DE2637560A1 - LEAK DETECTION DEVICE FOR AN OIL HEATING SYSTEM - Google Patents

Abstract

In this device, the burner (2), which is equipped with an oil-conveying pump (3), is connected to a vented fuel oil tank (1) via a conveying line (4) which contains a foot valve (53). The conveying line (4) is, furthermore, connected to a chamber (7) to which there are connected an intake line (11) of a vacuum pump (12) which generates an underpressure in the chamber (7), and a pressure cell (15) of an alarm device (16). In order both when using a single-walled storage container and when using a double-walled storage container to make it possible to monitor leaks in the lines (4, 10) connecting the burner (2) to the fuel oil tank (1), without said lines having to be surrounded by an enveloping tube, the device is laid out as follows: the chamber (7) projects in its vertical extent beyond the vertically highest point (5) of the line (4) and the oil column, which corresponds to the underpressure which can be produced in the chamber (7) by the vacuum pump (12), is smaller than the vertical distance of the highest point of the chamber (7), from the highest filled level of the fuel oil tank (1). <IMAGE>

Description

Leak detection suitability for an oil heating system (I.

The invention relates to a leak indicator device for a 3Rneizungsanlage, in the case of the burner equipped with an oil feed pump with a vented heating oil tank is connected via a delivery line which contains a foot valve or the like and in which the delivery line is connected to a chamber to which the suction line is connected a vacuum pump generating a negative pressure in the chamber and a pressure cell connected to an alarm device.

In the case of an oil heating system, the fuel oil tank itself and the as Feed line called delivery line to the burner and usually to the heating oil tank return line resulting in a source of danger that leaks Leakage oil emerges from the points of the heating oil tank and the lines supplying the burner and can endanger the environment. An early detection of such leaks is known about the heating oil storage tank by numerous, in particular vacumetric Leak detection devices are known for the storage containers that are often installed underground. These leak indicators generate in the shell space of a double-walled storage container a negative pressure, which is monitored by appropriate measuring devices and is used to trigger an alarm in the event of impermissible changes (DT-PS 1 150 248, DT-PS 1 258 b78). So-called fully vacuum devices are also known (DT-AS 1 2a6 336), where in the space above the liquid level by means of a Vacuum pump generates and monitors a negative pressure that changes with the filling level will. These comparative vacuum devices have the advantage that there are also leaks in the line leading to the burner to trigger an alarm. The disadvantage This fully vacumetric device lies in its complicated control system, which is so must be designed so that the normal consumption of fuel oil by the burner, which is too does not lead to a natural drop in the liquid level in the heating oil storage tank Cause of an alarm may be. It also creates difficulties in the event of an alarm determine whether the leak is in the container itself or in the pump delivery line This problem could be solved by analogous application of the jacket space technology solve, in which as with the DT-PS 1 600 375 the delivery line itself with a hell pipe surrounded, and the jacket space formed by the Höllrohr is monitored vacumetrically. Such a measure, however, is very expensive and when it is already installed Oil heating systems can hardly be retrofitted.

Finally, it should be pointed out that fully vacuum devices in practice work with very high negative pressure, d. H. a negative pressure of z. B. 4 m WS, and thus very high demands on the strength of the storage tank, to avoid the risk of imolosion. This danger exists with the vacumetric Monitoring of the jacket space of double-walled storage containers even with high negative pressure not. When the suction line of the vacuum pump in the shell space up to its sole area is performed, can, as is known, run with low negative pressure (z. B. 700 mm WS) will. In the case of low-pressure systems, special measures are usually not necessary, in order to prevent liquid from entering the vacuum pump in the event of an accident, for what A float valve must be provided for devices that work with high negative pressure got to. You can also see the ingress of liquid into a vacuum pump through a prevent hydrostatic valve (DT-PS 1 650 003).

In summary, it can be said of the state of the art that, although fully vacuum-metric Devices also monitor the flow line leading to the burner and the return line enable, in practice, however, the double-walled heating oil storage tank with monitoring the negative pressure in the shell space has given preference.

