NL9200426A - GAS DOSING DEVICE. - Google Patents

Abstract

The invention relates to a gas dosing device comprising a flow duct which is connected to a flow generating device such as a fan and has an inlet end for a main gas flow and an outlet end. The flow duct is divergent in the through-flow direction and a main gas valve element extending transversely of the duct is accommodated therein guided for movement coaxially of the duct. The main gas valve element is loaded in the direction counter to the through-flow direction and is connected to a mixing gas dosing unit which is connected to a mixing gas feed pipe and can deliver an amount of mixing gas related to the position of the main gas valve element in the duct. The invention further relates to a heating device (1) comprising means defining a flow duct (2) which is connected to a fan (6) and has successively in a through-flow direction at least a gas dosing device (3) as described above, a burner (4) and a heat exchanger (5) through which a heat transfer medium can flow. The inlet end of the gas dosing device is connected to the atmosphere and the mixing gas feed pipe is connected to a source of flammable gas. <IMAGE>

Description

GAS DOSING DEVICE

The invention relates to a gas dosing device comprising a flow-through duct connected to a flow generating device such as a fan, with an inlet end for a main gas flow and with a mixing gas dosing unit for dosing a mixing gas to the main gas.

Such a gas dosing device is generally known and is used, for example, for adding flammable gas such as natural gas to air for combustion in the burner of a heating device. The mixed gas dosing unit is for instance formed by a gas nozzle connected to a gas supply pipe into which the combustible gas is supplied under a certain pressure. In this way, an accurate mixing ratio of the main gas and the mixing gas can be set.

However, in certain applications it is desirable to obtain a variable amount of gas mixture. For example, it is well known in heating devices to use a burner which, depending on the circumstances, can operate with a lower or higher capacity. Complicated control systems are required to obtain an accurately determined gas / air mixture at both low capacity and full load. The associated costs in many cases prevent the use of such a variable gas metering device.

The object of the invention is now to provide a gas metering device of the type described in the preamble with which a gas mixture can be obtained in a simple and economical manner with an accurately constant mixing ratio, at considerably varying flow rates.

This object is achieved with the gas metering device described in claim 1. The main gas valve element will assume a position in the diverging flow-through channel depending on the amount of gas flowing through the flow-through channel as a result of the operation of the flow generating device. As more gas flows through the channel, the main gas valve element positions in a wider portion of the flow-through channel. The position of the main gas valve element is thus a measure of the amount of gas flowing through and the mixing gas metering unit accordingly supplies an amount of mixing gas adapted to the amount of gas flowing through. An optimum mixing ratio is thus obtained within very wide limits of the amount of main gas flowing through.

A very simple device is obtained with the feature of claim 2. With a larger flow of main gas quantity, the main gas valve element occupies a position in a wider part of the main gas channel, thus simultaneously positioning the mixed gas valve element in a wider part of the mixed gas channel, thereby proportionally more mixed gas can flow in.

The measure of claim 3 achieves that no maintenance-sensitive transmissions and seals and the like are required.

A very favorable further development is characterized in claim 4. The mixed gas valve and main gas valve elements which are joined together in one piece are not impeded in their movement by friction. Thus, there is no risk that the mixing elements stick to an incorrect mixing ratio.

A further simplification with simultaneous increase in reliability is achieved with the measure of claim 5. The mixed gas valve / main gas valve element can hereby float freely. This element forms the only moving part of the gas metering device.

The invention also relates to and provides a heating device comprising means which determine a flow-through duct connected to a fan, with successively in a flow direction at least one gas dosing device according to one of claims 1 to 5, a burner and a flow-through heat exchanger, wherein the inlet end of the gas metering device is connected to the atmosphere and the mixed gas supply line is connected to a source of combustible gas. Depending on the conditions, this heating device can operate at a lower or higher capacity, achieving high efficiency at all settings. At the same time, this heating device can be manufactured economically.

The invention is further elucidated in the following description with reference to the use of a gas metering device according to the invention in a heating device.

Pig. 1 schematically shows a heating device according to the invention.

Pig. 2 is an enlarged sectional perspective view of the gas metering device of the heating device according to the invention.

