FR2528154A1 - DEVICE FOR USING A PART OF THE HEAT CONTAINING THE EXHAUST GAS FROM A BOILER BY THE CHIMNEY - Google Patents

Abstract

The invention relates to a device for utilising a portion of the heat content of the waste gases escaping from the boiler through the stack, which contains at least one boiler and, in the direction of flow of the waste gases, at least one convective heat exchange surface which is downstream of the permanent heating surface of the boiler. In this device, the aim is to utilise a portion of the heat content of the waste gases escaping from the boiler. This takes place because a two-way device which can be actuated by a controller is installed in the line of the coolant that is to be led into the heat exchange surface, and the input of the controller is connected to the output of the temperature sensor installed in the escape cross-section of the stack and to the output of the instrument that is arranged in the line of the waste gases escaping from the boiler and measures the dew point temperature. Moreover, the output of the controller which transmits a command signal is connected to the executive member of the two-way device, the command signal being proportional to the difference in the input signals.

Description

DEVICE FOR USING A PART OF THE HEAT THAT
CONTAIN EVACUATING GAS FROM A BOILER
BY THE CHIMNEY
The present invention relates to a device for using part of the heat contained in the exhaust gases from a boiler by the chimney, this device comprising at least one boiler and at least one convection heat exchanger disposed after the permanent heating surface of the boiler. the boiler in the flue gas flow direction.

 The efficiency of coal, gas or oil heaters can be improved not only by providing complete combustion but also by reducing the heat of exhaust gas entering the atmosphere.

 The technical safety requirements for the oil and gas industries determine the minimum temperature at the point of connection of the exhaust gas, before discharge, for domestic or communal heat production devices. In the case of heat generating devices usable in industry and in power plants, for example with boilers, there is no officially determined value of the minimum temperature of the exhaust gases emitted by the device. This is because, for the thermal design of a boiler by the calculation of the temperature of the gases leaving the boiler, average conditions are taken into consideration for which the exhaust gases at the outlet point of the stack are not cooled in winter at below the dew point, even under unfavorable localization conditions and adverse atmospheric conditions. But in this way, for most of the year, the exhaust gases come out of the chimney with a temperature that, unjustifiably, is much higher than the dew point, dragging with them a large amount of heat unused, that is to say that the efficiency of the boiler is reduced.

 The situation is similar with individual boiler projects because in this case, the temperature of the exhaust gases leaving the boiler heating surface is determined so that the temperature of these exhaust gases at the outlet of the stack is is above the dew point even in unfavorable winter conditions.

 If the exhaust gases are cooled below the dew point, provision must also be made for protection against corrosion.

 In practice, it is necessary to calculate with the dew point of the water and the dew point of the acid. The two values are not constant even with the same boiler, as they depend on the fuel, the pressure, the moisture content and the amount of excess air. It follows from all this that for the design of a boiler, it is necessary to take into account these effects as well as the location conditions and the outside temperature, superimposed in the worst case and it follows that the temperature of the gases of Evacuation coming out of the chimney is always well above the temperature which should correspond to most of the use so that the temperature of the dew point is avoided.

 This means that for dimensioning, conditions that do not exist simultaneously - which is the case in most of the use - are taken into consideration and, consequently, the exhaust gases are led into the chimney. at an unjustified high temperature. As a result, exhaust gas escapes into the atmosphere through the outlet section of the chimney with a temperature that is higher than the dew point temperature. It is common for boilers of the same type and with the same heat exchanger to be used to burn sulfur-free natural gas and high-sulfur oil.

 In the case of heating with sulfur-free natural gas, it is necessary to avoid the dew point of the water, which at atmospheric pressure is between 50 and 700C. In the case of oil heating with a sulfur content, the dew point of the acid which, with a sulfur content of 0> 5, must be avoided is of the order of 1100 ° C.

 It should be noted that there is a notable difference between the two dew points and that in the case of alternate heating, the higher dew point of the sulfuric acid determines the temperature of the exhaust gases leaving the boiler, even during natural gas heating.

 The object of the invention is therefore to propose a device intended to use a part of the residual heat contained in the exhaust gases leaving the boiler, by means of which the exhaust gas is fed to the chimney, at any operating period. and by burning any fuel, come out of the chimney at a suitable temperature.