To solve the problem of monitoring the delivery line is one Leak indicator according to the genus of the invention has been proposed at which causes the oil to be conveyed from the tank to the chamber by the vacuum pump will. This calls for the use of a powerful vacuum pump and a high Vacuum. As a result, the chamber vessel itself becomes endangered by implosion Container. This proposed solution is also used to regulate the Level in the chamber built-in PTC thermistors that switch the vacuum pump and actuate a solenoid valve of the delivery line provided on the heating oil tank. Electric operated devices, such as this solenoid valve, are reluctant to be in the immediate vicinity Housed in the area of the heating oil tanks and, if necessary, permitted if they are used in an exposure-protected design.

The object of the invention is to provide a leak indicator for a To create an oil heating system that, like the proposed solution, both in use a single-walled as well as a double-walled storage container a leak monitoring which enables oil-carrying lines connecting the burner to the heating oil tank, without these having to be surrounded by a cladding tube, or without the heating oil tank itself must be hermetically sealed or even put under negative pressure.

The invention is intended to do justice to the oil heating systems where the heating oil tank and the burner are approximately at the same height. But it should also be adaptable to oil heating systems in which the heating oil tank is lower than the Burner. Finally, the invention should also be used in conjunction with a leak detection device for monitoring the negative pressure in the jacket space of a double-walled container with extensive utilization of the devices and device parts provided for this purpose be.

According to the invention it is therefore proposed that the chamber in its vertical extension towers over the highest point of the delivery line vertically and the negative pressure that can be generated in the chamber by the vacuum pump (U - in mm oil column measured) is smaller than the vertical asstand of the highest point of the chamber from the highest fill level of the heating oil tank.

The invention provides reliable monitoring of the delivery line with little equipment and without additional electrical equipment, such as PTC thermistors or a solenoid valve, both in the area of the heating oil tank and during of the operation of the burner as well as during its downtime. Furthermore the leakage indicator vents the delivery line of the pump, so that its safe Start-up is guaranteed even after the oil heating system has been inactive for a long period of time is.

A vorzweise in connection with the proposed erfindungsge A further solution to the problems according to the invention which is to be applied in accordance with the present invention is characterized according to the invention in that the connection of the delivery line via the Chamber with the vacuum pump is interrupted when the burner is switched on.

This may initially appear to be a disadvantage, since in this case a Monitoring of the delivery line is only given during the downtimes of the burner is. However, this also prevents fuel oil from leaking out to the full extent. The invention makes use of the fact that during the operation of the burner In practice, the delivery line referred to as the supply line cannot leak. Because this is under the suction effect of the burner pump. A sucking line is running not from. As soon as the burner pump has stopped, however, control over the through Use the vacuum pump that can be generated under pressure and there will be a leak that may be present show immediately. This embodiment according to the invention has the considerable advantage that it is independent of the geodetic suction head of the pump and even with a large one geodetic suction lift, which leads to a large manumetric suction lift of the pump, can be operated with a low negative pressure of the vacuum pump.

It should be emphasized at this point that in contrast to the The solution, which is not yet part of the state of the art, is the oil feed pump of the burner continues to take over the conveyance of the oil intended by the burner manufacturer, and can therefore work as intended.

A preferred embodiment of the invention provides that in the Chamber a vacuum of 300 - 1. ion mm oil column generated by the vacuum pump will.

Of course, the invention also enables monitoring the oil return line if this is also connected to the chamber. Since the chamber can be housed away from the fuel oil tank near the burner In addition, a considerable part of the return line is saved. the Monitoring of the return line has special Meaning as this is primarily at risk.

Further refinements of the invention are set out in the further subclaims and are explained in more detail in the course of the description of the accompanying figures. These show exemplary embodiments of the invention in a schematic representation. It Fig. 1 shows a leak indicator device for the oil supply lines of a Burner Fig. 2 shows a leak indicator device for an oil heating system with a vacuum-monitored double-walled heating oil tank Fig. 3 a special design the chamber and its connections Fig. 4 acting on the float of Fig. 3 Forces in FIG. 5 act on the float in FIG. 3 at the beginning of the oil level sinking on the forces acting Fig. 6 is provided for the leak indicator device Leak detector Fig. 7 shows an oil heating system.

