NL8600246A - Domestic heating circuit supplying tap water - has burner controlled by on-off cycle and restriction in circuit - Google Patents

Abstract

The heating circuit contains a first heat-exchanger in which heat is absorbed by the medium form burner combustion gases, and a second in which heat is transferred to tap water. The burner (5) is controlled by an on/off cycle, while there is a restriction (15) in the circuit between the first (4) and second (10) exchangers. A tank (16) is connected across the restriction, its capacity being the product of the medium flow and the duration of the on/off cycle.

Description

T / Atag-50 DEVICE FOR EQUALIZING TEMPERATURE VARIATIONS IN A HEAT MEDIUM.

The invention relates to a heating device comprising a heat media recycle pipe, a first heat exchanger incorporated in the recycle pipe for absorbing heat from combustion gases of a burner through the heat medium, a second tap water heat exchanger included in the recycle pipe tap water transferring heat from the heat medium, and a control device for controlling the operation of the burner.

Such a heating device is well known in the home heating application. Since the hot tap water must have a constant temperature, it is known in such heating devices to design the burner as a modulating burner, the load of which is regulated in relation to the temperature of the tap water when leaving the second tap water. heat exchanger. A modulating burner and its arrangement is expensive. In addition, it is very difficult to operate a modulating burner with an acceptable efficiency over a significant part of its control range.

The object of the invention is to provide a heating device of the type described in the preamble, which can supply tap water with a constant temperature, is simple and can operate with a high efficiency.

With a heating device according to the invention this is achieved in that the control device controls the burner according to an on / off cycle, because a restriction is included in the circulation pipe between the first and second heat exchanger and a reservoir is connected over the restriction, the reservoir being connected to a content that has the magnitude of the product of the heat medium flow rate and the period of the on / off cycle. An on / off controlled burner and its control is very simple and can be ^ -X, Λ. *

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2 are properly set to a maximum efficiency. By applying the restriction and the reservoir according to the invention it is achieved that the periodic temperature change in the heat medium leaving the first heat exchanger can be equalized to a substantially constant temperature at the inlet of the second heat exchanger.

With a suitable on / off cycle of the burner, the temperature curve of the heat medium on leaving the first heat exchanger becomes almost sinusoidal. According to the invention, a constant temperature at the inlet of the second heat exchanger is achieved within very narrow limits, in that the restriction is of such a size that it allows half of the heat medium flow rate and because the reservoir has a content equal to a quarter. of the product of the heat medium flow rate and the period duration of the on / off cycle. The temperature of the heat medium which has flowed through the reservoir hereby exhibits a phase shift of 180 "with the temperature of the heat medium which has flowed directly through the restriction. By mixing these two flows, a mixing flow with a constant temperature is obtained .

With a temperature variation which deviates strongly from the sine shape, a constant temperature can nevertheless be reached when, according to the invention, the restriction forms a closure and the reservoir has a content equal to the product of the heat medium flow rate and the period duration of the on / / out of cycle. In this embodiment of the inventive idea, the heat medium flow in the reservoir is mixed to a constant temperature.

The invention also relates generally to and provides an apparatus for compensating for temperature fluctuations in a heat medium flowing through a conduit, comprising a flow restriction incorporated in the conduit and a bypass bridging a heat medium reservoir.

The invention will be explained in more detail below with reference to the annexed drawings.

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Pig. 1 schematically shows a tap water heat exchanger to which the invention has been applied.

Pig. 2 shows a temperature curve.

Pig. 3 shows a house heating installation, in which the device for equalizing temperature fluctuations according to the invention is used.

The heating device 1 comprises a circulation pipe 2 for a heat medium. A boiler 3 is included in the recycle line 2. The heat medium in the recycle line flows into the boiler. 3 by a heat exchanger 4, where this medium absorbs heat from combustion gases from a burner 5. Gas is supplied to the burner 5 via a tap 6, which is switched on or off by a control (not shown in more detail). The burner is thus controlled according to an on / off cycle 15. A pump 7 is included in the circuit line 2 for the transport of the heat medium through the circuit.

Because of the on / off control of the burner, the temperature of the heat medium leaving the heat exchanger 4 varies by a period corresponding to that of the on / off control. Fig. 2 shows this medium temperature T as a function of time t. The period of the on / off cycle is indicated by tp.

The heating device 1 further comprises a second tap water heat exchanger 10. In this heat exchanger cold tap water is supplied via a pipe 12 and hot tap water is discharged via the pipe 11. A coil 13 is incorporated in the heat exchanger 10, which flows through heat medium from the circulation pipe 2.

According to the invention, between the heat exchanger 4 and the tap water heat exchanger 10, a restriction 15 is included in the pipe 2 and a reservoir 16 is connected over the restriction 15.