 According to the invention, this result is achieved by the fact that, in the conduct of the cooling medium leading to the heat exchanger is placed a two-way device which can be actuated by a regulator and that input of this regulator are connected the output of a temperature sensor placed in the outlet section of the chimney and the output of a dew point measuring device disposed in the exhaust gas duct exiting the boiler, and that the output of the controller producing an oriented control signal is connected to the actuating organ of the two-channel device, which control signal is proportional to the difference between the input signals.

 This solution makes it possible to obtain that the exhaust gases leaving the boiler are only cooled down to a temperature for which the temperature of the exhaust gases leaving the chimney is still higher than the momentary dew point, which means to say that no condensation or harmful corrosion occurs in the chimney. Furthermore, the device according to the invention makes it possible to use the heat contained in the exhaust gases to a predetermined temperature of construction, and that it makes it possible to avoid, during the use of the fuel, to take for unfavorable conditions when they are not present. In this way, it is possible to obtain a significant saving of the fuel and also to improve the efficiency of the boiler.

 It may be advantageous for the dew point meter to be periodically turned on.

This solution is advantageous because the dew point of the exhaust gas leaving the boiler, for a given boiler, does not change frequently and thus, with a periodic adjustment, possibly made by hand, the device is simpler and less expensive. .

 According to another embodiment of the invention, in the case of the use of several boilers, the latter are connected in parallel on the side of the exhaust gases and in the case of using several convection heat exchangers, the latter are connected in parallel both on the side of the exhaust gas and on the side of the coolant.

 The device according to the invention also offers the possibility of using several boilers or several heat exchangers.

 According to yet another embodiment, the device comprises several boilers which are connected in parallel on the side of the exhaust gas and each boiler is associated with a convection heat exchanger which comprises a separate autonomous cooling circuit, in which is arranged a two-way device.

 In this way, the device offers the possibility of using coolants of different types.

Other features and advantages of the invention will become apparent from the following description of several embodiments and with reference to the accompanying drawings in which:
FIG. 1 is a block diagram of a first embodiment in which a two-way device is arranged in a collector,
FIG. 2 is an embodiment in which the two-way device is arranged as a distributor,
Figure 3 is a block diagram of another embodiment in which the coolant from the two-way device does not result in the boiler but an outside user,
FIG. 4 represents the embodiment of FIG. 3 in the case where the two-way device is arranged as a distributor,
Figure 5 shows another embodiment in which several boilers are used and are connected in parallel on the side of the eva cation gases,
Figure 6 shows an embodiment similar to that of FIG. 2 with several boilers,
Figure 7 shows an embodiment similar to that of FIG. 3, with several boilers,
Figure 8 shows an embodiment similar to that of FIG. 4 with several boilers,
FIG. 9 represents an embodiment with a boiler and several heat exchangers connected in parallel,
FIG. 10 represents an embodiment with several boilers and several heat exchangers, the boilers being connected in parallel on the side of the exhaust gases and the heat exchangers being connected in parallel as well on the side of the exhaust gases as on the side of the coolant, and
11 shows a device with several boilers and several heat exchangers, the boilers being connected in parallel and the heat exchangers each having a clean cooling circuit.

 In the device shown in FIG. 1, a convection heat exchanger 5 is interposed behind the permanent heating surface of the boiler 4, seen in the direction of the exhaust gases. The exhaust gases leaving the boiler 4 pass through the pipe 11 in the chimney 6. In the pipe 11 is placed a stop device 7 and in the open or closed position of this device, the exhaust gases pass directly. in the chimney 6 or by the convection heat exchanger 5. This heat exchanger 5 also passes a coolant into the line 1 in which there is a two-way device 2. The coolant flows to the boiler 4, partly directly and partly via the heat exchanger 5 to convection.

 A temperature sensor 9 is disposed in the outlet section of the chimney 6. An apparatus 8 for measuring dew point is disposed in the pipe 11 of the exhaust gas. The outputs of the temperature sensor and this apparatus are connected to the input of a regulator 3 whose output is connected to the actuator 12 of the two-way device 2.

 The device according to the invention operates in the following manner.

 The boiler 4 is operated with the shut-off device 7 fully open, ie all of the exhaust gases are conducted via the pipe 11 directly into the conveyor 6 When the boiler 4 and the chimney 6 reach the temperature operating mode, dew point measuring apparatus 8 and temperature sensor 9 are turned on. As a result, the regulator 3 and the two-way device 2 are depressed.