Fig. 1 shows a heating oil tank 1, which is connected to the oil feed pump 3 of a Burner 2 is connected via a delivery line 4. In the delivery line 4 is a upwardly directed connection piece 8 is provided, which leads to a closed chamber 7 leads. The connection for a suction line 11 is located at the head of the chamber 7 a vacuum pump 12, the exhaust of which is denoted by 13. Furthermore is located at the head of the chamber 7 a connection line 14 for a pressure switch 15, which with one acoustic alarm device 16 is connected. The connection clip 6 in the delivery line 4 divides this into an inlet 4 a and an outlet 4 b. The oil feed pump 3 has a return line lo which opens into the chamber 7. At the end of the delivery line 4 a foot valve 53 is provided.

The vacuum pump 12 is via its suction line 11 in the chamber 7 generates a negative pressure, so that in-this heating oil 8, which is also the delivery line 4 and the return line lo fills, to the level U rises. The height U corresponds to the negative pressure that can be generated by the vacuum pump 12 and is here of the highest Point 5 of the delivery line 4 measured at. This vacuum level U is smaller here as the vertical extension of the chamber above the highest point 5 of the delivery line 4, which is represented by the height dimension H. The liquid level in the Chamber 7 standing oil column thus determines the remaining space under negative pressure 9 of the chamber 7. By suitable arrangement of the vacuum pump 12, part of the connection Lines 11 and 14 in the remaining space 9, and thus in the chamber 7 with included be.

The leak indicator shown in Fig. 2 serves both Monitoring of the delivery line 4 as well as the jacket space 23 of a double-walled Heating oil tank 1. The heating oil tank 1 consists of a massive outer tank 22 made of steel, into which a plastic sleeve 21 is inserted.

From the sole area of the storage tank 1, which is largely filled with oil 8, leads the delivery line 4 via the chamber 7 to the oil feed pump 3. The chamber 7 is here formed by a vertical pipe 49, in the bottom area of which the inlet 4 a and the flow 4 b of the delivery line 4 are connected and its upper one Has the connection of the suction line 11 of the vacuum pump 12 at the end. In the suction line connection of the vacuum pump 12, a solenoid valve 24 is provided on the chamber 7. A dash-dotted one Line 63 is intended to indicate that the solenoid valve 24 control technology with the burner pump 3 is coupled. Above the solenoid valve 24 is a float ventii 64 attached to the suction line 11 of the vacuum pump 12. This float valve 64 is not essential for the function, but prevents damage to the vacuum pump or at their control, an ingress of oil into the vacuum pump 12 and the pressure cell 15. A sight glass 27 is connected to the bottom of the chamber 7. The sight glass 27 is used as a water bag.

The exhaust of the vacuum pump 12 is in the dome space 31 of the heating oil tank 1 returned. This prevents unpleasant odors from escaping oil vapors.

The example shown in Fig. 2 also shows that the monitoring of the negative pressure in the chamber 7 provided connection line 14 also on the suction line 11 of the vacuum pump 12 can be connected.

It can also be seen that the suction line 11 of the vacuum chamber 12 is a The branch 28 leading to the jacket space 23 and the connecting line 14 of the pressure cell 15 of the alarm device connected to a measuring line 25 of the jacket space 23 has further junction 29. A suction pipe 26 therefore leads from the junction 29 in the jacket space 23, in which this suction line is led to the sole area. The branch point in the suction line 11 for the connection line 24 is designated by 30.

The vacuum pump 15 is via a corresponding electrical line 18 with an acoustic alarm device 16 and a visual warning device 17 connected. It goes without saying that the pressure cell 15 is appropriate electrical connections (not shown) and switches operated by the pressure cell contains. In the example shown, the pressure cell 15 contains three switching stages, wherein the switching contact assigned to the Stetler line 20 is the one permitted in the chamber 7 The largest switching contact assigned to the control line 19 is the one in the chamber 7 corresponds to the lowest permissible negative pressure. When this lowest negative pressure is reached in the chamber 7 the vacuum pump 15 is switched on automatically, until the maximum permissible negative pressure has been reached again.