The device 1 shown in Fig. 1 is a so-called HR heating boiler in which a flow-through channel 2 is determined in which a gas transport can be effected by a fan 6 incorporated therein, in the flow-through channel 2 there are successively a gas metering device 3, a burner 4, which in this embodiment is of the fully premixed type, a heat exchanger 5 and the aforementioned fan 6. The fan 6 discharges the supplied combustion gas to the chimney 7. It is noted that the fan 6 may also be included in another embodiment in the flow-through channel for the burner 4. The fan will not be exposed to higher temperatures and condensate.

The heat exchanger 5 is connected to a heating water supply pipe 11 and a heating discharge pipe 12 which are connected in known manner to radiators and convectors in order to deliver the heat supplied to the heating water in the heat exchanger 5 at desired locations.

In the gas metering device 3, the air drawn in by the operation of the fan 6 is mixed with gas from a gas supply line 8 in a predetermined desired mixing ratio, whereby optimum combustion takes place.

An electric gas valve 9 is included in the gas supply line 8, which can open and close the gas supply. A reducing valve 10 is also included in the gas supply line 8, which maintains the gas pressure in the gas supply line 8 at a constant value.

The entire device 1 is controlled by a control device 15 which is schematically shown here, of which only a few connecting lines are indicated. The control device 15 is connected to a flow sensor 16, a detonator 19, the previously taken electric throttle 9 and the fan 6. The flow sensor 16 may be a differential pressure sensor that responds to a pressure difference between lines 17 and 18. These lines 17 and 18 are connected to the flow-through channel 2 on different sides of the burner and heat exchanger assembly. As soon as the fan 6 is switched on by the control device 15, a flow occurs in the channel 2. As a result of this flow, a pressure difference arises over the burner 4 and heat exchanger 5 and thus a pressure difference between the pipes 17 and 18. This pressure difference is detected by the sensor 16 and this sensor gives a corresponding output signal to the control device 15. The control device 15 will then activate the gas valve 9 and the igniter 19, so that gas is added to the air flow and the air / gas mixture on the surface of the burner 19 is ignited. The hot combustion gases flow through the heat exchanger 5 and the heat is released in a known manner to the heating water therein. The cooled combustion gases are removed by the fan 6 to the chimney 7.

If, by means of detectors not shown in more detail, it is indicated to the control unit 15 that, for example, only a small amount of heat is to be generated, the control device 15 will operate the fan 6 at a low speed. On the other hand, when a great deal of heat is required, the fan 6 will be switched on at a high speed. At these extreme states and the intermediate states, a constant mixing ratio of the air and the gas in the air mixer 3 must nevertheless be obtained.

As can be seen in Fig. 2, which shows a preferred embodiment of the gas metering device according to the invention, this objective is achieved in an extremely simple, effective and reliable manner.

The gas metering device 3 comprises a housing 24 in which a diverging channel 25 is formed. This divergent channel 25 connects at its wide end and forms part of the flow-through channel 2. At the narrow end, the channel 25 connects to an air supply opening 26 which is freely connected to the environment. An air valve element 27 which extends transversely to the channel is incorporated in the diverging channel 25. This air valve element 27 is vertically movable coaxially with the channel 25, that is to say seen in Fig. 2. Connected to the air valve element 27 is a rod-shaped throttle valve element 28 which projects into a likewise diverging channel 30 in a gas regulator housing 29 which is fixedly connected to the housing 24 of the gas metering device. The gas supply pipe 8 is connected to the narrow end of the divergent channel 30.

The gas metering device 3 shown in Fig. 2 operates as follows.

The vertical arrangement of the gas metering device shown in Fig. 2 forces the integrally connected air valve element and throttle element 28 downwards, i.e. towards the narrow ends of the respective diverging channels 25 and 30. When there is no flow occurs through the channel 25, the valve elements lie in their bottom position indicated by dotted lines, closing both the air channel 25 and the gas channel 30.

