 p.m. and 6 p.m. will. With all characteristic curves in field D, there is a residual charge at 8:00 p.m. 30 96 ensured.

The remaining charge of 30 ß at 8 p.m. is sufficient to cover the rest of the time Experience has shown that hot water is heated again up to the low tariff period NT1 If, for example, a discharge takes place lengthways between 8:00 p.m. and 10:00 p.m. the characteristic curve k, then in the low tariff period NT1 the charging takes place along the Characteristic curve l.

If the characteristic curve d is designed to be steeper than shown in Figure 2, then the characteristics e and i also become correspondingly steeper.

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Claims (5)

Claims 1. Control of the heating of a thermally insulated Hot water tank, through which also at least a portion of the total water volume the hot water tank can be brought to a target temperature, including at least two parallel quantity switching contacts are provided, via which an electrical Radiator is switched and depending on the hot water storage tank of the Switch the temperature of the hot water tank to a certain level, thereby characterized in that the number of quantity switching contacts (7, 8, 9) is equal to the number the low tariff times (NT1, NT2, NT3) per cycle is that a timer (15) during each low tariff period (NT1, NT2, NT3) its own time switch contact (14, 12, 13) concludes that the first quantity switch contact (9) of the largest quantity (100 assigned to the time switch contact (14) of the longest, first low tariff period (NT1) is that the second quantity switching contact (7) of the smallest subset (30) is the timer contact (12) the second low tariff period before the longest, first low tariff period (NT1) (NT2) is assigned and that, if necessary, a third quantity switching contact (8) a larger subset (60 fo) the time switch contact (13) of a further low tariff period (NT3) is assigned between the first low tariff period (NT1) and the second Low tariff period (NT2). 2. Control according to claim 1, characterized in that that the further low tariff period (NT3) is before the second low tariff period (NT2). 3. Control according to claim 1 or 2, characterized in that the respective quantity switching contacts (7, 8, 9) with the respective time switch contacts assigned to them (12, 13, 14) are electrically in series and these series connections are connected in parallel are. 4. Control according to one of the preceding claims, characterized in that that for switching the quantity switching contacts (7, 8, 9) a single temperature sensor (6) is provided, which extends essentially over the entire height of the hot water tank (1) extends. 5. Control according to one of the preceding claims, characterized in that that a single radiator (5) is provided.