In practice, it is not a constant negative pressure but with a certain negative pressure range, e.g. B. 300 - tco mm WS or 500 - 700 mm WS to avoid constant switching of the vacuum pump. Falls in spite of the When the vacuum pump 15 is switched on, the negative pressure continues to fall, and an alarm is triggered. Since the chamber 7 communicates with the shell space 23 via the lines 11 and 26, an alarm also occurs if the pressure in the shell space 23 increases in an impermissible manner.

In Fig. 3, another embodiment of the invention is shown, the is characterized in that the chamber 7 by a float valve 32 in a upper and a lower sub-chamber is divided, and from the weight of the Float resulting opening force P1 of the valve float 34 is greater than the additional acting on the valve float QA in its closed position, Holding force P2 resulting from the negative pressure in the upper sub-chamber 37. at In this embodiment, the negative pressure created by the vacuum pump in the chamber 7 is generated, be so large within the scope of the teaching of the invention that without the float valve 32 the heating oil 8 would still penetrate into the upper sub-chamber 37. This illustrated Solution will be used when the exhaust of the vacuum pump does not enter the Tank space can be returned. There will then be an escape of oil vapors The exhaust of the vacuum pump is largely reduced. This special version is in the following described. A valve seat 33 is provided in the tube 49 forming the chamber 7, the valve opening of which is closed by the round head of the valve float 3. The valve float 34 is guided by guides 35, its lowest position determined by a support 36. In the bottom area of the tube 49 are suitable Threaded connections of the inlet 4 a and the outlet 4 b connected. In the soil itself a connection piece 40 is provided to which a further suitable connection 39 a sight glass 27 is attached. Gradually falling when the burner stops Water droplets can collect in this sight glass 27 and create a water sump 43 form. At the inspection of the system is the glass body 41 unscrewed the sight glass and replaced a seal 42 if necessary. At this Inspection Leaking oil can be collected and fed to the heating oil tank.

The float valve 32 is designed so that it opens as soon as the Fluid level drops significantly.

Act in the position of the float valve shown in Fig. 3 on the float the forces indicated by arrows in FIG. 4, namely those from the weight of the swimmer 34 resulting force P1, which is less than the buoyancy force P3, which leads to the closing of the float valve 32. As soon the float valve 32 is closed, acts on the float 34 in addition Force P2 resulting from the negative pressure in the upper sub-chamber 37. The power As the oil in chamber 7 drops, P3 changes continuously from its maximum value up to a value which finally reaches the float valve 32 together with P2 can keep more closed. When the column of fluid drops, as it happens, if there is a leak, the float valve opens. Once the liquid until the abutment 36 has sunk, act on the float 34 besides the constant dead weight P1 no more forces. As Fig. 5 shows, however, must be off the force resulting from the dead weight P1 must be significantly greater than that from the negative pressure resulting force P2 so that the valve can open at all.

In Fig. 6, a leak detector 52 is shown as it is in connection can be used with the leak indicator. It consists of a housing 48, in which an electrically operated vacuum pump 12, a pressure cell 15, a acoustic alarm signal generator 18 and corresponding lines are housed. An optical alarm device 17, namely a lamp, is in a breakthrough of the housing 48 so that it can be observed from the outside In practice Another control lamp will be provided to indicate the operational readiness of the device. In the housing 48 are the branch 28 and the other Junction 29. The following external connections now result a? Exhaust 13, from which a line is led to the tank space; b) 2 suction line connections 11 and 26, one of which is attached to the jacket space of a double-walled heating oil tank, the the other is connected to the chamber 7; c) 2 measuring line connections 25 and 14, one of which is attached to the jacket space of a double-walled heating oil tank, the other to the chamber 7 is connected; c) 1 electrical connection cable 47.