As soon as the fan is switched on at a certain speed, an air flow will occur in the air duct 2. Depending on the strength of this flow, the air valve element 27 is sucked up into the divergent channel 25 against the force of gravity acting on the valve assembly. As the height of the air valve 27 increases, the gap between the edge of the air valve and the wall of the channel 25 becomes larger, so that the upward force decreases, so that at a given speed of the air flow, an equilibrium situation is established at a certain height of the air flow. air valve element 27 in the conical channel 25. By the direct connection of the air valve element 27 to the throttle element 28, a corresponding position of this throttle element 28 in the gas channel 30 and consequently of the gap between the lower end of the throttle element 28 and the wall of the gas channel 30 is set. The amount of gas flowing through the gap between the lower end of the throttle element 28 and the wall of the diverging gas channel 30 depends on its width and consequently on the vertical position of the throttle element 28. By a suitable choice of the cone of the gas valve Thus, in conjunction with that of the air channel 25, it can be achieved that at any position of the air valve element 27 determined by the air flows in the channel 25, an appropriate amount of gas is supplied into the channel 25 in order to achieve the desired mixing ratio. In this way, an accurate mixing ratio can be achieved with a very large range of variation of the air velocity. As is clear from Fig. 2, the gas metering device is particularly simple in construction with only one moving element, which, moreover, can float freely in the situation of use and thus can occupy a suitable position unobstructed. The described gas metering device is therefore economical to manufacture and will function reliably for a long time.

The dimensioning of the conicities of the air channel 25 and the gas channel 30 can be determined experimentally and is to some extent independent of the further design of the heating device. The control range of the gas metering device must of course be adapted to the desired control range of the heating device.

A setting of the desired mixing ratio can be achieved by setting the reducing valve 10.

The device shown in the figures relates to a preferred embodiment and the invention is not limited to this embodiment. For example, it is not necessary to arrange the gas metering device vertically, but it may also be placed horizontally or in another position, however, a spring may then have to be fitted around the air valve to preload towards the narrow end of the divergent channel 25. A direct connection of the air valve element 27 to the throttle valve element 28 is also a favorable measure, but an indirect connection can also be used.

Although the gas dosing device according to the invention lends itself particularly well for use with a heating device, it is not limited thereto. The invention is applicable in all circumstances in which a mixed gas has to be added in a fixed ratio to a main gas, while the flow of the main gas flow varies widely.

Claims (7)

A gas metering device comprising a flow channel connected to a flow generating device such as a fan, with an inlet end for a main gas flow, and an outlet end, wherein the flow channel is divergent in the flow direction and a main gas valve element extending transversely of the channel is movable therein coaxially with the channel and in which the main gas valve element is loaded in the counterflow direction and is connected to a mixed gas metering unit connected to a mixed gas supply line and capable of delivering an amount of mixed gas related to the position of the main gas valve element in the channel. Apparatus according to claim 1, wherein the mixing gas metering unit comprises a mixing gas channel diverging in a direction parallel to the flow direction and a mixing gas valve element co-axially movably connected thereto and fixedly connected to the main gas valve element, the mixing gas channel being connected at the small cross section to a source of gas under constant pressure and with the other end connected to the flow-through channel. Device as claimed in claim 2, wherein the mixing gas channel is arranged coaxially with the flow-through channel and opens directly therein. An apparatus according to claim 3, wherein the mixing gas valve element is rod-shaped and the main gas valve element is a disk fixedly connected thereto and the rod-shaped mixing gas valve element is freely movable in the mixing gas channel. Device according to any one of the preceding claims, wherein it is arranged such that the flow direction is directed vertically upwards, so that the main gas valve element is loaded by gravity against the flow direction. A heating device comprising means defining a flow-through duct connected to a fan, with successively in a flow-through direction at least one gas metering device according to any one of the preceding claims, a burner and a heat exchanger which can flow through a heat transport medium, the inlet end of the gas metering device being connected to the atmosphere and the mixed gas supply line is connected to a source of combustible gas. The heating device of claim 6, further comprising a control device to which is connected an electrically operated gas valve included in the mixed gas supply line, a burner igniter and a flow sensor for detecting flow in the flow-through channel, the control device in response to an output signal from the flow sensor activates the gas valve and the igniter.