 The shut-off device 7 is closed periodically and in the meantime, the coolant stream is established in line 1. The dew point of the exhaust gases leaving the boiler 4 via line 11 is measured. and the meter transmits to the regulator 3 a signal proportional to the measured value. The temperature sensor 9 disposed in the outlet section of the chimney 6 measures the effective temperature of the exhaust gas exiting into the air and its output signal is retransmitted to the regulator 3.

The latter compares the two temperature values and, as a function of the sign of the difference, it delivers a control signal to the actuating device 12 of the two-way device 2. It follows that the two-way device 2 delivers to the convection heat exchanger 5 a quantity of coolant such that the exhaust gases are cooled to a temperature at which the temperature of the gases measured by the temperature sensor 9 is still greater than the temperature of the point momentary dew measured by the dew point measuring apparatus 8.

In the case where the chimney 6 is equipped with a protection against corrosion, that is to say where the temperature of the exhaust gases leaving the atmosphere may be other lower than a temperature difference determined at the temperature of the dew point, the regulator 3 reduces the dew point by this temperature difference and this reduced value is compared with the temperature measured by the temperature sensor 9
If the convection heat exchanger 5 is sufficiently sized, it is possible to obtain with the device according to the invention that, independently of all the factors influencing the dew point of the exhaust gases, the gases leave the chimney 6 at the temperature of the dew point or, in the case of a chimney with anti-corrosion protection, at a given temperature, below the dew point.

 For the coolant, it is possible to use a liquid, for example boiler feed water or water to be heated for use elsewhere, or air, for example example the combustion air of the boiler or air to be heated for use elsewhere.

 The operation of the dew point meter may be permanent or periodic. In the case of a periodic operation, the result of the previous measurement remains in the regulator 3 until the arrival of the next measurement result. The new measurement result clears the previous one.

 The embodiment shown in FIG. 2 differs from that of FIG. 1 in that the two-way device 2 is arranged as a distributor and not as a collector.

In the embodiment shown on the
Fig. 3, the cooling medium passing through the convection heat exchanger and the two-way device 2 does not lead to the boiler 4 but passes through the pipe 10 to an external user of heat.

 The embodiment of FIG. 4 differs from that of FIG. 3 in that the two-way device 2 is arranged as a distributor and not as a collector.

 The embodiment of FIG. 5 is identical in principle to that of FIG. 1 but the boilers are connected in parallel to the exhaust gas side. With the same difference, FIG. 6 is identical to FIG. 2, FIG. 7 in FIG. 3 and Fig.8 in FIG. 4.

 The embodiment of Figure 9 differs from that of Figure 1 in that n convection heat exchanger elements are connected in parallel.

 With the same difference, Figure 10 is identical to Figure 2.

 The embodiment shown in FIG. 11 differs from that of FIG. 2 in that n boiler elements 4 and n convective heat exchanger elements 5 and cooling agents of sorts are used. The boilers are connected in parallel to the exhaust gas side and the convection heat exchangers have independent cooling circuits.

Claims (5)

 1 - Device for using part of the heat contained in the exhaust gas leaving a boiler by the chimney, this device comprising at least one boiler and at least one convection heat exchanger in the direction of circulation of the exhaust gas, arranged after the heating surface of the boiler, characterized in that, in the line (1) of the cooling medium leading to the heat exchanger (5) is interposed a two-way device ( 2) which can be actuated by the regulator (3) the regulator input being connected to the output of a temperature sensor (9) mounted in the outlet section of the chimney (6) and at the outlet of a device Dew point measurement device (11) disposed in the pipe (11) of the exhaust gases leaving the boiler, the output of the regulator producing an oriented control signal being connected to an actuating member (12) of the device for two channels (2), the control signal being proportional to the difference between the input signals.  2 - Device according to claim 1, characterized in that the apparatus (8) for measuring dew point is periodically switched on.  3 - Device according to claim 1 or 2, characterized in that, in the case of use of several boilers (4), the boilers (4) are connected in parallel on the side of the exhaust gas (Figures 5 to 8 and 10, 11).  4 - Device according to any one of claims 1 to 3, characterized in that in the case of use of several heat exchangers (5) its last are connected in parallel both on the side of the exhaust gases as on the side of the coolant.  5 - Device according to any one of claims 1 to 3, characterized in that it comprises a plurality of boilers (4) which are connected in parallel on the side of the exhaust gas, each boiler (4) being associated with a heat exchanger thermal convection circuit having its own cooling circuit and in which a two-way device (2) is arranged.