There is a closing valve in each of the suction line 26 and the suction line 11 44 and 45, against the action of a spring with the application of manual holding force is closable. In the event of an alarm, the closing valve 44 and a corresponding closing valve So in the measuring line 25 held shut. If now the alarm is released again, it is certain that the leak is in the tank. Then the cross check is made by 3activating the closing valves 45 and 51 in the suction line 11 or the connecting line 14 executed and found confirmation that the alarm continues, the leak is actually in the tank and only in the tank.

In Fig. 7 is the spatial division of an oil heating system and the leak indicator shown for this purpose. The heating oil tank is in the ground 57 and is filled through a filling pipe 54. Aeration and ventilation pipe 55 with a cap 56 arranged on the head thereof is provided. The burner 2 the oil heating system is housed in a heating room 58, which is also the chamber 7 contains the leak indicator. The leak detector 52 itself is on one Wall of the neighboring room 59 hung. The rooms 58 and 59 are separated by a partition 62 separated.

The delivery line 4 leads from the heating oil tank 1 through the space 59 into the Heating room 58 and there to burner 2.

The function of the oil heating system and the leak indicator device is described below described. In the position shown in FIG. 7, the burner 2 is switched off; since the burner pump 3 is also at a standstill, the solenoid valve 24 is electrically operated by it Coupling with the burner opened, so that in the chamber 7 a through the vacuum pump the leak detector 52 generated negative pressure of, for example, 700 mm oil column prevails. Since the foot valve 53 is automatically closed when the burner 2 is stationary, and essentially holds the oil column standing in the delivery line 4, corresponds to the negative pressure generated by the vacuum pump in the chamber 7 is approximately the same as the negative pressure U as the distance between the liquid level in the chamber 7 and the highest point of the delivery line 4th

The highest point of the chamber 7 is here through the highest point 17 c of the suction line 11 determines the part of which is located in front of the highest point 11 c 11 a is part of chamber 7. The part 11 lying behind the highest point 11 c b of the suction line 11 is not taken into account when determining the overall height of the chamber 7.

In the event of a leak in the delivery line 4 or in the inlet 4 a or in the outlet 4 b as well as in the return line lo there is a pressure increase in the upper one Part of the chamber 7, which triggers an alarm.

As soon as burner 2 is switched on, the solenoid valve closes 24.

As soon as the solenoid valve 24 is closed, the chamber 7 is through this is divided into two independent sections, of which the leak detector 52 by the parts 11 a and 11 b of the suction line 11 represented sections according to as before, stand under a vacuum of, for example, 700 mm oil column. Under the suction of the ahlaufenden burner pump 3, which is initially very large because the entire column of liquid in the delivery line 4 must be accelerated, comes to a drop in the liquid level in the chamber 7 and thus to an increase of the negative pressure in the same until the on the column of liquid 7 have balanced forces acting in the chamber. This state of equilibrium will depend, among other things, on whether the heating oil tank 1 is full or almost empty is. In the filled state, to which the liquid level 60 corresponds, is the geodetic Suction lift S1 smaller than the geodatic suction lift 52 when the tank is almost empty, the the liquid level 61 is assigned. In the event of a leak in the delivery line 4 or There is no alarm in the return line lo when burner 2 is running the leak detector 52, since the solenoid valve 24 is closed, the alarm becomes however, it is made up as soon as the burner 2. has come to a standstill. This standstill of the burner 2, if air penetrates into the delivery line 4 through the leak can be brought about by the burner 2 itself, since it switches itself off, if there are irregularities due to the enrichment of air.

- Finally, some height information should be explained. The chamber 7 protrudes beyond the highest point of the delivery line 4 by the dimension H. This height dimension H is greater than the suction height U of the leak detector 52.

The dimension B corresponds to the distance from the highest point 11 c of the Suction line 11 and thus the chamber 7 from the connection of the feed line 4 to the feed pump 3.