When the temperature has an approximately sinusoidal course, as shown in Fig. 2, the restriction 15 is dimensioned such that half of the volume flow in the pipe 2 flows through the restriction 15 and the other half has through the reservoir 16. Furthermore, the reservoir 16 has a content equal to the volume in a quarter of the pe- Λ Λ ^ * * · *

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4 period tp flows through line 2, or equal to the volume flowing through restriction 15 in half a period tp.

As a result, medium entering the reservoir 16 leaves this reservoir 16 exactly half a period later. The temperature of the medium leaving the reservoir 16 therefore has a half-period phase lag with respect to the medium which has flowed directly through the restriction 15. At the mixing point 17, these flows mix to the constant average temperature.

This is further elucidated in Fig. 2. At time t2, the medium that has flowed directly through the restriction 15 has the temperature T2 at the mixing point, while the medium that comes out of the reservoir, since at time t1, has entered half a period earlier, and thus has the temperature T1. These temperatures T1 and T2 are symmetrical with respect to the average temperature Tg and thus mix up to the average temperature Tg, since both flows are the same size.

It goes without saying that the reservoir 16 is designed such that no mixing occurs therein. This can be achieved in a known manner by including a tube bundle therein or by designing this reservoir as a conduit coil.

The device 20 of Fig. 3 comprises a boiler 21 in which a burner 24 and a heat exchanger 25 are included. Medium heated by the burner 24 and the heat exchanger 25 leaves the boiler 21 through the conduit 22. The heat medium is supplied to heat consumers, which may be, for example, radiators or convectors 23. Heat medium cooled again is returned to boiler 21.

The burner 24 is on / off controlled so that the heat medium leaving the boiler has a varying temperature.

In the conduit 22 is a device 30 according to the invention. to compensate for temperature fluctuations in the heat medium flowing through the pipe. The device 30 comprises a flow restriction designed as an operable valve 26 and a bypass bridging the valve 26 with a heat medium reservoir 27. This reservoir 27 is designed as a mixing vessel. This means that the medium flowing into the reservoir is evenly mixed λ "> Λ Λ -) i: -¾ pi 1 *. A}) J Λ β W · *. VV:> v 5 with the already in the medium present The reservoir 27 has a content equal to the product of the heat media flow rate in the pipe 22 and the period duration of the temperature fluctuations In those cases where it is desired to add a constant temperature to the heat consumers 23 the valve 26 is completely closed and the heat medium will exhibit a constant temperature at the outlet of the reservoir 27.

In another application case, if the reservoir 27 has a smaller volume and is designed as a non-mixing reservoir, a minimum temperature fluctuation can be set by means of the adjustable restriction formed by the valve 26 on the mixing site 28. The flow time of the heat medium through the reservoir 27 depends on the amount of medium, according to the setting of the valve 26. When a large amount flows through the reservoir 27, the phase shift in the temperature course at the outlet of the reservoir 27 will be less than when a small amount of heat medium is passed through the reservoir 27. Due to the adjustable phase difference in the temperature course of the heat medium flow through the valve 26 and through the reservoir 27, a temperature which fluctuates only slightly can be achieved in this way, even if the temperature course shows a strongly deviating behavior.

Claims (6)

1. Heating device comprising a heat medium circulation line, a first heat exchanger incorporated in the circulation line for absorbing heat from combustion gases of a burner through the heat medium, a second, tap water heat exchanger included in the circulation line for the transfer water transfer and heat from the heat medium, and a control device for controlling the operation of the burner, characterized in that the control device controls the burner according to an on / off cycle, which in the circulation line between the first and second heat exchanger restriction is incorporated and a reservoir is connected over the restriction, the reservoir having a volume of the order of magnitude of the product of the. heat medium flow rate and the period duration of the on / off 15 cycle. 2. Device according to claim 1, characterized in that the restriction is of such a size that it allows half of the heat medium flow to pass through and that the reservoir has a content equal to a quarter of the product of the heat medium flow and the period duration. of the on / off cycle. 3. Device according to claim 1, characterized in that the restriction forms a closure and in that the reservoir has a content equal to the product of the heat medium flow rate and the period duration of the on / off cycle. 4. Apparatus for compensating for temperature fluctuations in a heat medium flowing through a conduit, characterized in that it comprises a flow restriction incorporated in the conduit and a bypass bridging a heat medium reservoir. Device according to claim 4, characterized in that the restriction is of such a size that it allows half of the heat medium flow to pass through and that the reservoir has a content equal to a quarter of the v, -j 2 o -V · 7 product of the heat medium flow rate and the period duration of the temperature fluctuation. 6. Device as claimed in claim 4, characterized in that the restriction forms a closure and that the reservoir has a content equal to the product of the heat medium flow rate and the period duration of the temperature fluctuation.