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Claims (15)

Claims 1. Leak indicator for an oil heating system, in which the burner equipped with an oil feed pump with a vented heating oil tank is connected via a delivery line1 which contains a foot valve or the like and in which the delivery line is connected to a chamber to which the suction line is connected a vacuum pump generating a negative pressure in the chamber and a pressure cell an alarm device are connected, characterized in that the chamber (7) the vertical highest point (5) of the delivery line in its vertical extension (4) and the negative pressure that can be generated by the vacuum pump (12) in the chamber (7) (U - measured in mm oil column) is smaller than the vertical distance of the highest Point of the chamber (7) from the highest fill 1 level (60) of the heating oil tank (1). 2. Leak indicator according to claim 1, characterized in that that the vertical extension of the chamber (7) is the vertically highest point (5) the delivery line (4) by a height H -. in mm - surmounted by the fact that is greater than the negative pressure U. 3. Leak indicator for an oil heating system in which the burners equipped with an oil feed pump with a vented heating oil tank a delivery line is connected which contains a foot valve or the like and in which the delivery line is connected to a chamber to which the suction line is connected a vacuum pump generating a negative pressure in the chamber and a pressure cell an alarm device are connected, in particular according to one of the claims 1 and 2, characterized in that the connection of the delivery line (4) via the Comb (7) with the vacuum pump (12) is interrupted when the burner is switched on. 4. Leak indicator according to claim 3, characterized in that that in the suction line (tl) of the vacuum pump (12) a switching with the burner (2) Solenoid valve (24) is provided. 5. Leak indicator according to claim 4, wherein the pressure cell (15) is connected to the suction line (11), characterized in that the Connection (14) of the pressure cell (15) between the solenoid valve (24) and the vacuum pump (12) lies. 6. Leak indicator according to one of claims 1 to 5, characterized characterized that the negative pressure U is between 300 and 1 loo mm oleic acid (= approx. 270 up to 1 ooo water column). 7. Leak indicator according to one of claims 1 to 6, in which the oil return line of the oil feed pump opens into the chamber, characterized in that that the oil return line (lo) is above the vertically highest point of the delivery line (4) is connected to the chamber (7). 8. Leak indicator according to one of claims 1 to 7, characterized characterized in that a vertical, substantially closed tube (49), which at least partially forms the chamber (7) is provided in its bottom area the inlet (4 a) and the outlet (4 b) of the delivery line (4) are connected, and its upper end the connection of the suction line (11), which is at most partially the chamber (7) forms. 9. Leak indicator device according to claim 8, characterized in that that the clear diameter of the tube (49) is larger, at least twice as large like the clear diameter of the delivery line (4). 1 O. Leak indicator device according to one of claims 1 to 9, characterized characterized in that in the suction line connection of the vacuum pump (12) on the chamber (7) the solenoid valve (24) is provided. 1 1. Leak indicator according to one of claims t to lo, characterized characterized in that a sight glass (27) is detachably connected to the bottom of the chamber (7) is. 12. Leak indicator according to one of claims 1 to 11, characterized characterized in that to the exhaust (13) of the vacuum pump (12) in a known manner Way an exhaust line is connected, which in the dome space (31) of the heating oil tank (1) opens. 13. Leak indicator according to one of claims 1 to 12 in one Oil heating system with a double-walled heating oil tank, in the manel room a negative pressure is generated and monitored, characterized in that the suction line (11) of the Vacuum pump (12) a branch (28) leading to the jacket space (23) and the connection line (14) of the pressure cell (15) of the alarm device one to the measuring line (25) of the jacket space (23) has connected further branch (29). 14. Leak detection device according to claim 13, consisting of a housing, in which an electrically operated vacuum pump, at least one pressure cell, a Alarm signal generator and lines leading to corresponding external connections are provided are, characterized in that the branch (28) and / or the further branch (29) housed inside the housing (48), as well as in both suction lines (11, 26) and / or in the measuring line (25) and the connecting line (14) on or in the housing (48) each have a closing valve (44, 45 or 50, 51) are provided. 15. Leak detection device according to claim 14, characterized in that the closing valves (44, 45 or So, 51) against the action of a spring with application manual holding force can be closed.